Abstract: The present application relates to the technical field of sensors, and particularly relates to a lightning-proof piezoelectric acceleration sensor which comprises a housing, a core assembly, an insulation sheet, a shielding cover, a lightning-proof circuit board and a heat-shrinkable sleeve, the core assembly is provided inside the housing, the insulation sheet has one end fixedly connected to the core assembly and the other end fixedly connected to an inner wall of the housing, the shielding cover is sleeved outside the core assembly and has an open end oriented towards the insulation sheet, the lightning-proof circuit board is fixedly provided on an upper end of the shielding cover and is electrically connected to an external connector and the core assembly respectively, the heat-shrinkable sleeve is sleeved outside the shielding cover and has a lower end connected to the housing and an upper end situated higher than the shielding cover.

Abstract: The present disclosure relates to a cable and a high temperature resistant piezoelectric acceleration sensor. The cable comprises a high temperature connection terminal, a low temperature connection terminal, and a high temperature resistant wire segment and a low temperature wire segment located between the high temperature connection terminal and the low temperature connection terminal.

Abstract: The disclosure provides a charge output element and a piezoelectric acceleration sensor. The charge output element includes: a base including a supporting member and a connecting member disposed on the supporting member; a flexible member sleeved on the connecting member for bending deformation; a mass block assembly disposed around a circumference of the connecting member, wherein the mass block assembly is coupled to the connecting member by the flexible member and suspended above the supporting member to drive the flexible member to be bent and deformed in an extending direction of the connecting member; and a piezoelectric element attached to a surface of the flexible member away from the supporting member and disposed to move along with movement of the flexible member. Therefore, the sensitivity of the charge output element can be improved while the sensitivity of the charge output element is not susceptible to the strain of the base.

Abstract: The disclosure provides a piezoelectric acceleration sensor including a charge output element, a casing, a cable assembly and a connector. The casing is snap-fitted to a supporting portion of a base of the charge output element, and forms a receiving space for receiving the charge output element, the piezoelectric, and the mass block with the supporting portion. The cable assembly is connected to the supporting portion. The connector is connected to an end of the cable assembly facing away from the supporting portion, and is insulated from the cable assembly. One end of either of a first lead and a second lead of the cable assembly is electrically connected to the piezoelectric element, while the other end of the first lead is electrically connected to a conductive terminal of the connector and the other end of the second lead is electrically connected to a housing of the connector.

Abstract: The disclosure provides a piezoelectric sensor, including a piezoelectric crystal cylinder including a plurality of crystal layers which are laminated, each crystal layer including two axially opposite end faces, each end face including an electrode film region and a terminal film region, wherein the electrode film region and the terminal film region on the same end face are separated by a crystal exposure region, the electrode film region on one end face of the two end faces in each crystal layer is electrically connected to the terminal film region on the opposite end face of the two end faces, and the electrode film regions on adjacent end faces of adjacent crystal layers are in contact with each other and form an electrical connection while the terminal film regions on the adjacent end faces of the adjacent crystal layers are in contact with each other and form an electrical connection.

Abstract: The disclosure relates to a piezoelectric acceleration sensor. The piezoelectric acceleration sensor includes: a charge output member comprising a base, a piezoelectric element disposed on the base and a mass, wherein the base includes a supporting portion and a connecting portion disposed on the supporting portion and extending in a first direction, and the piezoelectric element and the mass are sleeved on the connecting portion; a shielding cover sleeved on the connecting portion, wherein the shielding cover is connected to the connecting portion and the supporting portion, the shielding cover forms a shielding space outside a periphery of the connecting portion and above the supporting portion, and the piezoelectric element and the mass are arranged in the shielding space; and a housing coupled with the supporting portion, wherein the housing and the supporting portion form an accommodating space for accommodating the charge output member and the shielding cover.

Abstract: The present invention discloses a system for detecting the concentration of non-metal particles in a fluid and detection method thereof. The detection system comprises a particle morphology detection device, a metal particle detection device, and a detection pipeline, the particle morphology detection device and the metal particle detection device being connected to each other and wound around the detection pipeline. The detection method comprises: S1, detecting the concentration of fluid particles; S2, detecting the concentration of fluid metal particles; and S3, detecting concentration of fluid non-metal particles. By means of the detection system and the detection method, the concentration of non-metal particles in a fluid can be more accurately detected, and the detection accuracy is improved.

Abstract: The present invention discloses a device and method for detecting fluid transparency. The detection device comprises: a detection pipeline, which allows a beam to be incident on and emergent from a fluid therein; a laser tube, used for outputting the incident beam; and a photoelectric detector, used for detecting the emergent beam from the fluid, wherein the photoelectric detector comprises a scatter detector and a transmission detector; and the detection method comprises obtaining a scattered background noise value and a transmission background noise value of a device, obtaining the scattered light intensity Iscatter obtained by the scatter detector and the transmission light intensity Itransmission obtained by the transmission detector, and calculating the particle-absorbed light intensity Iabsorb; obtaining the total light intensity Itotal of a laser; and obtaining a fluid transparency T.

Abstract: A method for detecting the concentration of particles in a fluid is disclosed. The method comprises the steps of: S1: introducing a pure fluid into a detection device to obtain a scatter background noise value U noise output by the detection device; S2: introducing a fluid to be detected into the detection device, obtaining scatter signals output by the detection device, and obtaining voltage signals of standard particles; S3: sampling signals of the fluid in a certain period of time, extracting effective signals, carrying out threshold value analysis on the effective signals Ux obtained by sampling, and obtaining the number of particles present in the period of time; and S4: obtaining the concentration of the particles in the fluid according to the number of particles in S3. According to this method, the accuracy in calculation of the concentration of particles in a fluid can be effectively improved.

Abstract: The present application refers to the field of sensing device, in particular to a vibration and temperature integrated sensor, comprising a vibration sensor body; a temperature sensor body, coupled to the vibration sensor body; wherein, the vibration sensor body comprises a first casing and a vibration sensing assembly disposed inside the first casing; a shielding case is disposed outside the vibration sensing assembly; and the shielding case and the first casing have an insulating layer therebetween. The vibration and temperature integrated sensor of the present application has strong insulation and voltage resistance, strong working stability and enhanced working life.

Abstract: The present disclosure relates to a charge output device, an assembly method thereof, and a piezoelectric acceleration sensor, the charge output device comprises a bracket comprising a support member and a connecting member disposed on the support member; a piezoelectric element surrounding the connecting member and comprising a plurality of piezoelectric crystal groups and electrode plates, the plurality of the piezoelectric crystal groups are disposed at intervals in a circumferential direction of the connecting member and surrounds the connecting member in a polygonal arrangement, the piezoelectric crystal group comprises at least one piezoelectric crystal, the at least one piezoelectric crystal and the electrode plates are alternately stacked in a normal direction of a circumferential surface of the connecting member; and a mass surrounding an outer surface of the piezoelectric element and suspended above the support member, the connecting member, the piezoelectric element and the mass are interference-fi

Abstract: The present disclosure relates to a charge output device, an assembly method and a piezoelectric acceleration sensor.

Abstract: Disclosed is a charge output element, comprising: a support comprising a connecting part; a piezoelectric element, which is an annular structural body and is sleeved on the connecting part, wherein the piezoelectric element is provided with a first deformation groove, and the first deformation groove passes through a side wall of the piezoelectric element to disconnect the piezoelectric element in a circumferential direction; and a mass block, which is an annular structural body and is sleeved on the piezoelectric element, wherein the piezoelectric element is in interference fit with the connecting part and the mass block, and the piezoelectric element, the mass block and the support of the charge output element are in rigid contact with each other. Further disclosed are a method for assembling the charge output element and a piezoelectric accelerometer.

Abstract: Disclosed is a charge output element, comprising: a base, comprising a supporting part and a connecting part arranged on the supporting part, the connecting part being provided with a mounting hole; a support, sheathed on the connecting part and arranged a clearance away from the connecting part, the support being connected to the supporting part; a piezoelectric element, connected to the support in a sheathed manner; and a mass block, connected to the piezoelectric element in a sheathed manner and hanging in the air above the supporting part. Further disclosed is an annular shear-type piezoelectric accelerometer. The charge output element and the annular shear-type piezoelectric accelerometer can prevent the impacts of a connecting member on the piezoelectric element, thereby ensuring the stability of the frequency response and the transverse sensitivity of the annular shear-type piezoelectric accelerometer and thus ensuring the accuracy of a detection result.

Abstract: The present disclosure relates to the technical field of wireless detection, in particular to a wireless communication point inspection vibrometer configured to monitor vibration and temperature of rotating equipment, comprising: a housing, internally provided with a piezoelectric transducer, a temperature detection component and a first printed circuit board, wherein the piezoelectric transducer and the temperature detection component are both in communication connection with the first printed circuit board, and the first printed circuit board is provided with a wireless transmitting component. The present disclosure solves the problems that an external antenna is adopted in signal transmission of a piezoelectric acceleration transducer in the prior art, and the external antenna is large in volume and is not convenient to be installed in a relatively small space.

Abstract: A three-axis piezoelectric accelerometer, comprising: a housing, three charge output elements arranged inside the housing, and a connector electrically connected to the three charge output elements, wherein the three charge output elements are respectively used for detecting vibrations in directions along X-axis, Y-axis and Z-axis which are perpendicular to each other in pairs. The charge output element comprises: a support comprising a connecting part; a piezoelectric element being an annular structural body, wherein the piezoelectric element is connected to the connecting part in a sheathed manner and is provided with a first deformation groove penetrating a side wall of the piezoelectric element to disconnect the piezoelectric element in a circumferential direction; and a mass block being an annular structural body, wherein the mass block is connected to the piezoelectric element in the sheathed manner, and the piezoelectric element is in interference fit with the connecting part and the mass block.

Abstract: The embodiments of the present disclosure disclose an electronic bandage. The electronic bandage includes a fabric layer, an insulating layer and a conductive layer disposed in order from top to bottom; wherein the insulating layer is provided with a power source and a negative high voltage generator connected with each other, and the negative high voltage generator is further connected to the conductive layer; the conductive layer is provided with two or more support strips at intervals in length direction, the support strips protrude downward from the conductive layer, two or more microelectrodes are distributed on a lower surface of the conductive layer, and a height of a downward protruding portion of a support strip is greater than a height of a microelectrode.