Improved device for measuring air specific heat ratio through vibration method

Abstract

The invention discloses an improved device for measuring an air specific heat ratio through a vibration method, and relates to measurement of a physical constant. In order to solve problems of the prior art, an adopted technical scheme is as follows: the improved device for measuring the air specific heat ratio through the vibration method comprises a glass tube and a steel ball, wherein the steel ball is close to the surface of the glass tube and keeps a distance of 0.01-0.02mm with the glass tube on a corresponding position; a small hole is formed on the side face of the glass tube; the improved device is characterized in that two or more cylinders are symmetrically distributed on the steel ball, wherein axes of all cylinders are mutually parallel; one side of each cylinder is closely contacted with the steel ball and is embedded in the steel ball while the other side is protruded out of spherical surface of the steel ball; grooves are formed on the glass tube, and the number of the grooves is identical to the number of the cylinders on the spherical surface of the steel ball; and the cylinders on the spherical surface of the steel ball can slide up and down along the grooves of the glass tube. Multiple rings and multiple rows of small holes are formed, namely 10-500 small holes. The improved device disclosed by the invention has the beneficial effects that the steel ball is effectively prevented from rotating; and flowing air is nearly in laminar flow, thus relieving collision between the steel ball and the wall of the steel tube.

Description

technical field [0001] The invention relates to the measurement of physical constants, and in particular provides a device for measuring air specific heat ratio by vibration method. Background technique [0002] Vibration method to measure specific heat capacity ratio of air is a commonly used method for measuring specific heat capacity ratio. The measurement method used in the physics laboratory, the experimental principle is detailed in "Improvement of the experimental method for measuring gas specific heat capacity ratio by vibration method", Journal of Taizhou University, December 2010 No. Volume 32, Issue 6, Page 39-42, "2 Experiments", and "Experimental Analysis of Air Specific Heat Capacity Ratio Measurement by Vibration Method, Laboratory Science, Volume 16, Issue 3, June 2013, Issue 35-37" "1.1 Principles of the original experiment". [0003] The principle adopted by the prior art, see figure 1 , the gas injection port injects gas continuously and stably, and the ...

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Problems solved by technology

[0006] (2) The non-equivalence of the force on the top and bottom of the small hole does not have the mechanical conditions of simple harmonic vibration: the thrust of steel ball A on the upper and lower ends of the small hole is different, and the thrust on the lower end of the small hole is different. The thrust of the gas is large, and the thrust on the upper end (the gas leaks from the small hole) is small. The airflow environment in which the steel ball A moves is abrupt. Both documents are skeptical about its principle; if there is no small hole , the steel ball A is subjected to the thrust produced by the pressure difference, and the steel ball A will always rise without vibrating. Although, in the document "Improvement of the experimental method for measuring the gas specific heat capacity ratio by vibration method", it is proposed to find the steel ball under the small hole The balance position of A will then produce a vibration with an amplitude of about 1cm. Due to the lack of external force, it is difficult to achieve only through the adjustment of the air flow. The reason is that the steel ball A will fall when the air flow is small, and the steel ball A will rise when the air flow is large. Then the steel ball A is stable, then after the steel ball A is stable, the airflow must be increased to promote its rise, and after a certain distance, it must immediately return to the appropriate airflow mentioned above, so that the thrust generated by the pressure difference is equal to the gravity. This step hard to accomplish;

The literature "Improvement of the Experimental Method for Measuring Gas Specific Heat Capacity Ratio by Vibration Method" also found rotation (called spin in the literature) and collision phenomena. During the vibration process of steel ball A, we found that its reflected light changed, and then we marked it with red The pen draws a cross on the surface of the steel ball A, and it is found that the cross of the steel ball A rotates during the vibration process, and the direction of rotation changes with different instruments and at different times. This result is presented to us by the tube wall or / And the surface of the steel ball A is not uniform, and the asymmetric flow of the airflow at the small hole causes the steel ball A to rotate under asymmetric force. We also found that the frequency of its rotation also shows differences in different instruments and at different times. In other words, the steel ball A is not in a laminar flow environment, but has a certain turbulent flow, its rotational kinetic energy will affect the accuracy of the measurement, and, due to the uncertainty of the rotation, it cannot be corrected quantitatively

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