CN111982900B - Experimental method for controlling cooling mode of wire thermal simulation sample - Google Patents

Abstract

The invention relates to an experimental method for controlling a cooling mode of a wire thermal simulation sample, which comprises the following steps: 1) Processing a sample; 2) 2 thermocouples are welded in the middle of the sample; 3) Clamping the sample on a clamp, and connecting a thermocouple with a temperature measuring system; 4) Setting an experimental mode and conditions: 5) Performing a thermal simulation experiment, and recording temperature data of a sample in the heating and cooling processes; 6) And selecting a metal tissue of the sample at the position of 1-1.5 mm deep inside the thermocouple for observation. The invention can carry out thermal simulation experiment on natural cooling or forced air cooling of the wire rod, has simple and easy method, and meets the requirement of manufacturing enterprises on the controlled cooling of the wire rod tissue for the simulation experiment research.

Description

An experimental method for controlling the cooling mode of wire thermal simulation specimens

Technical field

The invention relates to the technical field of thermal simulation experiments, and in particular to an experimental method for controlling the cooling mode of a wire thermal simulation sample.

Background technique

Thermal simulation experimental machines are widely used in materials science research. They can simulate the structural change characteristics of metal materials under different processing conditions, and are of great significance for revealing the structural transformation rules of materials. In the thermal simulation experiment, the sample is heated under the clamping of the chuck, and then undergoes operations such as heat preservation, deformation, and cooling, so that the sample obtains different organizational states.

In actual production, the cooling after wire rod rolling is usually natural cooling or air-cooling forced cooling. The specimens used for thermal simulation experiments are small and naturally cool quickly under the clamping of the chuck. Generally, it is necessary to control the cooling mode of the specimen by auxiliary heating of the specimen. This method is difficult to reveal. The cooling characteristics of the sample in the natural cooling state. Therefore, it is necessary to develop a simple simulation experiment method on a thermal simulation experimental machine, so that it can conduct thermal simulation experiments on natural cooling or forced air cooling of wires, so that the thermal simulation experiments can be closer to the actual conditions at the production site.

The Chinese patent application with application number CN201410229626. This detection method is to make the material into a cylindrical sample with length L ₀ and diameter d ₀ in the thermal simulation experiment and place it in the thermal simulation experimental machine. The axial temperature gradient of the sample is controlled to obtain a length of 0 in the middle. l ₀ uniform temperature zone, control deformation and controlled cooling of the uniform temperature zone, the middle part of the sample after the experiment is drum-shaped; the sample after the experiment can be made into metallographic, tensile, impact and other testing samples, It can not only observe the structural characteristics of materials under different process conditions, but also detect its strength, hardness and plastic toughness indicators. This technical solution can solve the problem of difficulty in measuring material strength and plasticity after thermal simulation experiments, and provides an accurate and reliable method for material research and thermal processing process development. However, this technical solution does not involve the method of simulating natural cooling of the specimen or forced cooling by air cooling.

Contents of the invention

The present invention provides an experimental method for controlling the cooling mode of a wire rod thermal simulation sample, which can conduct thermal simulation experiments on natural cooling or forced air cooling of the wire rod. The method is simple and easy to implement, and satisfies the production enterprise to simulate controlled cooling of the wire rod structure. Requirements for experimental research.

In order to achieve the above objects, the present invention adopts the following technical solutions:

An experimental method for controlling the cooling mode of wire thermal simulation specimens, including the following steps:

1) Sample processing: Multiple samples processed from wire rods into cylinders of different diameters are polished to make the surface of the sample show a metallic luster;

2) Weld 2 thermocouples in the middle of the sample;

3) Clamp both ends of the sample to the corresponding fixtures, and connect the signal output end of the thermocouple to the temperature measurement system;

4) Set the experimental method and conditions:

4a) The heating temperature of the sample is 900~1000℃, and the temperature is maintained for 50~90s;

4b) Simulate the natural cooling or forced air cooling of the wire through samples of different diameters; specifically: when the sample cooling rate is set to 2~10°C/s, select a sample with a diameter of 16~25mm; when When the sample cooling rate is set to 11 to 20°C/s, select a sample with a diameter of 8 to 15mm; when the sample cooling rate is set to 21°C/s or above, select a sample with a diameter of 5 to 7mm;

Or use samples of different diameters to simulate the two cooling methods of the wire with or without the inverse temperature platform; specifically: when the simulated cooling method is without the inverse temperature platform, select the sample diameter to be 5 ~ 7mm; when the simulated cooling method is to have an inverse temperature platform, select the sample diameter to be 14~25mm;

5) Conduct thermal simulation experiments and record the temperature data of the sample heating and cooling processes;

5a) Thermal simulation experiment without thermal compression: heat the sample to 900~1000℃ and keep it for 50~90s to fully austenitize the sample; then cut off the power and allow the sample to cool naturally in a vacuum state; pass Samples of different diameters can simulate natural cooling or forced air cooling of wires;

5b) Conduct a thermal simulation experiment of hot compression: heat the sample to 900~1000℃ and keep it for 50~90s to fully austenitize the sample; then conduct a hot compression experiment and control the deformation rate to 5~20s ^-1 . The deformation amount is 10% to 30%; then the power is turned off to allow the sample to cool naturally in a vacuum state; through samples of different diameters, the simulation of natural cooling or forced air cooling of the wire is realized;

6) After the sample is cooled, select the metal structure located inside the thermocouple with a depth of 1 to 1.5 mm for observation; grind and polish the sample to obtain a metallographic sample, using a mass concentration of 3% to 5 % nitric acid alcohol solution to corrode the metallographic sample, and conduct metallographic observation under a metallographic microscope with a magnification of more than 500 times.

The length of the sample is 10 to 20 mm.

In step 6), the thermally simulated sample is first mounted so that the thermocouple is positioned on the surface of the sample; and then the thermally simulated sample is ground inward from the thermocouple position using 80 to 150 grit sandpaper. Dropped 1~1.5mm.

Compared with the prior art, the beneficial effects of the present invention are:

1) It can conduct thermal simulation experiments on natural cooling or forced air cooling of wires. The method is simple and easy to implement, which meets the requirements of production enterprises for simulation experimental research on controlled cooling of wire structures;

2) By selecting samples of different diameters, the simulation of different cooling rates of the wire can be achieved. Moreover, this simulation is closer to the actual situation of on-site production, and can more truly reflect phenomena such as the latent heat release of phase change in the wire during the cooling process. This is similar to the way that ordinary thermal simulation samples use electric heating compensation to control the temperature of the sample cooling process. ratio has significant differences.

Description of the drawings

Figure 1 is a schematic diagram of the principle of an experimental method for controlling the cooling mode of a wire thermal simulation sample according to the present invention.

In the picture: 1. Sample 2. Fixture 3. Thermocouple 4. Temperature measurement system

Detailed ways

The specific embodiments of the present invention will be further described below in conjunction with the accompanying drawings:

An experimental method for controlling the cooling mode of wire thermal simulation specimens, including the following steps:

1) Sample processing: Multiple samples processed from wire rods into cylinders of different diameters are polished to make the surface of the sample show a metallic luster;

2) Weld 2 thermocouples in the middle of the sample;

3) As shown in Figure 1, clamp both ends of sample 1 on the corresponding fixture 2, and connect the signal output end of thermocouple 3 to temperature measurement system 4;

4) Set the experimental method and conditions:

4a) The heating temperature of the sample is 900~1000℃, and the temperature is maintained for 50~90s;

4b) Simulate the natural cooling or forced air cooling of the wire through samples of different diameters; specifically: when the sample cooling rate is set to 2~10°C/s, select a sample with a diameter of 16~25mm; when When the sample cooling rate is set to 11 to 20°C/s, select a sample with a diameter of 8 to 15mm; when the sample cooling rate is set to 21°C/s or above, select a sample with a diameter of 5 to 7mm;

Or use samples of different diameters to simulate the two cooling methods of the wire with or without the inverse temperature platform; specifically: when the simulated cooling method is without the inverse temperature platform, select the sample diameter to be 5 ~ 7mm; when the simulated cooling method is to have an inverse temperature platform, select the sample diameter to be 14~25mm;

5) Conduct thermal simulation experiments and record the temperature data of the sample heating and cooling processes;

5a) Thermal simulation experiment without thermal compression: heat the sample to 900~1000℃ and keep it for 50~90s to fully austenitize the sample; then cut off the power and allow the sample to cool naturally in a vacuum state; pass Samples of different diameters can simulate natural cooling or forced air cooling of wires;

5b) Conduct a thermal simulation experiment of hot compression: heat the sample to 900~1000℃ and keep it for 50~90s to fully austenitize the sample; then conduct a hot compression experiment and control the deformation rate to 5~20s ^-1 . The deformation amount is 10% to 30%; then the power is turned off to allow the sample to cool naturally in a vacuum state; through samples of different diameters, the simulation of natural cooling or forced air cooling of the wire is realized;

6) After the sample is cooled, select the metal structure located inside the thermocouple with a depth of 1 to 1.5 mm for observation; grind and polish the sample to obtain a metallographic sample, using a mass concentration of 3% to 5 % nitric acid alcohol solution to corrode the metallographic sample, and conduct metallographic observation under a metallographic microscope with a magnification of more than 500 times.

The length of the sample is 10 to 20 mm.

In step 6), the thermally simulated sample is first mounted so that the thermocouple is positioned on the surface of the sample; and then the thermally simulated sample is ground inward from the thermocouple position using 80 to 150 grit sandpaper. Dropped 1~1.5mm.

The following examples are implemented on the premise of the technical solution of the present invention and provide detailed implementation modes and specific operating processes. However, the protection scope of the present invention is not limited to the following examples. The methods used in the following examples are conventional methods unless otherwise specified.

[Example]

In this embodiment, an experimental method for controlling the cooling mode of a wire thermal simulation sample is as follows:

1) Sample processing: Process the wire sample to be simulated into cylinders with a length of 15mm and different diameters. The processed sample is then polished to make the surface of the sample show a metallic luster for welding of the thermocouple. The surface of the sample must be free from rust and other phenomena to prevent inaccurate temperature measurement due to weak thermocouple welding or the thermocouple falling off in the high-temperature area of the sample.

2) Weld two thermocouples in the middle of the sample, and check whether the thermocouples are welded firmly to prevent inaccurate temperature measurement of the sample.

3) Clamp both ends of the sample in the two clamps at the corresponding ends, and connect the thermocouple cable to the connector of the temperature measurement system. Check whether the connection between the thermocouple and the temperature measurement system is correct to prevent measurement data from appearing. Invalid phenomena occur;

4) According to the actual conditions of the production site, set the heating temperature, cooling rate, cooling method and other parameters of the sample, and select a sample with an appropriate diameter based on this to meet the organizational state of the sample under simulated site conditions. changes in the need for simulation studies. details as follows:

4a) Set the heating temperature of the sample to 900°C and keep it warm for 60 seconds;

4b) Set the cooling rate of the sample: Set the cooling rate of the sample as:

Example 1: The cooling rate of the sample is 22°C/s, the diameter of the sample is selected to be 5mm, and the length is 15mm;

Example 2: The cooling rate of the sample is 15°C/s, the diameter of the sample is selected to be 8mm, and the length is 15mm;

Example 3: The cooling rate of the sample is 12°C/s, the diameter of the sample is selected to be 12mm, and the length is 15mm;

Example 4: The cooling rate of the sample is 6°C/s, the diameter of the sample is selected to be 18mm, and the length is 15mm;

4c) Determine the simulated cooling method of the sample according to the diameter of the sample:

Example 1: There is no inverse temperature platform;

Example 2-Example 4: There is a temperature inversion platform;

Samples with different diameters have different simulated cooling methods. Based on this, if you want to conduct experiments with two simulated cooling methods, with and without an inverse temperature platform, you can also select samples with different diameters.

5) Conduct thermal simulation experiments on the sample and record the temperature data during the heating and cooling process of the sample;

5a) Thermal simulation experiment without thermal compression: heat the sample to 900°C and hold it for 60 seconds to fully austenitize the sample. Then the power is turned off, allowing the sample to be naturally cooled in a vacuum state, and the simulation of natural cooling or forced air cooling of the wire is realized through samples of different diameters.

5b) Conduct a thermal simulation experiment of thermal compression: heat the sample to 900°C and hold it for 60 seconds to fully austenitize the sample. Then conduct a thermal compression experiment on the sample, with a deformation rate of 5 to 20s ^-1 and a deformation amount of 10% to 30%. Then the power is turned off to allow the sample to cool naturally in a vacuum state. Through samples of different diameters, the wire can be naturally Simulation of cooling or forced air cooling.

6) After the sample is cooled, select the metal structure at a depth of 1.2mm below the thermocouple for observation. First, the thermally simulated sample is mounted so that the thermocouple is positioned on the surface of the sample. Then use No. 80 sandpaper to remove 1.2mm from the thermocouple position on the thermally simulated sample. Grind the sample with No. 500, No. 800, and No. 1000 sandpaper in sequence. After polishing the sample, the metallographic sample was etched with a 4% nitric acid alcohol solution and observed under a 500x metallographic microscope.

The above are only preferred specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto. Any person familiar with the technical field can, within the technical scope disclosed in the present invention, implement the technical solutions of the present invention. Equivalent substitutions or changes of the inventive concept thereof shall be included in the protection scope of the present invention.

Claims (2)

1. An experimental method for controlling the cooling mode of wire thermal simulation specimens, which is characterized by including the following steps: 1) Sample processing: Multiple samples processed from wire rods into cylinders of different diameters are polished to make the surface of the sample show a metallic luster; 2) Weld 2 thermocouples in the middle of the sample; 3) Clamp both ends of the sample to the corresponding fixtures, and connect the signal output end of the thermocouple to the temperature measurement system; 4) Set the experimental method and conditions: 4a) The heating temperature of the sample is 900~1000℃, and the temperature is maintained for 50~90s; 4b) Simulate the natural cooling or forced air cooling of the wire through samples of different diameters; specifically: when the sample cooling rate is set to 2~10°C/s, select a sample with a diameter of 16~25mm; when When the sample cooling rate is set to 11 to 20°C/s, select a sample with a diameter of 8 to 15mm; when the sample cooling rate is set to 21°C/s or above, select a sample with a diameter of 5 to 7mm; Or use samples of different diameters to simulate the two cooling methods of the wire with or without the inverse temperature platform; specifically: when the simulated cooling method is without the inverse temperature platform, select the sample diameter to be 5 ~ 7mm; when the simulated cooling method is to have an inverse temperature platform, select the sample diameter to be 14~25mm; 5) Conduct thermal simulation experiments and record the temperature data of the sample heating and cooling processes; 5a) Thermal simulation experiment without thermal compression: heat the sample to 900~1000℃ and keep it for 50~90s to fully austenitize the sample; then cut off the power and allow the sample to cool naturally in a vacuum state; pass Samples of different diameters can simulate natural cooling or forced air cooling of wires; 5b) Conduct a thermal simulation experiment of hot compression: heat the sample to 900~1000℃ and keep it for 50~90s to fully austenitize the sample; then conduct a hot compression experiment and control the deformation rate to 5~20s ^-1 . The deformation amount is 10% to 30%; then the power is turned off to allow the sample to cool naturally in a vacuum state; through samples of different diameters, the simulation of natural cooling or forced air cooling of the wire is realized; 6) After the sample is cooled, select the metal structure located inside the thermocouple with a depth of 1 to 1.5 mm for observation; first, mount the sample after thermal simulation so that the thermocouple is positioned on the surface of the sample; then use 80 Grind the thermally simulated sample 1 to 1.5 mm inward from the thermocouple position with ~150-grit sandpaper; grind and polish the sample to obtain a metallographic sample, using a mass concentration of 3% to 5%. The metallographic sample is etched with a nitric acid alcohol solution, and metallographic observation is carried out under a metallographic microscope with a magnification of more than 500 times. 2. An experimental method for controlling the cooling mode of a wire thermal simulation sample according to claim 1, characterized in that the length of the sample is 10 to 20 mm.