CN112229538A - Device and method for measuring temperature of femtosecond laser processing material based on thermodynamics method - Google Patents

Abstract

The invention discloses a device and a method for measuring the material temperature in a femtosecond laser processing process. The method is suitable for temperature measurement in the process of processing materials by femtosecond laser. The device is simple, convenient to operate, and the measurement is accurate reliable. The device design utilizes the basic principle of thermodynamics, the total energy of the femtosecond laser pulse entering the cavity and the work done by gas in the machining process are measured and converted to obtain the heat generated by the femtosecond laser, and the temperature in the material removing process is further calculated. The device has good gas tightness, can accurately capture, and generates the volume of gas instant expansion in the process of femtosecond laser processing. By integrating the measurements, the accuracy and reliability of the measurements is improved. The design of the upper air valve and the lower air valve ensures that the internal pressure of the cavity is standard atmospheric pressure in the processing process, thereby providing convenience for the calculation of a subsequent formula.

Description

Device and method for measuring temperature of femtosecond laser processing material based on thermodynamics method

Technical Field

The invention relates to a gas volume measurement and collection technology, and particularly provides an experimental device and method for measuring the removal temperature of a material in a femtosecond laser processing process.

Background

How to measure the temperature of a material during femtosecond laser processing has been a difficulty. And the measurement of the temperature during the material removal by laser has guiding significance for the femtosecond laser processing of the material. The existing femtosecond laser processing thermodynamic process, namely a dual-temperature model (TTM), describes the temperature evolution process when laser acts on the surface of a material, but few experiments prove the correctness of the theory convincingly. Because the theoretical predicted material temperature is difficult to measure effectively. The device provided by the invention can verify the existing theory.

The existing technical scheme is divided into two types. One is the blackbody radiation method (appl. optics.55(13),8347-8351(2016)) which estimates the temperature of a material by measuring the blackbody radiation spectrum curve inside quartz glass using planck's equation fitting. The method can only be used for measuring the temperature in the transparent material, and the measuring equipment is required to have nanosecond-level time resolution measuring capability, so the measuring difficulty is higher. Another method is to deduce the processing temperature of the material by measuring the electron density at the surface of the material by pump probing. The pumping detection method has poor measurement accuracy. In addition, the measuring instruments of the two methods are expensive, and have high requirements on the time resolution of the instruments.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a device and a method for measuring the temperature of a femtosecond laser processing material based on a thermodynamic method, wherein gas generated during processing is captured in time through two sensitive gas valves, and the volume of the generated gas is measured through a piston. And (4) obtaining the temperature in the material processing process through formula calculation. The device has the advantages of simple measurement method, high precision, no requirement on time resolution, relatively cheap instrument and device, simple structure, convenient and safe operation and suitability for femtosecond lasers with different wavelengths.

The invention is composed of a processing cavity and a gas volume measuring cylinder. The bottom of the cavity is provided with a bottom cover with good air tightness. The bottom cover is provided with an air valve which can be used for air inlet when the bottom cover is cooled after processing. And a gas valve is arranged at the part of the cavity body, which is connected with the measuring cylinder, and is used for capturing gas in the process of processing and generating gas. The amount of trapped gas is measured by the piston. And this device can measure gas accumulation volume to reach more accurate measuring effect.

The concrete technical scheme of the invention is as follows:

a temperature measuring device for a femtosecond laser processing material based on thermodynamics is characterized by comprising a cavity for placing a material to be measured, a gas measuring cylinder, an upper gas valve and a lower gas valve;

the bottom of the cavity is provided with a bottom cover, the bottom cover is provided with an air inlet, the air inlet is connected with a lower air valve, the upper part of the cavity is provided with an air outlet, the air outlet is communicated with a gas measuring cylinder through the upper air valve, and a piston with air tightness can slide in the gas measuring cylinder; and light-transmitting glass is arranged on the side surface of the cavity.

The light-transmitting glass is optical glass which is transparent to the wavelength of femtosecond laser and can be replaced.

The gas measuring cylinder is provided with volume scales.

The method for measuring the temperature by using the device for measuring the temperature of the material processed by the femtosecond laser based on thermodynamics comprises the following steps:

a. opening the bottom cover, placing the material to be detected on the bottom cover, and aligning the processing surface with the light-transmitting window;

b. closing the bottom cover to ensure the air tightness of the cavity and the gas measuring cylinder, and reading the degree of the piston in the gas measuring cylinder at the moment;

c. aligning a light-passing window to the femtosecond laser, focusing a femtosecond laser objective lens on a material to be processed, and opening light to control the pulse number and the pulse interval for measurement;

d. when the number of pulses is N, recording the degrees of the pistons at the moment, and calculating the difference of the degrees of the pistons at two times to obtain a volume V;

e. calculating the temperature T of the material to be measured during processing, wherein the formula is as follows:

T＝(U-P*V)*V_m/(C_m*V)，

wherein U is the laser pulse energy, Cm is the gas molar heat capacity, Vm is the gas molar volume at standard atmospheric pressure, and P is the standard atmospheric pressure.

The working principle of the invention is as follows:

during measurement, the bottom cover of the device is opened, the material is placed into the cavity, and the processing surface is aligned to the light-transmitting glass. And closing the bottom cover and checking the air tightness of the device. When the femtosecond laser is turned on to process the material, when the femtosecond laser is used for phosgenating the material, the pressure in the cavity is increased due to the gasification of the material, the upper valve is pushed open due to the action of the pressure, and the gas enters the measuring cylinder. When the femtosecond light action is finished, the gasified material begins to be condensed, then the pressure in the cavity is reduced, the upper valve is closed, the lower valve is opened at the moment, and the external air enters the cavity through the lower valve. The pressure in the cavity is ensured to be stabilized to the standard atmospheric pressure. The device retains the information of the gas volume through the design of the double-valve direction, so that the device has no requirement on the time resolution. The degree of the piston is more considerable through the measurement of a plurality of pulses. The accuracy of the measurement is increased.

Because the device needs to convert the measured quantity by using a formula, the formula is explained, and the process based on the action of the femtosecond laser and the material is material gasification and phase explosion. And the basic principle of thermodynamics:

U＝Q+W

wherein U is internal energy, Q is heat, and W is work. The energy provided by N pulsed femtosecond lasers acting on the material is U, the volume expansion produced by material gasification and phase explosion does work as W, and then:

U＝Q+PV

v is the measurement volume and P is the standard atmospheric pressure, assuming that at the instant the laser is acting on the material, all the heat of the material is concentrated in the vaporized material (this approximation does not hold true for picosecond light with a substantial presence of thermal effects in the crystal lattice). According to the gas heat capacity formula, the material temperature is as follows:

c is the heat capacity of the part of gas, the molar volume of the gas is Vm under a standard condition, the molar heat capacity of the gasification of the material is Cm, and then the heat capacity of the part of gas is as follows:

the material temperature can be obtained by combining the above formula, wherein V is the gas volume measured by the device:

compared with the prior art, the invention has the beneficial effects that: the device is specially used for measuring the removal temperature of the material when the femtosecond laser with any wavelength processes the material. The device is used for special optical glass which is easy to replace when passing through a light-passing window of a femtosecond laser beam, and is transparent to a selected femtosecond laser waveband. The device has good gas tightness and ensures the gas volume accuracy of the captured material. Because the design of the double gas valves records the change of the gas volume, the change of the gas volume can reflect the instant energy information. The measurement is more accurate. Compared with the existing method, the measuring instrument has no requirement on time resolution, and is cheaper. The method is simple, convenient to operate and stable in performance, and provides an efficient, reliable and accurate way for measuring the temperature of the material in the femtosecond laser processing process.

Drawings

FIG. 1 is a schematic structural diagram of a thermodynamics-based femtosecond laser processing material temperature measuring device

FIG. 2 is a diagram showing a state of use, and FIG. 2(a) is a schematic diagram showing the opening of an upper gas valve for material gasification, and arrows indicate gas flow directions; fig. 2(b) is a schematic view of the valve opening upon cooling of the gasification material, with the arrow indicating the direction of gas flow.

Detailed Description

The invention is further illustrated with reference to the following figures and examples, which should not be construed as limiting the scope of the invention.

Referring to fig. 1, fig. 1 is a view illustrating an apparatus for measuring a temperature of a material in a femtosecond laser process, in which gas valves are provided at the top and bottom of a chamber to sensitively trap gas generated during a process of gasification and maintain a pressure of the chamber.

The device comprises a device main body and a bottom cover, wherein the device main body comprises a light-transmitting window, an upper air valve and a gas measuring cylinder. The light-transmitting window is positioned on the side surface of the cavity. The upper air valve is connected with the cavity and the gas measuring cylinder, and a piston 4 is arranged in the gas measuring cylinder 3 and used for measuring the volume of gas. The bottom cover 1 is provided with a lower air valve 6 which is used for connecting the air inlet cavity and the gas measuring cylinder 3 together to ensure the air tightness. The side surface of the cavity is provided with a light-transmitting glass 8. A piston 4 is provided in the gas measuring cylinder 3 for measuring the volume of collected gas.

The device cavity comprises a bottom cover 1 of the cavity, a cavity 2, an upper valve 5, a lower valve 6, a material 7 to be measured, a light-transmitting glass 8 cavity on the side surface of the cavity and an incident femtosecond laser 9. The gas measuring part of the device comprises a gas measuring cylinder 3 and a piston 4 in the measuring cylinder.

When measurement is needed, the bottom cover 1 of the cavity is opened to place the material 7 into the cavity, and the surface to be processed faces the light-transmitting glass 8. And (3) closing the bottom cover 1, covering the cavity by hands, and if the piston of the cavity is increased by 4 degrees, indicating that the air tightness of the cavity is good. When the cavity is cooled again, the reading of the piston 4 is read. The cavity clear glass 8 is aligned to the femtosecond laser 9 while the focus is adjusted to the surface of the material 7. And introducing N pulsed femtosecond lasers. Piston 4 readings were observed to increase at this time, and the piston degrees were read at this time. The difference value of the degrees of the pistons obtained twice is V.

Reading out the total energy U of the incident femtosecond light based on the parameters of the femtosecond laser or by using a power meter, and then substituting V/N into the formula:

in (1). The temperature at which the femtosecond laser processes the material can be obtained.

Claims (4)

1. A temperature measuring device for a material processed by femtosecond laser based on thermodynamics is characterized by comprising a cavity (2) for placing the material to be measured, a gas measuring cylinder (3), an upper gas valve (5) and a lower gas valve (6);

the bottom of the cavity (2) is provided with a bottom cover (1), the bottom cover (1) is provided with an air inlet, the air inlet is connected with a lower air valve (6), the upper part of the cavity (2) is provided with an air outlet, the air outlet is communicated with the gas measuring cylinder (3) through the upper air valve (5), and a piston (4) with air tightness can slide in the gas measuring cylinder (3); and light-transmitting glass (8) is arranged on the side surface of the cavity (2).

2. The thermodynamically-based femtosecond laser processed material temperature measurement device according to claim 1, wherein: the light-transmitting glass (8) is optical glass which is transparent to the wavelength of femtosecond laser and can be replaced.

3. The thermodynamically-based femtosecond laser processed material temperature measurement device according to claim 1, wherein: the gas measuring cylinder (3) is provided with volume scales.

4. A method for measuring a temperature using the thermodynamically based femtosecond laser processing material temperature measuring apparatus according to any one of claims 1 to 3, the method comprising the steps of:

a. opening the bottom cover, placing the material to be detected on the bottom cover, and aligning the processing surface with the light-transmitting window;

b. closing the bottom cover to ensure the air tightness of the cavity and the gas measuring cylinder, and reading the degree of the piston in the gas measuring cylinder at the moment;

c. aligning a light-passing window to the femtosecond laser, focusing a femtosecond laser objective lens on a material to be processed, and opening light to control the pulse number and the pulse interval for measurement;

d. when the number of pulses is N, recording the degrees of the pistons at the moment, and calculating the difference of the degrees of the pistons at two times to obtain a volume V;

e. calculating the temperature T of the material to be measured during processing, wherein the formula is as follows:

T＝(U-P*V)*V_m/(C_m*V)，

wherein U is the laser pulse energy, Cm is the gas molar heat capacity, Vm is the gas molar volume at standard atmospheric pressure, and P is the standard atmospheric pressure.

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