RU2363940C2 - Device to measure thermomechanical characteristics of thermoplastic materials - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: proposed invention relates to testing equipment. The device comprises fixed base for tested material to be positioned thereon, system to load penetrator fixed on the rod, penetrator travel control system, specimen deformation degree metre and penetrator. Afore mentioned devices and systems are mounted to perform joint motion in guides, along the device vertical axis towards the specimen to be tested. The device comprises additionally the specimen initial temperature control system, penetrator individual heating unit provided with penetrator heating temperature control and system to regulate penetrator heating conditions according to preset program. The system to load penetrator incorporates the one-test load stabilisation appliance that allows modifying it depending upon test. Aforesaid appliance represents a load correction preset-program device.

EFFECT: possibility to measure thermo mechanical characteristics at material dynamically increasing temperatures; simplified method.

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Description

The present invention relates to the field of testing equipment, in particular to devices for determining the physicomechanical characteristics of materials, and can be used to determine the thermomechanical characteristics of thermoplastic materials.

A device for determining the strength properties of materials, containing means for placing a test specimen, an indenter, an indenter drive mechanism and means for registering strength indicators of samples (RF patent No. 2142617, IPC G01N 3/40, publ. 10.12.1999, BI No. 34 / 1999).

A disadvantage of the known device is the complexity of the measurements, the inability to determine the thermomechanical parameters of the samples and the operational registration of indicators of a multiple batch of samples during group control tests.

It is known as a prototype of the proposed device that includes a base, a system for positioning samples, an indenter loading system and the indenter itself, a heating and cooling system for samples, control mechanisms for linear movements of samples (RF patent No. 21447737, IPC G01N 3/42, publ. 20.04. 2000, BI 11/2000).

The disadvantages of the prototype are the relatively high duration of the measurement process due to the need for prolonged heating of the entire sample, the complexity of the measurements, the inability to quickly record the performance of multiple batches of samples during group control tests under conditions of dynamically increasing temperatures.

The objective of the authors of the invention is to develop a device for measuring the thermomechanical characteristics of thermoplastic materials, which allows you to quickly and accurately determine the thermomechanical parameters of thermoplastic materials in a wide range of increasing test temperatures (-50 ° C - + 200 ° C).

A new technical result provided by using the proposed device lies in the possibility of measuring the thermomechanical characteristics of materials under conditions of dynamically increasing temperatures of the material under study and increasing the efficiency of multiple measurements, as well as simplifying the measurement process.

These tasks and a new technical result are achieved by the fact that the known device for measuring the thermomechanical characteristics of thermoplastic materials, containing a fixed base with means for positioning a sample of the test material, an indenter loading system mounted on a rod, an indenter movement control system and an indenter proper, which are installed with the possibility of their joint movement along the guides along the vertical axis of the device towards the sample of the studied mother la, indenter movement system, indicator-meter of the indenter penetration into the sample, in accordance with the proposed, it is additionally equipped with a system for controlling the initial temperature of the sample, an individual indenter heating unit, which is equipped with sensors for controlling the indenter heating temperature and a system for regulating the indenter heating mode according to a given program, and the indenter loading system is equipped with a means of stabilizing the load during one test and with the possibility of its variation from experience to experience, Making a device with a predetermined program load correction (p, m) = const.

The proposed device is illustrated as follows.

A device for measuring the thermomechanical characteristics of thermoplastic materials consists of an indenter, indenter loading systems, a heating and cooling system, a temperature measuring system and indenter movement.

The drawing shows a General diagram of the proposed device mounted on a common rack (frame), where 1 is a fixed base, 2 - guides, 3 - fixed crosshead. The guides 2 are moved by a movable traverse 4, which serves as a guide as part of the indenter movement system and can be fixed in a predetermined position. On the upper plane of the movable crosshead 4, a loading device 6 of a mechanical (spring mechanism) or hydraulic (piston mechanism) type is installed, with the help of which the necessary constant load of the indenter 12 is provided, supported and controlled by the device 7 as a means of stabilizing the load.

All nodes and mechanisms of the proposed device are mounted on a common rack with the possibility of their joint movement with the indenter along the guides along the vertical axis of the device in the direction of the sample of the material under study.

The device 7 can be made in the form of an electrical or mechanical device with a given program for correcting the load in terms of mass (m) or pressure (p): (p, m) = const.

Sample 15 is installed in the chamber 14 using positioning means, rigidly fixing them on the fixed base of the device.

On the lower plane of the movable crosshead, displacement sensors 8 are installed as a system for controlling the indenter movements, in the immediate vicinity of which a heater 13 is installed, which is mounted inside the heat-insulating casing as part of the individual heating system of the indenter 12.

The individual indenter heating system includes a heater, means for regulating and recording heating parameters.

The set initial temperature of the sample is provided by the temperature control unit 17, respectively, and the initial temperature of the sample is provided by the control unit 16. Controlled parameters (the amount of indenter penetration as the temperature of the indenter increases) are recorded by means of the device 18.

On the base of the rack (frame), a chamber 14 is installed for heating or cooling the sample as a system for controlling the initial temperature of the sample in which the test sample 15 is placed.

As a system for measuring the degree of deformation of the sample, sensors 8 and an indicator-meter of the indenter penetration into the sample associated with 7 (not shown) are used.

The device operates as follows.

Initially, the test sample 15 is placed in the chamber 14 and rigidly fixed with the camera on the fixed base of the device. After that, the movable yoke 4 together with the indenter 12 in the assembly is lowered until the indenter contacts the sample 15, after which the movable yoke 4 is rigidly fixed on the guides 2.

Then, using the control device 16, the sample is heated (or cooled) to a predetermined initial temperature T _о , which is maintained constant during the experiment.

The loading device 6 creates the necessary load and fixes the initial depth of penetration of the indenter into the sample 15. Using the software control device of the indenter temperature control system, the heating mode and the maximum heating temperature of the indenter are set.

The operation of the individual indenter heating implemented in the proposed device and the use of a set of means for heating and regulating the latter according to a given program of dynamically increasing temperatures of the test material provide an increase in the accuracy of measuring the thermomechanical characteristics of the test heterogeneous materials due to localization of heating only in the measured zone and reduce energy costs and the duration of the process .

This approach allows you to easily measure in a wide temperature range (from -50 ° C to ... + 200 ° C), because provides autonomy to maintain and control the temperature of the sample and indenter.

The indenter temperature is monitored throughout the experiment with recording its changes by recording the thermomechanical curves in the form of a diagram ΔL = f (T ° C).

The magnitude of the indenter penetration into the sample is controlled using displacement sensors 8. During the test, the temperature of the indenter penetration depth is recorded (for a given constant load).

When reaching the maximum set temperature, the power to the heaters 16 and 17 of the measuring devices is turned off and the load is removed from the indenter.

Thus, the proposed device in comparison with the prototype is distinguished by the ability to measure the thermomechanical characteristics of materials under conditions of dynamically increasing temperatures, simplicity, a wide temperature range of studies of thermomechanical curves (from -50 ° C to ... + 200 ° C), the speed of obtaining experimental data and minimal ( local and superficial) damage to the studied samples.

The industrial applicability of the proposed device is confirmed by the following example implementation

Example

In laboratory conditions, an experimental prototype of the claimed device is used, shown in the drawing, where 1 is a fixed base, 2 are guides, 3 is a fixed crosshead. A movable traverse 4 moves along the guides 2, as part of a system for moving a spherical indenter, which can be fixed in the required position using, for example, four nuts 5. On the upper plane of the movable traverse 4, a mechanical type load device 6 is installed in the form of a preloaded spring mechanism, using which provides the necessary constant load of the indenter 12, supported and controlled by the device 7 as a means of stabilizing the load. The device 7 is made in the form of a spring mechanism, the degree of which is tightened is adjusted taking into account the signal of the sensor 8.

Before installing the sample 15 in the chamber 14, made in the form of a thermocryocamera, which allows you to expand the range of the initial low temperatures, it is necessary to rotate the four nuts 5 counterclockwise to raise the movable crosshead 4 to a height sufficient to remove the cover 19 of the thermocryocamera 14 and install the sample in it 15. In the conditions of the example used a sample of polystyrene.

After installing the sample and cover 19, the movable crosshead 4 together with the indenter 12 (assembled) is lowered using the lower nuts 5 until the indenter contacts the specimen, after which the movable crosshead 4 is rigidly fixed to the guides 2 by rotating the upper nuts 5. clockwise. the load on the indenter, controlled by instrument 7, should not exceed 2% of the expected working load, and displacement sensors 8, depending on their design, should show the initial value (taken as zero), from which it will produce I'm counting down the value of the implementation of the indenter.

Two displacement sensors 8, the measuring tips 9 of which are supported by a support disk 10, rigidly connected to the power rod 11 of the indenter 12, on which the heater 13 of the indenter 12 is mounted, are installed on the lower plane of the moving beam.

The heating system includes an electric heater located on the indenter 12, the indenter itself and control means, which are mounted inside the heat-insulating casing.

The operation of the system is controlled by sensors for monitoring the temperature of the indenter heating and the control system of the indenter heating mode according to a given program.

The predetermined initial temperature of the sample is provided by temperature control units 16, and the indenter heating according to the program of dynamically increasing temperatures is provided by unit 17. Controlled parameters (the amount of indenter penetration with increasing indenter temperature) are recorded on a two-coordinate device 18 in the form of a dependence ΔL = f (T), where ΔL is the indenter penetration, T is the measurement temperature.

The loading device 6 creates the necessary load and fixes the initial penetration depth of the indenter into the sample 15. Using the software control device (type RU-01M), the heating mode (0.1-2 ° C / min) and the maximum heating temperature are set.

The indenter temperature is monitored throughout the experiment using an instrument of the KSP type or by a two-coordinate instrument 18 during the recording of the diagram ΔL = f (T ° C).

The magnitude of the indenter penetration into the sample is controlled using displacement sensors of the 19801 type or using a digital raster system for linear measurements. Discrete control of implementation is also possible with the use of mechanical indicators with a sensitivity of 1 μm.

During the test, it is recorded either discretely (after 5 ° C) or continuously the temperature dependence of the indenter penetration depth (for a given constant load).

When reaching the maximum set temperature, the power to the heaters 16 and 17 of the measuring devices is turned off and the load is removed from the indenter.

The test results are shown in table 1.

As shown by experimental checks of the proposed device, it was possible to measure the thermomechanical characteristics of materials under conditions of dynamically increasing temperatures in the range from -50 ° C to + 200 ° C, increase the efficiency of multiple measurements, expand the temperature range of tests, and also simplify the measurement process.

Table 1 Implementation example Sample material Temperature range Test sample damage The ability to determine thermomechanical parameters in conditions of increasing temperature Sample material Determined indicators of samples Prototype Device There is no data For a given fixed test temperature Sample fracture strain Not determined Not specified The value of critical strength, fracture temperature The device proposed polystyrene At a temperature dynamically increasing according to a given program in the range of -50 ° С - + 200 ° С Plastic deformation of the sample Register the diagram in the form of the dependence ΔL = f (T) Polystyrene Ftoroplast Softening temperature, strength at various temperatures in the conditions of its dynamic growth, at different loads, permissible operating temperature

Claims (1)

A device for measuring the thermomechanical characteristics of thermoplastic materials, containing a fixed base with means for positioning a sample of the test material, an indenter loading system mounted on a rod, an indenter movement control system and an indenter proper, which are installed with the possibility of their joint movement along the guides along the vertical axis of the device in the direction sample of the studied material, indenter movement system, system for measuring the degree of deformation image tsa, characterized in that the device is additionally equipped with a system for controlling the initial temperature of the sample, an individual indenter heating unit, which is equipped with sensors for monitoring the indenter heating temperature and a system for controlling the indenter heating mode according to a predetermined program, and the indenter loading system is equipped with load stabilization during one test and with the possibility of its variation from experience to experience, made in the form of a device with a given load correction program (p, m) = const, where p is the pressure , m is the mass created by the load.