DE202018100405U1 - emergency module - Google Patents

Abstract

An emergency module, characterized by comprising: a constant voltage module, a constant current module, a first comparator, and a second comparator, the constant voltage module connected between a power supply and the first comparator, the constant current module connected between the constant voltage module and the second comparator, wherein the power supply outputs a high level to the constant voltage module, wherein the fundamental voltage of the constant voltage module is compared with the comparison signal of the first comparator, wherein an electrical signal for controlling the change in the conversion ratio between the input voltage and the output voltage of the power supply is output, whereby the output voltage value predetermined constant voltage value is reached, wherein the basic signal of the constant current module is compared with the comparison signal of the second comparator, wherein an electrical signal for controlling the input gsstroms, whereby the input current is kept constant, wherein one end of the output voltage is an output voltage terminal, the output voltage terminal is connected to the constant current module, wherein the constant output voltage is fed to the constant current module, wherein the input current, the input power and the output power of the constant current module be kept constant, wherein the constant current module is connected to a charging device, wherein the charging device is connected to the load to adjust the output voltage and the current according to the voltage required by the load.

Description

Field of the invention

The present invention relates to the field of emergency lighting, and more particularly to an emergency module.

State of the art

LEDs are being used extensively and the LED lamps used for indoor and outdoor lighting are also becoming increasingly popular. Although LED power consumption is low, it is important to keep the current and voltage of the power supply relatively stable within a certain range, and at the same time provide some over-current / over-voltage protection to the LEDs.

Many electrical equipment is equipped with a back-up backup power supply, so if the external power supply fails, the electrical equipment will continue to run on backup backup power. In many areas of life emergency lights are needed, such. B. in corridors, in staircases and in warehouses.

In the prior art, it is customary to set the current output in such an emergency module as a constant current output, which limits the size of the output voltage, so that the access load is limited accordingly. If the number of loads or the connection mode of the series and parallel circuit is changed, the use of a new power supply is required, which easily leads to a waste of resources and the environment is not conducive.

Object of the invention

The object of the present invention is to overcome the shortcomings of the prior art and to provide an emergency module in which the range of the output voltage is unlimited by the setting of a constant power, whereby the problem that the LED module only for one load can be resolved to allow for full use of resources and thereby save energy.

To overcome the above technical problem, the present invention provides an emergency module comprising a constant voltage module, a constant current module, a first comparator, and a second comparator, wherein the constant voltage module is connected between a power supply and the first comparator, the constant current module being connected between the constant voltage module and the constant voltage module second comparator is connected.

The power supply unit outputs a high level to the constant voltage module, comparing the fundamental signal of the constant voltage module with the comparison signal of the first comparator, outputting an electrical signal for controlling the change ratio of the conversion ratio between the input voltage and the output voltage of the power supply unit, whereby the output voltage value reached predetermined constant voltage value.

The fundamental signal of the constant current module is compared with the comparison signal of the second comparator, whereby an electrical signal for controlling the input current is output, whereby the input current is kept constant.

One end of the output voltage is an output voltage terminal, the output voltage terminal being connected to the constant current module, the constant output voltage being fed to the constant current module while keeping the input current, the input power and the output power of the constant current module constant.

The constant current module is connected to a charging device, wherein the charging device is connected to the load to adjust the output voltage and the current according to the voltage required by the load.

In a preferred embodiment, the first comparator is connected to an output voltage terminal, wherein the voltage of the first comparator changes synchronously when the magnitude of the output voltage changes, wherein the comparison signal of the constant voltage means is concretely a first reference voltage value, wherein the comparison signal of the first comparator concretely is a voltage value of the first comparator, the constant voltage module sending an electric signal for controlling the change in the conversion ratio between the input voltage and the output voltage according to the comparison result between the reference voltage and the voltage of the first comparator.

Concretely, in a preferred embodiment, the constant voltage module is a first chip U5 with the first terminal Pin3 connected to the power supply, the second terminal Pin5 of the first chip U5 providing an electrical signal for controlling the conversion ratio between the input voltage and the output voltage sends, wherein the third terminal Pin2 of the first chip U5 has a first reference voltage and is connected to the first comparator.

In a preferred embodiment, the second terminal Pin5 is connected between the power supply and the output voltage terminal, wherein the conversion ratio between the input voltage and the output voltage is 1-D1, where D1 is the duty cycle of the first chip U5 at which an electrically conductive connection is made wherein the second terminal Pin5 transmits another duty cycle signal for changing the conversion ratio between the input voltage and the output voltage, wherein the conversion formula between the input voltage and the output voltage is as follows: V _O = V _IN / (1 - D1) where V _{O is} the output voltage and V _{IN is} the input voltage.

In a preferred embodiment, a first switch is disposed between the second terminal Pin5 and the output voltage terminal, wherein the input voltage is converted to an output voltage by the conversion ratio between the input voltage and the output voltage.

When the output voltage value reaches the predetermined voltage value, the first switch is turned on and the output voltage terminal outputs a voltage, and when the output voltage value does not reach the predetermined voltage value, the first switch is turned off and the output voltage terminal outputs no voltage.

In a preferred embodiment, the first comparator is concretely a first comparison resistor R36, wherein the first switch is concretely a first diode D9.

When the output voltage value is lower than the predetermined voltage value, the voltage value of the first comparison resistor R36 is smaller than the first reference voltage value and the electrically conductive connection is disconnected at the first diode D9, whereby the output voltage terminal outputs no voltage, the duty D1 of the second terminal Pin5, in which an electrically conductive connection is made, increases to a certain value, so that the output voltage value using the conversion formula reaches the predetermined voltage value.

When the output voltage value is equal to the predetermined voltage value, the voltage value of the first comparison resistor R36 is equal to the first reference voltage value, and an electrically conductive connection is made at the first diode D9 and the output voltage terminal outputs the predetermined voltage value.

When the output voltage value is higher than the predetermined voltage value, the voltage value of the first comparison voltage is greater than the first reference voltage value, and the duty cycle D of the second terminal Pin5 at which an electrically conductive connection is established decreases to a certain value, so that the output voltage value is below Using the transformation formula reaches the specified voltage value.

In a preferred embodiment, the constant current module is the second chip U6 with the input current flowing into the input power terminal, the fourth terminal Pin1 of the second chip U6 being connected to the output voltage terminal and the input power terminal and outputting a duty cycle signal for controlling the magnitude of the input current second comparator is connected between the output voltage terminal and the input power terminal, wherein the basic signal of the constant current module is concretely a second reference voltage value, wherein the fifth terminal Pin6 of the second chip U6 is provided with a second reference voltage and connected to the second comparator.

In a preferred embodiment, the second comparator is a comparison device consisting of two parallel-connected resistors R37, R38, wherein the output voltage terminal outputs a predetermined voltage value to the second chip U6, wherein the input current flows into the comparator consisting of shunt resistors, wherein a voltage difference, namely Comparative information of the second comparator, between the two parallel resistors R37, R38 is generated, which is compared with the second reference voltage value.

When the voltage difference generated between the two shunt resistors R37, R38 is smaller than the second reference voltage value, the duty signal D2 sent from the fourth terminal Pin1 rises to a certain value, whereby the input current reaches the predetermined current value.

If the voltage difference generated between the two parallel resistors R37, R38 is greater than the second reference voltage value, the duty cycle signal D2 sent from the fourth terminal Pin1 decreases to a certain value, whereby the input current reaches the predetermined current value.

In a preferred embodiment, the invention further includes an overvoltage protection module, wherein the overvoltage protection module comprises a second switch and a third switch, the second switch being connected between the input power terminal and the third switch, the third switch between the second switch and the sixth terminal Pin4 of the second chip U6, the second switch and the third switch, when the output voltage value is too high, are turned on, lowering the level signal of the sixth terminal Pin4 and the output voltage.

In a preferred embodiment, the second switch is the Zener diode ZD1, where the third switch is the transistor Q7, with the negative electrode of the Zener diode ZD1 connected to the input current terminal and the positive electrode connected to the base of the transistor Q7 the collector of the transistor Q7 is connected to the sixth terminal Pin4, wherein in the Zener diode ZD1, when the output voltage value is too high, an electrically conductive connection is made, wherein the base of the transistor Q7 receives a high level signal and at the base an electric is made conductive connection, wherein the level signal of the sixth terminal Pin4 is lowered, wherein the fourth terminal Pin1 sets the transmission of the Duty degree signal D2, d. H. stops, whereby the output voltage is lowered.

With the technical solution of the present invention, the following advantageous effects are achieved over the prior art:
In the technical solution, the constant input power is ensured by setting a constant voltage and a constant current. Further, since the same chip has a constant power, it is determined that the output power is kept constant. In actual use of the emergency module, when the number of loads or the connection manner of the series and parallel connection are reset, the output voltage of the emergency module changes. The emergency module according to the invention, the output voltage can be adjusted according to the voltage required for the load, the current is adjusted accordingly. The invention can be used in different situations. With the invention, the goal of using a single power module for different loads can be achieved to allow for full utilization of resources, thereby saving energy and economically utilizing resources. Furthermore, an overvoltage protection module is provided in the invention, with which it can be ensured that the circuit is not damaged by an excessive output voltage.

In the following, the invention will be described in more detail in a schematic representation with reference to the figures. It shows:

1 3 is a circuit diagram of the constant voltage range of a preferred embodiment according to the present invention;

2 FIG. 4 is a circuit diagram of the constant current range of the preferred embodiment according to the present invention; FIG.

3 a schematic representation of the appearance of the product of the preferred embodiment according to the present invention.

Detailed description of the embodiment

In order to provide a thorough understanding of the present invention, a preferred embodiment will now be described in detail with reference to the drawings.

An emergency module comprises a constant voltage module, a constant current module, a first comparator and a second comparator, the constant voltage module being connected between a power supply and the first comparator, the constant current module being connected between the constant voltage module and the second comparator.

The power supply unit outputs a high level to the constant voltage module, comparing the fundamental signal of the constant voltage module with the comparison signal of the first comparator, outputting an electrical signal for controlling the change ratio of the conversion ratio between the input voltage and the output voltage of the power supply unit, whereby the output voltage value reached predetermined constant voltage value.

The fundamental signal of the constant current module is compared with the comparison signal of the second comparator, whereby an electrical signal for controlling the input current is output, whereby the input current is kept constant.

One end of the output voltage is an output voltage terminal, wherein the Output voltage terminal is connected to the constant current module, wherein the constant output voltage is fed to the constant current module, wherein the input current, the input power and the output power of the constant current module are kept constant.

The constant current module is connected to a charging device, wherein the charging device is connected to the load to adjust the output voltage and the current according to the voltage required by the load.

The first comparator is connected to an output voltage terminal, wherein the voltage of the first comparator changes synchronously when the magnitude of the output voltage changes, wherein the comparison signal of the constant voltage means is concretely a first reference voltage value, wherein the comparison signal of the first comparator concretely a voltage value of the first Comparator is, wherein the constant voltage module according to the comparison result between the reference voltage and the voltage of the first comparator sends an electrical signal for controlling the change in the conversion ratio between the input voltage and the output voltage.

See the 1 to 3 , The constant voltage module 1 Concretely, a first chip U5 is connected to the power supply with the first terminal Pin3, the second terminal Pin5 of the first chip U5 sending an electrical signal for controlling the conversion ratio between the input voltage and the output voltage, the third terminal Pin2 of the first chip U5 has a first reference voltage and with the first comparator 2 connected is.

The second terminal Pin5 is connected between the power supply and the output voltage terminal, wherein the conversion ratio between the input voltage and the output voltage is 1 - D1, where D1 is the duty cycle of the first chip U5 at which an electrically conductive connection is made, the second Port Pin5 sends another duty cycle signal to change the conversion ratio between the input voltage and the output voltage, where the conversion formula between the input voltage and the output voltage is as follows: V _O = V _IN / (1 - D1) where V _{O is} the output voltage and V _{IN is} the input voltage.

A first switch 3 is disposed between the second terminal Pin5 and the output voltage terminal, and the input voltage is converted into an output voltage by the conversion ratio between the input voltage and the output voltage.

When the output voltage value reaches the predetermined voltage value, the first switch becomes 3 turned on and the output voltage terminal outputs a voltage, wherein the first switch 3 when the output voltage value does not reach the predetermined voltage value, is turned off and the output voltage terminal outputs no voltage.

The first comparator 2 is actually a first reference resistor R36, wherein the first switch 3 Specifically, a first diode D9 is.

When the output voltage value is lower than the predetermined voltage value, the voltage value of the first comparison resistor R36 is smaller than the first reference voltage value and the electrically conductive connection is disconnected at the first diode D9, whereby the output voltage terminal outputs no voltage, the duty D1 of the second terminal Pin5, in which an electrically conductive connection is made, increases to a certain value, so that the output voltage value using the conversion formula reaches the predetermined voltage value.

When the output voltage value is equal to the predetermined voltage value, the voltage value of the first comparison resistor R36 is equal to the first reference voltage value, and an electrically conductive connection is made at the first diode D9 and the output voltage terminal outputs the predetermined voltage value.

When the output voltage value is higher than the predetermined voltage value, the voltage value of the first comparison voltage is greater than the first reference voltage value, and the duty cycle D of the second terminal Pin5 at which an electrically conductive connection is established decreases to a certain value, so that the output voltage value is below Using the conversion formula reaches the predetermined voltage value, namely +6 V, and it is supplied via the output voltage terminal, the constant current module with power.

Please refer 2 , The constant current module 4 is the second chip U6, with the input current flowing into the input current terminal, the fourth terminal Pin1 of the second chip U6 having the Output voltage terminal and the input power terminal is connected and outputs a duty cycle signal for controlling the size of the input current, wherein the second comparator 5 is connected between the output voltage terminal and the input power terminal, wherein the basic signal of the constant current module 4 Specifically, a second reference voltage value is provided, the fifth terminal Pin6 of the second chip U6 provided with a second reference voltage and the second comparator 5 connected is.

The second comparator 5 is a comparison device consisting of two parallel-connected resistors R37, R38, wherein the output voltage terminal outputs a predetermined voltage value to the second chip U6, wherein the input current flows into the comparator consisting of shunt resistors, wherein a voltage difference, namely the comparison information of the second comparator 5 is generated between the two shunt resistors R37, R38, which is compared with the second reference voltage value.

When the voltage difference generated between the two shunt resistors R37, R38 is smaller than the second reference voltage value, the duty signal D2 sent from the fourth terminal Pin1 rises to a certain value, whereby the input current reaches the predetermined current value.

When the voltage difference generated between the two shunt resistors R37, R38 is greater than the second reference voltage value, the duty-cycle signal D2 sent from the fourth terminal Pin1 decreases to a certain value, whereby the input current reaches the predetermined current value.

The output voltage terminal outputs a constant voltage to the second chip U6, giving a constant current to the second chip, so that the input power is kept constant. Since the power is the same for the same chip, the output power is kept constant. When the fourth terminal Pin1 outputs a high level signal, the inductor L3 starts to store energy. When the fourth terminal Pin1 outputs a low level signal, the discharge of the inductor L3 starts. In this way, the inductance L3 after energy storage can meet the load requirements within a certain range. With the emergency module according to the invention 11 For example, a voltage in the voltage range of +6 V to +55 V can be provided, whereby the goal of using a single power module for different loads can be achieved to allow full utilization of resources and thereby save energy and use resources economically.

In order to protect the circuit from damage caused by overvoltage, the emergency module according to the invention comprises 11 Furthermore, an overvoltage protection module, wherein the overvoltage protection module, a second switch 6 and a third switch 7 includes, wherein the second switch 6 between the input power connection and the third switch 7 is switched, the third switch 7 between the second switch 6 and the sixth terminal Pin4 of the second chip U6 is connected, the second switch 6 and the third switch 7 when the output voltage value is too high, are turned on, wherein the level signal of the sixth terminal Pin4 and the output voltage are lowered.

The second switch 6 is concretely a Zener diode ZD1, whereby the third switch 7 is the transistor Q7, wherein the negative electrode of the Zener diode ZD1 is connected to the input power terminal and the positive electrode is connected to the base of the transistor Q7, wherein the collector of the transistor Q7 is connected to the sixth terminal Pin4, wherein Diode ZD1, if the output voltage value is too high, an electrically conductive connection is made, wherein the base of the transistor Q7 receives a high level signal and the base is made an electrically conductive connection, wherein the level signal of the sixth terminal Pin4 is lowered, the fourth Terminal Pin1 sets the transmission of the D2 Degree, ie stops, whereby the output voltage is lowered.

Please refer 3 showing a schematic exploded perspective view of the appearance of the product according to the invention formed by the emergency module of the preferred embodiment. The lamp includes a translucent cover 8th , a main body 9 , a light module 10 and an emergency module 11 , wherein the translucent cover 8th and the main body 9 combined with each other, wherein the light module 10 and the emergency module 11 interconnected and in the main body 9 are arranged.

The present invention thus provides an emergency module comprising a constant voltage module, a constant current module, a first comparator and a second comparator, wherein a power supply outputs a high level to the constant voltage module, wherein the base signal of the constant voltage module is compared with the comparison signal of the first comparator an electrical signal is output for controlling the change in the conversion ratio between the input voltage and the output voltage of the power supply, whereby the output voltage value reaches the predetermined constant voltage value, wherein the basic signal of the constant current module is compared with the comparison signal of the second comparator, wherein an electrical signal for controlling the Input current is output, whereby the input current is kept constant, wherein the constant output voltage is fed to the constant current module, wherein the input current of the constant current module s is kept constant so that the input power of the constant current module is kept constant, i. H. the output power of the constant current module is kept constant. With the technical solution of the present invention, the problem that the LED module is designed only for a load, can be solved to allow a full utilization of resources and thereby save energy.

The above description represents only a preferred embodiment of the invention and is not intended to limit the claims. All equivalent changes and modifications that can be made according to the description and the drawings of the invention by a person skilled in the art fall within the scope of the present invention.

LIST OF REFERENCE NUMBERS

1

Constant voltage module

2

first comparator

3

first switch;

4

Constant current module

5

second comparator

6

second switch

7

third switch;

8th

translucent cover

9

main body

10

light module

11

emergency module

Claims (10)

An emergency module, characterized by comprising: a constant voltage module, a constant current module, a first comparator, and a second comparator, the constant voltage module connected between a power supply and the first comparator, the constant current module connected between the constant voltage module and the second comparator, wherein the power supply outputs a high level to the constant voltage module, wherein the fundamental voltage of the constant voltage module is compared with the comparison signal of the first comparator, wherein an electrical signal for controlling the change in the conversion ratio between the input voltage and the output voltage of the power supply is output, whereby the output voltage value predetermined constant voltage value is reached, wherein the basic signal of the constant current module is compared with the comparison signal of the second comparator, wherein an electrical signal for controlling the input gsstroms, whereby the input current is kept constant, wherein one end of the output voltage is an output voltage terminal, the output voltage terminal is connected to the constant current module, wherein the constant output voltage is fed to the constant current module, wherein the input current, the input power and the output power of the constant current module be kept constant, wherein the constant current module is connected to a charging device, wherein the charging device is connected to the load to adjust the output voltage and the current according to the voltage required by the load. An emergency module according to claim 1, characterized in that the first comparator is connected to an output voltage terminal, wherein the voltage of the first comparator changes synchronously when the magnitude of the output voltage changes, wherein the comparison signal of the constant voltage means is concretely a first reference voltage value Specifically, the comparison signal of the first comparator is a voltage value of the first comparator, wherein the constant voltage module sends an electric signal for controlling the change in the conversion ratio between the input voltage and the output voltage according to the comparison result between the reference voltage and the voltage of the first comparator. Emergency module according to claim 2, characterized in that the constant voltage module is in effect a first chip U5, wherein the first terminal Pin3 is connected to the power supply, wherein the second terminal Pin5 of the first chip U5 an electrical signal for controlling the conversion ratio between the input voltage and the Output voltage sends, wherein the third terminal Pin2 of the first chip U5 has a first reference voltage and is connected to the first comparator. Emergency module according to claim 3, characterized in that the second terminal Pin5 is connected between the power supply and the output voltage terminal, the conversion ratio between the input voltage and the output voltage being 1 - D1, D1 being the Duty cycle of the first chip U5, in which an electrically conductive connection is made is, wherein the second terminal Pin5 transmits another duty cycle signal for changing the conversion ratio between the input voltage and the output voltage, wherein the conversion formula between the input voltage and the output voltage is as follows: V _O = V _IN / (1 - D1) where V _{O is} the output voltage and V _{IN is} the input voltage. Emergency module according to claim 4, characterized in that a first switch between the second terminal Pin5 and the output voltage terminal is arranged, wherein the input voltage is converted by the conversion ratio between the input voltage and the output voltage in an output voltage, wherein the first switch, when the output voltage value of the reaches predetermined voltage value, is turned on and the output voltage terminal outputs a voltage, wherein the first switch, when the output voltage value does not reach the predetermined voltage value is turned off and the output voltage terminal outputs no voltage. Emergency module according to claim 5, characterized in that the first comparator is in effect a first comparison resistor R36, wherein the first switch is concretely a first diode D9, wherein the voltage value of the first comparison resistor R36, when the output voltage value is lower than the predetermined voltage value, smaller than is the first reference voltage value and at the first diode D9, the electrically conductive connection is disconnected, whereby the output voltage terminal outputs no voltage, wherein the duty D1 of the second terminal Pin5, in which an electrically conductive connection is established, rises to a certain value, so that the Output voltage value using the conversion formula reaches the predetermined voltage value, wherein the voltage value of the first comparison resistor R36, when the output voltage value is equal to the predetermined voltage value, equal to the first reference voltage value and at the first diode D9 an electrical and the output voltage terminal outputs the predetermined voltage value, wherein the voltage value of the first comparison voltage when the output voltage value is higher than the predetermined voltage value is greater than the first reference voltage value and the duty cycle D of the second terminal Pin5, at which an electrically conductive Connection decreases to a certain value, so that the output voltage value using the conversion formula reaches the predetermined voltage value. Emergency module according to claim 1, characterized in that the constant current module is the second chip U6, wherein the input current flows into the input power terminal, wherein the fourth terminal Pin1 of the second chip U6 is connected to the output voltage terminal and the input power terminal and a duty cycle signal for controlling the size of the Output current outputs, wherein the second comparator between the output voltage terminal and the input power terminal is connected, wherein the base signal of the Konstantstromkomulset is a second reference voltage value, wherein the fifth terminal Pin6 of the second chip U6 provided with a second reference voltage and connected to the second comparator. Emergency module according to Claim 7, characterized in that the second comparator is a comparison device consisting of two resistors R37, R38 connected in parallel, the output voltage connection delivering a predetermined voltage value to the second chip U6, the input current flowing into the comparator consisting of parallel resistances, a voltage difference, namely the comparison information of the second comparator, between the two parallel resistors R37, R38 is generated, which is compared with the second reference voltage value, wherein the sent from the fourth terminal Pin1 Duty signal D2 when the voltage difference between the two parallel resistors R37, R38 is smaller than the second reference voltage value, rises to a certain value, whereby the input current reaches the predetermined current value, wherein the duty cycle signal D2 sent from the fourth terminal Pin1, when the between the two P As a result, when the current difference R37, R38 is greater than the second reference voltage value is lower than a predetermined value, the input current reaches the predetermined current value. Emergency module according to claim 1, characterized in that it further comprises an overvoltage protection module, wherein the overvoltage protection module comprises a second switch and a third switch, wherein the second switch between the input power terminal and the third switch is connected, the third switch between the second switch and the sixth terminal Pin4 of the second chip U6 is connected, wherein the second switch and the third switch are turned on when the output voltage value is too high, and the level signal of the sixth terminal Pin4 and the output voltage are lowered. Emergency module according to claim 8 or 9, characterized in that the second switch is the Z-diode ZD1, wherein the third switch is the transistor Q7, wherein the negative electrode of the Z-diode ZD1 connected to the input power terminal and the positive electrode to the base of the transistor Q7, the collector of the transistor Q7 being connected to the sixth terminal Pin4, and in the Zener diode ZD1, if the output voltage value is too high, an electrically conductive connection is established, the base of the transistor Q7 being a high level signal and an electrically conductive connection is established at the base, wherein the level signal of the sixth terminal Pin4 is lowered, the fourth terminal Pin1 setting, ie stopping, the transmission of the duty cycle signal D2, whereby the output voltage is lowered.

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