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ASTM D4567-19 Standard Test Method for Single-Point Determination of Specific Surface Area of Catalysts and Catalyst Carriers Using Nitrogen Adsorption by Continuous Flow Method
来源: | From: Gold APP Instruments | Published Date: 2023-02-08 | 431 Time(s) of View | 分享到:
This test method is useful for determining the specific surface area of catalysts and catalyst carriers for material specifications, manufacturing control, and research and development in the evaluation of catalysts.

Significance and Use

This test method is useful for determining the specific surface area of catalysts and catalyst carriers for material specifications, manufacturing control, and research and development in the evaluation of catalysts.


Scope

This test method covers the single-point determination of the surface area of catalysts and catalyst carriers that exhibit Type II or Type IV nitrogen adsorption isotherms using a nitrogen-helium flowing gas mixture. This test method is applicable for the determination of total surface areas from 0.1 to 300 m2, where rapid surface area determinations are desired.


Because the single-point method uses an approximation of the BET equation, the multipoint BET method (Test Method D3663) is preferred to the single-point method.



Summary of Test Method

The sample is degassed by heating in a flow of inert gas to remove adsorbed vapors from the surface. The sample is then immersed in a liquid nitrogen bath causing adsorption of nitrogen from a flowing mixture of a fixed concentration of nitrogen in helium. When adsorption is complete, the sample is allowed to warm to room temperature causing desorption, which results in an increase in the nitrogen concentration in the flowing mixture. The quantity of nitrogen gas desorbed is determined by sensing the change in thermal conductivity.


Calculation of the surface area is based on a modified form of the BET equation.

A schematic diagram of the basic apparatus

Apparatus

6.1 A schematic diagram of the basic apparatus is shown in Fig. 1. The apparatus may be constructed of glass or metal tubing. It has the following features:


6.1.1 Flow Control—A flow control system will be present after the gas inlet(s) to establish and control the flow of the analysis gas at the target concentration, eliminating fluctuations in the gas flow. The instrument can have a single gas inlet when working with pre-mixed gas or two gas inputs in the case the gas mixture is created in the instrument. The flow control system can consist of a combination of a pressure regulator, a regulating valve, and a volumetric flow meter or mass flow controller(s).


NOTE 1—In some systems, a flow meter may also be found after the sample cell to monitor the flow rate of the nitrogen-helium mixture.


6.1.2 Thermal Conductivity Detector(s)—The apparatus will contain at least one thermal conductivity detector situated after the path selector to sense changes in the gas mixture after flowing through the sample cell. Analyzers with mass flow contollers do not need a secondary reference detector before the sample station as the initial gas concentration is precisely known. In analyzers without mass flow control of the input gas, a reference detector to sense the nitrogen-helium gas mixture before the sample station is also necessary. When a two detector configuration is used, the detectors are initially balanced to allow the detection of changes in the nitrogen concentration.


NOTE 2—Some systems with a two detector configuration may include a Bridge Balance Meter, to display balance or imbalance between the two detectors or a Digital Integrator, to measure the imbalance between detectors and display the surface area of the sample, or both.


6.1.3 Flow-Through Sample Cells, of various volumes and shapes depending on the application.


6.1.4 Equilibration Paths—The apparatus will have at least two equilibration paths, selected by a selector valve or a combination of valves, between the sample cell and the down stream detector. Two or more paths allow for temperature and pressure equilibration of a wide range of volumes of gases. 


6.1.5 Diffusion Baffle, to prevent air from diffusing back into the system during cooling of the sample.


6.1.6 Septum or Fixed Loop, (not shown in Fig. 1) for injection of calibration gas. (Optional: only required on analyzers without precise mass flow control of input gas.)


6.1.7 Degassing Station, (not shown in Fig. 1) with heating mantle, for removal of adsorbed vapors from the sample. (The degassing station can either be integrated into the apparatus or part of an independent sample preparation device.)


6.1.8 Cold Trap, (not shown in Fig. 1) for removal of impurities in the gas mixture. (Optional: Cold trap is not required if gas purity meets noted specification.)


6.1.9 Thermal Equilibration Tube, (not shown in Fig. 1) to allow the flowing gas mixture to reach temperature and pressure equilibration before reaching the first detector, in two detector configuration systems, or the sample station.


NOTE 3—Instruments without a cold trap do not require a thermal equilibration tube.


6.2 Dewar Flasks.


6.3 Laboratory Balance with 0.1 mg (10−7 kg) sensitivity.


6.4 Gas-Tight Syringe or Gas Sampling Loop, 1.00 cm3.


(Optional: only required on analyzers without precise mass flow control of input gas.)


NOTE 4—Commercial instruments are available for determining single point BET area. These instruments typically conform to the schematic in Fig. 1, and the manufacturer’s manual should be consulted for proper calibration and reporting of single point BET area.

ASTM D4567-19 Standard Test Method for Single-Point Determination of Specific Surface Area of Catalysts and Catalyst Carriers Using Nitrogen Adsorption by Continuous Flow Method

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