RU106804U1 - LASER POWER SUPPLY - Google Patents

Abstract

 1. The laser power supply unit containing a power source, a first temperature sensor, a control device, the input of which is electrically connected to the output of the first temperature sensor, and the output is electrically connected to the input of the power source, characterized in that it is equipped with a second temperature sensor and an electric power unit for the heater of the active laser element, whose input is electrically connected to the output of the second temperature sensor. ! 2. The laser power supply unit according to claim 1, characterized in that the electric power supply unit of the heater of the active laser element includes a comparison device and a key, while the output of the second thermal sensor is electrically connected to the input of the comparison device, the output of which is electrically connected to the control terminal of the key.

Description

The utility model relates to power electronics, in particular to power sources, and can be used to create laser power sources.

A known laser power supply (PSU) [1], including a power source, a control device, the output of which is electrically connected to the input of the power source, a temperature sensor.

The power source contains a constant voltage stabilizer, the control device is made on a resistive voltage divider, a thermal resistance is used, which is located in the resistive voltage divider circuit of the control device.

With increasing ambient temperature, the resistance of the temperature sensor increases, the division coefficient of the resistive voltage divider increases, which causes an increase in the voltage supplied to the input of the control device, from which an increased signal is input to the input of the power source, causing a corresponding increase in its output voltage and laser pump power.

In connection with the use of a resistive voltage divider and one thermal resistance in the control device, the described PSU has a narrowed linear temperature range for regulating the supply voltage, and, accordingly, the laser pump power.

A wider temperature range for regulating the supply voltage, and accordingly, the laser pump power, has a BP described in [2], which is the closest in technical essence and the achieved result and selected as a prototype.

BP [2] includes a power source, a temperature sensor, a control device, the output of which is electrically connected to the input of the power source, and the input is electrically connected to the output of the temperature sensor.

The control device is made on a resistive voltage divider; two thermal resistors are used as part of the temperature sensor, which are located in the resistive voltage divider circuit of the control device.

With an increase in the ambient temperature, the resistance of the temperature sensors increases, the division coefficient of the resistive voltage divider increases, which causes an increase in the voltage supplied to the input of the control device, from which an increased signal is supplied to the input of the power source, causing a corresponding increase in its output voltage and laser pump power.

In connection with the use of a resistive voltage divider with two thermal resistances in the control device, which have significantly different temperature dependences, the described PSU has a wider temperature range for regulating the supply voltage, and, accordingly, the laser pump power.

However, the indicated PSU [2] does not allow turning on the electric power of the heater of the active laser element (EPNAL) at a temperature lower than fixed.

The objective of this utility model is to expand the functionality of the laser power supply by providing a heating mode for the active laser element while lowering the temperature of the active element below a fixed one.

The essence of the utility model is that the laser power supply unit containing a power source, a first temperature sensor, a control device, the input of which is electrically connected to the output of the first temperature sensor, and the output is electrically connected to the input of the power source, is equipped with a second temperature sensor and an electric power unit for the heater of the active element a laser whose input is electrically connected to the output of the second temperature sensor.

It is possible to perform an electric power unit for the heater of the active laser element, including a comparison device and a key, while the output of the second temperature sensor is electrically connected to the input of the comparison device, the output of which is electrically connected to the control terminal of the key.

The introduction of a second thermal sensor and an electric power supply unit for the heater of the active laser element into the power supply unit, the input of which is electrically connected to the output of the second thermal sensor, allows you to expand the functionality of the laser power unit by providing a heating mode for the active laser element when the temperature of the active element is lower than fixed.

The implementation of the electric power supply unit of the heater of the active laser element, including the comparison device and the key, where the output of the second temperature sensor is electrically connected to the input of the comparison device, the output of which is electrically connected to the control output of the key, allows you to create a simple circuit of the electric power supply unit of the heater of the active laser element.

The essence of the utility model is illustrated in the drawing.

The figure shows a functional diagram of a power supply unit with a connected laser, on which elements not included in the power supply unit are indicated by a dotted line.

The PSU contains a laser power supply 1, the first 2 and second 3 temperature sensors, a control device 4, the input of which is electrically connected to the output of the first temperature sensor 2, and the output is electrically connected to the input of the laser power supply 1, electric heater block 5 of the active laser element heater, the input of which electrically connected to the output of the second temperature sensor 3.

Power source 1 is a current generator on an IR2104SPBF chip, has a current adjustment in the range from 0 to 7A. The power source 1 provides a constant laser pump current, the laser diode 6 is used as a radiating element.

As the first temperature sensor 2, the LM135AH microcircuit is used, mounted on the housing of the laser emitter 7 and located in the circuit of the resistive DC voltage divider.

As the second temperature sensor 3, the LM135AH microcircuit is used, installed on the power supply board 1 and located in the circuit of the resistive DC voltage divider.

The control device 4, the output of which is electrically connected to the input of the power source 1, provides a control signal to the input of the power source 1.

Functionally, the control device 4 includes a comparison device 8 on the LM397MF and LMC7101AIM5 microcircuits, a resistive divider with resistors 9 and 10, two comparison devices 11 and 12, each of which is made on the LMC7101AIM5 microcircuit, and a matching device 13 with "current mirrors" on two ICs BCV62B. The comparison device 11 is designed to compare the signal from the temperature sensor 2 with the lower reference voltage and operates at temperatures below the first set value. The comparison device 12 is designed to compare the signal from the temperature sensor 2 with the upper reference voltage and operates at temperatures above the second set value. The outputs of the comparison devices 11 and 12 are connected with the corresponding inputs of the matching device 13, from the output of which the total current signal is supplied to the variable resistor 9 of the control device 4.

The resistive divider with resistors 9 and 10 is supplied with a reference voltage U _op1 , while the signal from the variable resistor 9 is supplied to the input of the comparison device 8.

The electric power supply unit 5 of the heater of the active element of the laser, the input of which is electrically connected to the output of the second temperature sensor 3, includes a comparison device 14 on the LMC7101AIM5 chip, the input of which is electrically connected to the output of the second temperature sensor 3, and the output is electrically connected to the control output of the key 15 on the transistor IRLR024NPBF. The first power output of the key 15 is electrically connected to the output of the negative direct voltage U _{0 of the} constant voltage source (not shown), the second power output of the key 15 is electrically connected to the first output of the heater 16 (the resistor RT020F100R 5% is used as an active element) of the active laser element, the second output which is electrically connected to the output of a positive constant voltage U ₀ source of constant voltage.

Another embodiment of the electric power supply unit 5 of the heater 16 of the active laser element is also possible.

BP works as follows.

While the case of the laser emitter 7 has a temperature that is within certain limits above the first set and below the second set, the signal from the output of the temperature sensor 2 is also in a certain range above the lower threshold and below the upper threshold value. In this case, the comparison devices 11 and 12 of the control device 4 are turned off. The currents of the comparison devices 11 and 12 supplied to the input of the matching device 13 are equal to zero, the total current from the output of the matching device 13 supplied to the variable resistor 9 is zero. The input of the comparison device 8 receives a constant signal from a variable resistor 9, determined by flowing through a resistive divider with resistors 9 and 10, the current of the reference voltage source U _op1

Comparison device 8 generates a constant control signal that is independent of temperature and arrives from the output of control device 4 to the input of power source 1. Power source 1 provides a constant laser pump power, in our case, a constant pump current of a laser diode 6.

As soon as the temperature of the housing of the laser emitter 7 becomes lower than the first set, the signal of the temperature sensor 2 supplied to the input of the control device 4 will be less than the lower threshold value.

With a lower lower threshold value, the signal of the temperature sensor 2 is triggered by the comparison device 11, which increases the output current supplied through the matching device 13 to the variable resistor 9. The comparison device 12 is turned off and its output current is zero. The total current from the output of the matching device 13, supplied to the variable resistor 9, is greater than zero. The increased constant signal from the variable resistor 9, determined by the total current of the reference voltage source U _opt1 and the output current of the matching device 13 flowing through the variable resistor 9, flows through the resistor 9, and the comparison device 8 compares this signal with reference and increases the signal from the output of the control device 4, supplied to the input of the power source 1.

The power source 1 in this case increases the pump power of the laser, in our case, the constant pump current of the laser diode 6.

As soon as the temperature of the housing of the laser emitter 7 becomes higher than the second set, the signal of the temperature sensor 2, which is input to the control device 4, will be higher than the upper threshold value.

With a higher upper threshold value, the signal of the temperature sensor 2 is triggered by the comparison device 12, which increases the output current supplied through the matching device 13 to the variable resistor 9. The comparison device 9 is turned off and its output current is zero. The total current from the output of the matching device 13, supplied to the variable resistor 9, is greater than zero. The increased constant signal from the variable resistor 9, determined by the total current of the reference voltage source U _opt1 and the output current of the matching device 13 flowing through the variable resistor 9, flows through the resistor 9, and the comparison device 8 compares this signal with reference and increases the signal from the output of the control device 4, supplied to the input of the power source 1.

The power source 1 in this case increases the pump power of the laser, in our case, the constant pump current of the laser diode 6.

As soon as the ambient temperature of the active element of the laser becomes lower or equal to a certain value, the signal of the temperature sensor 3 supplied to the input of the electric power supply unit 5 of the heater of the active laser element will be less than the set minimum value. A comparison device 14, comparing this signal with the reference one, is triggered, and a signal that opens the key 15 is supplied to the control output of the key 15. The key 15 closes the power circuit of the heater 16 (resistor) of the active laser element, which heats up and heats the active laser element.

Thus, it is possible to expand the functionality of the laser power supply by providing a heating mode for the active laser element while lowering the temperature of the active element below a fixed one.

Sources of information used:

1. Shmelev K.D., Korolev G.V. Laser power supplies. - M. Energoizdat, 1981. - S. 91-92.

2. Shmelev KD, Korolev GV Laser power supplies. - M. Energoizdat, 1981. - S. 96-98 (prototype).

Claims (2)

1. The laser power supply unit containing a power source, a first temperature sensor, a control device, the input of which is electrically connected to the output of the first temperature sensor, and the output is electrically connected to the input of the power source, characterized in that it is equipped with a second temperature sensor and an electric power unit for the heater of the active laser element, whose input is electrically connected to the output of the second temperature sensor. 2. The laser power supply unit according to claim 1, characterized in that the electric power supply unit for the heater of the active laser element includes a comparison device and a key, while the output of the second thermal sensor is electrically connected to the input of the comparison device, the output of which is electrically connected to the control terminal of the key.