Shock Accelerometer Research Articles

Lessons Learned in Applying Accelerometers to Nuclear Effects Testing

Exoatmospheric nuclear effects, such as those that would be encounter by reentry bodies, provide instantaneous (near zero‐duration), impulsive loading of structures. Endoatmospheric nuclear effects possess an impulse that is finite in duration, but whose rise time is still instantaneous. The commonality of these loadings is that they initiate waves propagating through structures, resulting in extremely short duration accelerations to free surfaces where accelerometers are mounted. Over the years, attempts have been made to measure free surface accelerations using ceramic, quartz, and piezoresistive accelerometers. This paper describes the lessons learned, and looks to the future. It also provides a history of shock accelerometer development.

Mass loading effect of shock accelerometers

Mass loading affects the sensitivity of an accelerometer. The mass loading effect can be corrected using mass loading correction curves published by manufacturers. These curves, however, are only applicable to the sinusoidal acceleration below 500 m/s2. The mass loading effect on the sensitivity of an Endevco 2270 accelerometer in shock calibration, from 500 m/s2 and up, was investigated using a laser vibrometer. A new method for conversion of a velocity signal to an acceleration signal was developed. With this method, the sensitivities of the above accelerometer for different mass loads at different shock levels were measured. The mass loading effect in shock calibration for this accelerometer was then obtained. The limitations of the sensitivity measurements were also studied. The variance of the measured sensitivity was mainly due to the resolution limitation (8-bit) of the A/D converter in the digital oscilloscope. A correlation matching algorithm was then developed that utilizes the similarity between the measured acceleration signal and that converted from the velocity signal to further improve the resolution of the digital oscilloscope.

A novel PVDF based high-Gn shock accelerometer

High-Gn accelerometers are always used in explosion and shock measurement. The principle and solution of high-Gn piezoelectric accelerometers are introduced in detail. Focusing on piezoelectric material, structure model and assembling techniques, we investigated high-Gn accelerometers with compression mode, with an energy converter made of novel piezoelectric material PVDF. The dynamic range and operating frequency range are within 50000 Gn and 15 kHz respectively. The shock tests indicated that the characteristics of waveforms acquired from test were similar to those of ready commodities. It can be used for specific test conditions during explosion and shock process.

A silicon micromachined shock accelerometer with twin-mass-plate structure

Presented in this paper, is a shock accelerometer fabricated by silicon micromachining technology. The accelerometer is constructed with an iso-width twin-mass-plate structure that can greatly increase the natural frequency and facilitate the fabrication process. Theoretical analysis and ANSYS simulation of the structure show that it can cover a wide range from 2,000 g to 200,000 g depending on the thickness of the plate if packaged successfully. The primary performance of the accelerometer was examined using a free dropping-bar system. Experimental results on sensitivity and resonance frequency are presented and compared with the theoretical values. The results of the shock tests show that the accelerometer with a plate thickness of 74 μm has a sensitivity of 1.43 μV g −1 under 5 V excitation, and its resonance frequency is greater than 200 kHz.

Impact penetrometry on a comet nucleus — interpretation of laboratory data using penetration models

The first — and possibly deepest — in situ science measurements on the 46P/Wirtanen nucleus will be made by two sensors of the Rosetta Lander's MUPUS experiment. A piezoelectric shock accelerometer (ANC-M) and a resistance temperature sensor (ANC-T) will be mounted in the Lander's harpoon anchor. This will be shot into the surface at about 60 m s −1 on touchdown, reaching a final depth of between a few centimetres and about 2.5 m, depending on the hardness of the ground and the maximum available cable length. Early indications of the strength of the surface material and any distinct layers should prove valuable to subsequent depth-sensitive investigations, including the MUPUS thermal probe, seismic sounding experiments, the sampling drill and composition analyses of the extracted material. Interpretation of the ANC-M data will help to constrain models of the formation and evolution of the material found at the landing site and document the mechanical and structural context of nearby sampled material. We report on the results of recent test shots performed with a prototype anchor into several porous materials: two types of glass foam, H 2O ice and CO 2 ice. With the help of data from direct shear tests and quasi-static penetration tests, we interpret the processed deceleration data using a cavity-expansion penetration model. Layers of distinctly different strengths can be detected and located, and the deceleration profiles are in reasonable agreement with the profiles obtained by quasi-static tests. The anchor projectile's long sharp tip tends to smear out the boundaries, however. In applying the penetration model we found that the coefficient of sliding friction and the target's volumetric strain have a much stronger influence on the deceleration profile than the initial target density and angle of internal friction. Very small values of volumetric strain (corresponding to high ‘drag coefficient’) were required to fit deceleration profiles to the measured data for the glass foam, contrary to what we initially expected by inspecting the thin layer of crushed material around the walls of the penetrated channel. We interpret this to mean that such brittle, porous materials as the glass foam (and perhaps highly porous, brittle, cryogenic ice) do not exhibit plastic deformation before failing completely by the crushing of cell walls. The decelerating forces are thus thought to be dominated by momentum transfer to the crushed material and by the crushing strength of the cellular microstructure, rather than by the force required to deform the target plastically. The cavity-expansion model seems to be well-suited to the ice shots, but for the brittle, cellular glass foam, alternative approaches, taking into account the material's microstructure, are needed. As a first step in this direction, a microstructural model linking textural properties of the material (pore and grain size, and relative contact area between grains) is applied to the glass foam data, obtained from quasi-static penetration tests and from direct shear strength tests. It is demonstrated that the dependence of strength on porosity can be well represented by the model suggested. A microstructural model for sintered ices, relating strength properties to porosity and thermal properties, would be useful for interpretation of MUPUS ANC-M data in the context of other physical properties measurements. The work presented here may also have some relevance to the design of future comet landers or penetrators. The harpoon anchor/penetrometer approach could be employed on other minor body landing missions, while the modelling technique is similar in many ways to that appropriate for other penetrometers/penetrators.

Modeling of Shock Propagation and Attenuation in Viscoelastic Components

Protection from the potentially damaging effects of shock loading is a common design requirement for diverse mechanical structures ranging from shock accelerometers to spacecraft. High damping viscoelastic materials are employed in the design of geometrically complex, impact-absorbent components. Since shock transients are characterized by a broad frequency spectrum, it is imperative to properly model frequency dependence of material behavior over a wide frequency range. The Anelastic Displacement Fields (ADF) method is employed herein to model frequency-dependence within a time-domain finite element framework. Axisymmetric, ADF finite elements are developed and then used to model shock propagation and absorption through viscoelastic structures. The model predictions are verified against longitudinal wave propagation experimental data and theory.

Characterization of shock accelerometers using Davies bar and laser interferometer

In this paper, we propose a novel method for evaluating the frequency response of shock accelerometers using Davies bar and interferometry. The method adopts elastic wave pulses propagating in a thin circular bar for the generation of high accelerations. The accelerometer to be examined is attached to one end of the bar and experiences high accelerations of the order of 103∼105 m/s2. A laser interferometer system is newly designed for the absolute measurement of the bar end motion. It can measure the motion of a diffuse surface specimen at a speed of 10−3 ∼100 m/s. Uncertainty of the velocity measurement is estimated to be±6×10−4 m/s, proving a high potential for use in the primary calibration of shock accelerometers. Frequency characteristics of the accelerometer are determined by comparing the accelerometer's output with velocity data of the interferometry in the frequency domain. Two piezoelectric-type accelerometers are tested in the experiment, and their frequency characteristics are obtained over a wide frequency range up to several ten kilohertz. It is also shown that the results obtained using strain gages are consistent with those by this new method.

Characterization of shock accelerometers using davies bar and strain-gages

This paper proposes a novel method for evaluating the dynamic characteristics of shock accelerometers under high acceleration levels and a wide frequency bandwidth. High accelerations of 103∼105m/s2 can be generated by the reflection of an elastic wave pulse propagating in a metal bar known as the Davies bar. The elastic wave pulse is produced by the collision of a projectile against one end of the bar, and is detected by straingages. The accelerometer to be characterized is attached to the other end of the bar. The one-dimensional theory of elastic waves enables the derivation of an input acceleration to the accelerometer from the measured strain. The dispersion of the elastic waves caused by the lateral inertia of the bar is compensated for by using a two-dimensional analytical solution. This method was validated by an experiment characterizing a piezoelectric-type accelerometer within the frequency band approximately 1 kHz∼70 kHz.

Method and apparatus for measuring dynamic response characteristics of shock accelerometer

First Page

A study on the characterization of the accelerometers using Davies' bar technique. 1st report. The estimation of the frequency response of the accelerometers using the strain gauger.

A new method for the characterization of shock accelerometers is proposed. The reflection of the elastic wave propagating in a metal bar is used to generate input acceleration to an accelerometer. The elastic wave is produced by the collision of a projectile against the end of the bar and is detected with the strain gauges. The input acceleration is estimated using the one-dimensional theory of elastic wave propagation. The dispersion of the elastic wavefront due to the lateral inertia of the bar is corrected by using Skalak's analysis. The acceleration under which this method is carried out is higher than that of the conventional shaking method. The bandwidth of this method is wider than that of the conventional method because the input acceleration is of pulse shape.

Study on the dynamic force/acceleration measurements

This paper presents a new method of estimating the dynamic characteristics of a shock accelerometer using elastic wave propagation in a metal bar. The output from the accelerometer attached to a Davis bar is compared with the theoretical acceleration calculated using the relationship derived from the one-dimensional wave equation of motion in elastic media. The experiment was carried out using the 2 m long stainless steel bar, a solenoid valve air gun, a transient recorder, and a personal computer for signal processing. Details are given of the experimental equipment, the comparison of the accelerometer output with the differentiation of the strain gauge signal, the comparison of the integration of the acceleration signal with the strain gauge signal, and the response curve of the accelerometer calculated using the fast Fourier transform.

An investigation of ball-on-ball impact

The Bureau of Mines, U.S. Department of the Interior, has used a shock accelerometer to measure deceleration in ball-on-ball impact. The accelerometer signal was analyzed by a fast-Fourier-transform (FFT) technique, and signal components were identified from the accelerometer characteristics, solid mechanics, and finite-element modal and spectral analysis. Following frequency-domain digital filtering to remove extraneous frequencies, the remaining signal was reconstituted by an inverse FFT. Supporting Hertzian quasistatic and elastic and elastic-plastic dynamic finite-element calculations were carried out. All calculations predicted similar peak decelerations and contact times. The former agreed well with experiment. However, stress-wave effects make it difficult to use deceleration measurements to define contact times, even at an impact velocity of 8 ms−1. Such an impact must be analyzed as dynamic rather than static.

A fiber optic lever for noncontact shock and vibration measurements

Frequency response of accelerometers used in shock and vibration measurements is usually limited by linearity considerations to one‐third of the resonant frequency of the accelerometer. In addition, for highly sensitive measurements, the added mass of the accelerometer may alter the characteristics of the surface motion. And finally, to obtain displacement waveform measurements, the signal obtained through an accelerometer must be integrated twice with great loss of frequency response and dynamic range. The use of noncontacting fiber optic levers offers an attractive alternative in some shock and vibration problems, particularly where knowledge of displacement waveform characteristics is desirable. In this paper, displacement, velocity, and acceleration detection limits as well as frequency response and dynamic range of a fiber optic lever developed for shock and vibration measurements are presented and compared with corresponding published accelerometer specifications. Acceleration, velocity, and displacement waveform measurements from an impactively excited plate by a miniature shock accelerometer and a fiber optic lever are also compared.

Optical FM System for Measuring Mechanical Shock

A technique is described for calibrating shock accelerometers by measuring the Doppler shift in light frequency produced by the change in velocity of a target. The system employs a quadrature laser interferometer and a single-side-band carrier insertion circuit to distinguish between positive and negative velocities. Key words: Accelerometer; calibration; Doppler; interferometer; laser; shock measuring; single-side-band.

Optical FM system for measuring mechanical shock

A technique is described for calibrating shock accelerometers by measuring the Doppler shift in light frequency produced by the change in velocity of a target. The system employs a quadrature laser interferometer and a single-side-band carrier insertion circuit to distinguish between positive and negative velocities. Key words: Accelerometer; calibration; Doppler; interferometer; laser; shock measuring; single-side-band.