JPH0536209Y2 - - Google Patents

Description

[Detailed Description of the Invention] "Industrial Application Field" This invention relates to a thermal analysis device that quantitatively analyzes gas generated from a sample made of concrete when the sample is heated.

"Prior Art" Differential thermal balance devices are widely used as this type of thermal analysis device. In this method, a sample plate of a balance is suspended in an electric furnace, and while the sample is heated, changes in weight due to changes in temperature are measured from the inclination of the balance rod. In this differential thermal balance device, the sample must be made into a fine powder or flake, and there are also restrictions on the size and weight of the sample.

``The problem that the invention aims to solve'' By the way, in recent years, in order to investigate the effect of concrete materials on heat, the amount of gas (mainly water vapor and carbon dioxide gas) generated when concrete materials are heated has been studied. There is a desire to quantitatively understand the relationship with temperature.

In thermal analysis of such concrete materials, it is desirable that the sample be in a form close to the actual state of use, that is, in the form of a relatively large block. The equipment cannot be used.

Additionally, it is conceivable to analyze the samples mentioned above using a gas chromatograph, but since continuous measurements cannot be performed with a gas chromatograph, measurements must be taken continuously while changing the heating temperature. It cannot be used in such cases.

This invention was made in view of the above circumstances, and the purpose is to provide an apparatus that is not limited by the size or shape of a sample and can perform thermal analysis continuously.

``Means for solving the problem'' This device is a thermal analysis device that performs quantitative analysis of sample gas consisting of carbon dioxide gas and water vapor generated from concrete samples while heating them. , a heating means for heating the sample, a measuring means for measuring the amount of sample gas generated from the sample during heating, and a gas that continuously guides the sample gas from the heating means to the measuring means by means of a carrier gas. The measuring means comprises an introducing means, and a moisture collecting device connected to the sample gas introducing means to collect water vapor in a supersaturated state from a sample gas in a supersaturated state of water vapor, and as the measuring means,
The present invention is characterized by using a thermal conductivity detector that detects the sample gas concentration in the mixed gas by detecting the thermal conductivity of the mixed gas of the carrier gas and the sample gas guided by the measuring means. .

"Operation" The thermal analysis device of this invention heats a sample with a heating means to generate a sample gas, and continuously guides the sample gas by a carrier gas to a measuring means consisting of a thermal conductivity detector. Thermal conductivity detector measures the concentration of the sample gas in the mixed gas by comparing the thermal conductivity of the mixed gas of carrier gas and sample gas with that of the carrier gas alone, and determines the generation of sample gas from that concentration. Quantitatively measure the amount.

"Example" Hereinafter, an example of this invention will be described with reference to FIGS. 1 and 2. Fig. 1 is a schematic diagram of the thermal analysis device of the first embodiment, and Fig. 2 is a schematic diagram of the thermal analysis device of the second embodiment. This is a quantitative analysis of water vapor and carbon dioxide, which are known to be generated in

First, the configuration of the apparatus of the first embodiment will be explained with reference to FIG. In the figure, reference numeral 1 is an electric furnace (heating means), and 2 is a reaction tube arranged inside the electric furnace 1. The electric furnace 1 has a heating temperature that can be set appropriately, and the reaction tube 2 is made of quartz glass so that a sample 3 can be stored therein.

A carrier gas introduction pipe 4 is connected to the upper end of the reaction tube 2, and a cooling pipe 5 is connected to the lower end of the reaction tube 2. A flask 6 and a cold trap 7 are connected to the cooling pipe 5. The carrier gas introduced into the reaction tube 2 passes through a cooling tube 5, a flask 6, and a cold trap 7 in sequence as shown by the arrows in the figure, and is discharged. These cooling pipe 5, flask 6, and cold trap 7 constitute a moisture collecting device that collects water vapor in a supersaturated state from a sample gas in a supersaturated state. The sample gas generated from the sample 3 is carried by the carrier gas, and the water vapor in the sample gas is condensed in the cooling pipe 5 and collected in the flask 6, and the water vapor that passes through the flask 6 without condensing. is led to a cold trap 7, where it is condensed and collected. The cooling pipe 5, flask 6, and cold trap 7 are used to remove excess water vapor from the sample gas, since the water vapor in the sample gas generated from the sample 3 is supersaturated and cannot be measured as it is. This is to make the gas saturated. Note that nitrogen gas, helium gas, or the like may be used as the carrier gas.

In addition, a sample gas introduction tube 8 is provided at the lower end of the reaction tube 2.
is connected, and this introduction pipe 8 is connected to two branch pipes 9, 1
Branched to 0. One branch pipe 9 includes a carbon dioxide adsorption device 11 and a thermal conductivity detector (measurement means) 12.
The other branch pipe 10 is connected to a suction pump 16 via a water vapor adsorption device 14 and a thermal conductivity detector (measuring means) 15. These introduction pipes 8, branch pipes 9, 10,
The suction pumps 13 and 16 constitute a sample gas introduction means 17 that continuously guides the sample gas together with the carrier gas to the thermal conductivity detectors 12 and 15.

The above carbon dioxide adsorption device 11 includes a suction pump 1
3 adsorbs only carbon dioxide gas from the sample gas sucked together with the carrier gas from inside the reaction tube 2. For example, a column filled with a filler that selectively adsorbs carbon dioxide gas may be used. The water vapor adsorption device 14 also adsorbs only water vapor from the sample gas sucked together with the carrier gas from the inside of the reaction tube 2, and uses a packed bed of molecular sieves or a cold trap similar to the cold trap 7 described above. You can use .

Further, the thermal conductivity detectors 12 and 15 described above are arranged in constant temperature baths 18 and 19, and the sample side detectors 12a and 15a and the standard side detector 12 are arranged respectively.
b, 15b. The branch pipes 9, 10 are connected to the sample side detectors 12a, 15a, respectively, and the standard side detectors 12b,
15b each have a carrier gas introduction pipe 20,
21 is connected so that carrier gas can be introduced. These thermal conductivity detectors 1
2 and 15 are connected to recorders 22 and 23 for recording measurement results, respectively.

These thermal conductivity detectors 12 and 15 detect a mixed gas of sample gas and carrier gas guided to sample side detectors 12a and 15a, and a standard side detector 12b,
The concentration of the sample gas in the mixed gas is measured by comparing and detecting the difference in thermal conductivity with the carrier gas guided by the carrier gas. It is similar to That is, these thermal conductivity detectors 12 and 15 are the sample side detector 12
A, 15a and the standard side detectors 12b, 15b are both covered with filaments (not shown) made of tungsten or platinum, which are assembled into a bridge circuit, and are made to be heated by passing current through these filaments. There is. When a gas passes around this filament, the filament is cooled by the heat conduction effect of the gas, its temperature decreases, and its electrical resistance decreases, but the degree of change in electrical resistance depends on the thermal conductivity of the gas. It depends. Therefore, if the carrier gas contains components with different thermal conductivities, the electrical resistance will change compared to the case of only the carrier gas, so by electrically detecting the degree of change, it is possible to This is to measure the concentration of sample gas mixed in the gas.

The configuration of the apparatus of the first embodiment has been explained above, and now how to use it will be explained. First, sample 3 of concrete material is cut into a predetermined shape, for example, with a diameter of 45 mm.
It is formed into a columnar shape with a length of 44 mm and a height of 44 mm, and is housed in a reaction tube 2 and heated in an electric furnace 1. At the same time, a predetermined flow rate of carrier gas is continuously supplied from the carrier gas introduction pipe 4, and each suction pump 13, 16 is driven to supply a predetermined flow rate of mixed gas (mixed gas of sample gas and carrier gas) from inside the reaction tube 2. is continuously drawn into each thermal conductivity detector 12, 15.

By doing this, the mixed gas sucked from the reaction tube 2 is sucked into each of the branch tubes 9 and 10, and the mixed gas sucked into the branch tube 9 is heated after carbon dioxide is adsorbed in the carbon dioxide adsorption device 11. conductivity detector 12. On the other hand, branch pipe 10
After water vapor is adsorbed from the mixed gas sucked into the water vapor adsorption device 14, the mixed gas is transferred to a thermal conductivity detector 15.
guided by. Then, the thermal conductivity detector 12 measures the water vapor concentration in the mixed gas, and the thermal conductivity detector 15 measures the carbon dioxide concentration in the mixed gas, and the measurement results are sent to the recorders 22 and 23. Record.

In this way, according to the device of this first embodiment,
Since the amount of water vapor and carbon dioxide generated from concrete sample 3 during heating can be measured separately and continuously, the amount of these gases can be measured over a long period of time in relation to the heating temperature and heating time. It can be measured over a period of time. The size and shape of the sample 3 are not particularly limited as long as they can be accommodated within the reaction tube 2.
It is known that there is almost no gas generated from concrete other than water vapor and carbon dioxide, so this device can quantify almost the entire amount of gas generated from concrete.

The apparatus of the first embodiment has been described above, and next, the second embodiment will be explained with reference to FIG. This second
In the embodiment, two thermal conductivity detectors 30,
31 are arranged in series, a water vapor adsorption device 32 is arranged between both thermal conductivity detectors 30 and 31, and the sample gas introducing means 33 is connected to one suction pump 3.
The configuration is the same as that of the first embodiment, except that the mixed gas is guided to the downstream detector 31 after passing through the detector 30 at the front stage.
In the apparatus of this second embodiment, the sample gas generated from the sample 3 is directly guided together with the carrier gas to the detector 30 at the front stage to simultaneously measure the amount of water vapor and carbon dioxide. , and the subsequent detector 31
It is now possible to measure carbon dioxide concentration.

According to this device, although the amount of water vapor generated cannot be directly measured, it is possible to know the amount of water vapor generated by subtracting the measurement results of both the detectors 30 and 31. Further, since only one suction pump 34 is required, this embodiment has the advantage that the configuration is simpler than that of the first embodiment. In this second embodiment, the same effect can be achieved even if a carbon dioxide gas adsorption device is provided in place of the water vapor adsorption device 32, and the moisture concentration is measured by the thermal conductivity detector 31 at the subsequent stage.

"Effects of the invention" As explained in detail above, according to this invention, the sample gas generated from the sample by the heating means is continuously guided to the measurement means consisting of a thermal conductivity detector. The size and shape of the sample may be arbitrary, and there are no restrictions as in the case of using a differential thermal balance device, and there is an effect that continuous quantitative analysis can be performed.

Furthermore, even if the high-temperature sample gas generated from the sample by the heating means is cooled and the water vapor becomes supersaturated when introduced into the sample gas introduction means, the sample gas introduction means is equipped with a moisture trapping device. Since the supersaturated water vapor is collected from the sample gas in which the water vapor is supersaturated by the connection, the sample gas in which the water vapor is saturated can be introduced into the sample gas introducing means. Therefore, the water vapor in the sample gas does not condense and remain as water droplets in the sample gas introducing means, thermal conductivity detector, etc., so that accurate quantitative analysis of the sample gas can be performed.

Furthermore, since the sample gas is forced to flow through the carrier gas, the sample gas can be continuously and reliably guided to the thermal conductivity detector. Therefore, continuous quantitative analysis can be performed easily and reliably as the heating temperature of the sample changes.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram of a thermal analysis apparatus according to a first embodiment of this invention, and FIG. 2 is a schematic diagram of a thermal analysis apparatus according to a second embodiment of this invention. 1... Electric furnace (heating means), 3... Sample, 12,
15... thermal conductivity detector (measuring means), 17...
Sample gas introducing means, 30, 31... thermal conductivity detector (measuring means), 33... sample gas introducing means.

Claims (1)

[Scope of utility model registration request] A thermal analysis device that performs quantitative analysis of sample gas consisting of carbon dioxide and water vapor generated from the sample while heating the sample made of concrete, which includes a heating means for heating the sample and a sample gas generated from the sample during heating. a measuring means for measuring the amount of sample gas generated; a sample gas introducing means for continuously guiding the sample gas from the heating means to the measuring means by means of a carrier gas; a moisture collecting device that collects water vapor in a supersaturated state from a supersaturated sample gas; A thermal analysis device for concrete, characterized in that it uses a thermal conductivity detector that measures the concentration of a sample gas in a mixed gas by comparing it with the thermal conductivity of the concrete.