Abstract: The present application discloses a vibration table, comprising a magnetic circuit device for generating a magnetic field; a moving coil skeleton, disposed in the magnetic circuit device, moving up and down in the magnetic field and having a placement groove; an adapter, disposed in the placement groove; an excitation coil, radially winding along an outer peripheral wall of the moving coil skeleton and located in the magnetic field generated by the magnetic circuit device; wherein, the moving coil skeleton is provided with a cut-off groove. The vibration table provided in the present application uses a metal beryllium as a material for a moving coil skeleton and an accelerometer adapter. The large specific stiffness of the metal beryllium is used to increase the axial natural frequency of the moving coil skeleton, thereby increasing the effective working frequency range of the vibration table.

Abstract: Disclosed is a piezoelectric ceramic stacked structure and a piezoelectric accelerometer.

Abstract: A calibration method and system for a lubrication oil metal debris sensor includes applying an excitation to the lubrication oil metal debris sensor to be calibrated, obtaining a second output signal from the lubrication oil metal debris sensor to be calibrated based on a test metal ball with a known diameter, and determining a sensitivity characteristic parameter of the lubrication oil metal debris sensor to be calibrated according to the diameter of the test metal ball with the known diameter, the second output signal, and a preset data processing model. Large particulate metal balls with large diameter are used as calibration particles. The calibration performed by the combination of the particulate metal ball and the data processing model helps when the signal processing circuit cannot be matched with the actual performance of the sensor and avoids an underestimation of the monitoring capability of the lubrication oil metal debris sensor.

Abstract: A piezoelectric acceleration sensor provided by the present invention comprises: a housing, wherein the housing is internally molded with an installation chamber, and one side face of the housing is provided with a cable connector; an adjustment structure, configured to adjustably connect the housing position to a to-be-measured object, so as to adjust the relative position between the to-be-measured object and the cable connector; and a charge output structure, installed in the installation chamber and configured to induce vibration and output electric signals, wherein the charge output structure is electrically connected with the cable connector. Through the adjustment structure, the housing position can be adjustably connected to the to-be-measured object, such that the cable connector keeps away from the position of obstacles, and the position of the cable connector can be flexibly adjusted, thereby facilitating installation.

Abstract: A magnetic installation base provided by the present invention comprises: a base applicable to be connected with an acceleration sensor; and a magnet set installed on the base and having an adsorption surface formed at an end far away from the base. The magnet set comprises several magnets, and the ends of adjacent magnets forming the adsorption surface have opposite polarities. During use, the magnetic installation base is adsorbed onto the surface of a to-be-tested object, therefore, the appearance of the to-be-tested object does not need to be destroyed, moreover, since the ends of adjacent magnets forming the adsorption surface have opposite polarities, the adsorption surface is ensured to have sufficient magnetic lines, and the adsorption capacity is larger.

Abstract: The invention provides a magnetic induction particle detection device and a concentration detection method, wherein the detection device comprises a signal detection system, a detection pipeline, excitation coil and a positive even number of induction coils, and the excitation coil are connected with the signal detection system and wound around the detection pipeline; the induction coils are connected with the signal detection system and wound around the excitation coil sequentially and reversely with respect to each other. By means of the device, preparation and installation can be facilitated, and detection precision can be improved. The method comprises the steps of: S1: acquiring an output signal of the signal detection system and obtaining a voltage amplitude change; and S2: according to the obtained voltage amplitude change, detecting the metal particle concentration. By means of the method, the precision of calculation can be improved.

Abstract: A charge output element, comprising: a base (110), which comprises a supporting part (111), a connecting part (112), and a mounting hole (113); a piezoelectric element (120), sleeved on the connecting part (112), an annular gap being formed between the piezoelectric element (120) and the connecting part (112); a mass block (130), sleeved on the piezoelectric element (120); a pre-tightening member (140), inserted in the annular gap; a locking member (150), having a columnar part (151) and a stop part (152) connected to each other, the columnar part (151) cooperating with the mounting hole (113) to lock the components above, and the stop part (152) pressing against a first end (142), so that the pre-tightening member (140) provides a radial pre-tightening force to tightly fix the piezoelectric element (120), the mass block (130), and the base (110).

Abstract: A manufacturing method for an electrode of a high-temperature piezoelectric element, comprises: coating traditional conductive slurry on surfaces of a molded piezoelectric material (1); then polarizing the piezoelectric material (1); and then removing the coating of conductive slurry (2) on the surfaces there of, and connecting the piezoelectric material to outside electrode lead wires (3) to output a signal generated by piezoelectric effect thereof. A structure of a high-temperature piezoelectric element, comprises polarized piezoelectric material (1), wherein the coating of metallic conductive slurry (2) is removed from the surfaces of the polarized piezoelectric material (1) and the surfaces of the polarized piezoelectric material (1) is connected to electrode lead wires (3) to output a signal generated by piezoelectric effect thereof.

Abstract: A shear-type piezoelectric sensor and a method for manufacturing the shear-type piezoelectric sensor are provided. The shear-type piezoelectric sensor comprises a collar, a piezoelectric element, and a mass block, wherein the collar is disposed outside a fastening nail, the fastening nail can be screwed onto a support arranged on a base; the piezoelectric element is disposed outside the collar; the mass block is disposed outside the piezoelectric element, the collar is expanded as the fastening nail is screwed onto the support, the piezoelectric element is expanded by an expanding force transferred from the collar, and the mass block is expanded by an expanding force transferred from the piezoelectric element. The shear-type piezoelectric sensor can be assembled easily and has high sensitivity and can be used in a high-temperature environment.

Abstract: A manufacturing method for an electrode of a high-temperature piezoelectric element, comprises: coating traditional conductive slurry on surfaces of a molded piezoelectric material (1); then polarizing the piezoelectric material (1); and then removing the coating of conductive slurry (2) on the surfaces there of, and connecting the piezoelectric material to outside electrode lead wires (3) to output a signal generated by piezoelectric effect thereof. A structure of a high-temperature piezoelectric element, comprises polarized piezoelectric material (1), wherein the coating of metallic conductive slurry (2) is removed from the surfaces of the polarized piezoelectric material (1) and the surfaces of the polarized piezoelectric material (1) is connected to electrode lead wires (3) to output a signal generated by piezoelectric effect thereof.