RU163307U1 - Vortex Motion Sensor - Google Patents

Abstract

Eddy current displacement sensor, including the sleeve-foot of the sealed case with one section of the internal and two sections of the external thread, a movable hollow rod with an external thread and an immersion section with an eddy current transducer — an inductive coil, sealed on its end, an electrical connector connected to it and lock nut for fixing the position of the movable rod, characterized in that the movable rod is made with sequentially located after the immersion and thread of additional sections with an additional stuffing box and a larger diameter section with an electrical connector installed in it and two opposite flats, the threaded section of the movable rod is mated directly with the internal thread section located in the lower part of the body-sleeve-foot, and the lock nut is made on the upper section the external thread of the sleeve body and covering the split collet washer and elastic sealing gasket mating with the surface of the stuffing box portion of the movable rzhnya and the upper end portion of the male thread, the hub body.

Description

The utility model relates to measuring technique and can be used for non-contact measurement of linear displacements or rotational speed of ferromagnetic objects, as well as for monitoring their vibrational state, including in extreme (explosive) conditions.

Vibration measurement of industrial machines and mechanisms is an integral part of modern vibrodiagnostic systems. Continuous vibration diagnostics of machines and mechanisms helps to prevent the possibility of emergency situations, technological disasters, increase the life of expensive objects, etc. Currently, both primary (piezoelectric, induction, etc.) and non-contact transducers (eddy current, capacitive, etc.) can be used as primary vibration transducers in such systems. In many cases, non-contact vibration transducers have an advantage over contact ones, since they do not affect the measurement object with their mass, and this allows measurements of the vibrational state of even small objects by mass and size. In the general case, non-contact vibration transducers, in particular eddy current ones, are simple to manufacture, have a large dynamic range of measurement of vibration parameters (in this case, vibration displacements), and it is possible to measure static displacements, i.e. the frequency range of the measured vibration displacements starts from 0 Hz, which greatly simplifies the design of standard measuring instruments for determining its conversion coefficient during calibration and calibration.

Known eddy current displacement transducer ("Eddy current axial displacement transducer", RU 2442965, G01D 5/20, G01N 27/90, 02/20/2012) and issued by the patent holder (Open Joint-Stock Company "Scientific and Production Association of Measuring Equipment", NPO IT) - “Current-eddy sensor IT12.30.000”

The known sensor comprises a cylindrical hollow metal housing with an external thread and two nuts, a eddy current sensitive transducer located in the housing, and a sealed cable entry with an electrical connector connected to it through an open portion of the cable. The cable entry is connected to the cable section in the armored hose and termination at the end of the cable.

In the removed casing of the studied mechanism, the eddy-current transducer body with an open cable section is passed through a threaded hole for installing a cable entry. The eddy-current transducer body with an external thread is installed in a hole mating with an internal thread in an arm that is not mechanically connected to the surface being monitored. Rotating the transducer housing, set the initial clearance between the surface to be monitored and the transducer. The installed position of the converter housing is fixed with nuts. After installing the eddy current transducer, the casing of the investigated mechanism is returned to its place and the cable entry of the transducer is hermetically installed in the threaded hole in the casing.

For reasons that impede the achievement of the technical result indicated below when using the known device, it is the difficulty of installing an eddy current sensitive transducer requiring partial dismantling of the test object (casing) and installation of additional equipment (bracket).

СО (модель 5499-002 с взрывозащищенным корпусом модели 10041, (Metrix & Provib Tech, Каталог фирмы ООО «АЛЬКОНТ», 2007, РФ, 141703, Московская обл., г. Долгопрудный), который является наиболее близким аналогом заявляемого датчика.Known eddy current displacement sensor, manufactured by METRIX

СО (model 5499-002 with explosion-proof case of model 10041, (Metrix & Provib Tech, Catalog of the company ALKONT LLC, 2007, Russian Federation, 141703, Moscow Region, Dolgoprudny), which is the closest analogue of the claimed sensor.

The known eddy current displacement sensor comprises a sealed housing and a reversibly mounted hollow rod installed in the housing with an eddy current transducer, an inductive coil, sealed to its immersion end.

The collapsible explosion-proof sealed housing of the sensor consists of three parts: the lower and middle - two bushes-futorok - with external and internal threaded sections, and the upper rotary part with an output electrical connector connected by a cable to the eddy current transducer.

The lower sleeve has two sections with an external thread - the lower section for installation on the object of study and the upper threaded section for interfacing with the middle part of the housing.

The internal fine thread of the lower sleeve of the housing is interfaced with the external thread of the third sleeve-foot, the internal thread of which is associated with the threaded portion of the hollow rod with a lock nut for rough adjustment of the working gap between the eddy current transducer and the measurement object. The third sleeve is a werner of fine adjustment of the working clearance.

The middle part of the body - the sleeve-futurka is a transitional link between the lower sleeve and the upper rotary part of the body with the output connector.

Installation of the known sensor is made in the working position as follows.

The middle and upper parts are disconnected from the sensor housing and, rotating the hollow rod with a coarse locknut inside the werner, move the immersion end of the rod with the eddy current transducer to a length that excludes the mechanical contact of the eddy current transducer with the measured surface.

Install and tightly fix the lower sleeve-futork of the sensor housing in a pre-made hole in the cover of the controlled mechanism opposite to the measured surface. Connect the output connector of the sensor to the measuring device. Rotation of the hollow rod with a coarse locknut inside the werner sets a preliminary working gap between the eddy current transducer and the measured surface. The required gap value is controlled by a measuring device. Fix the installed position of the rod with a lock nut relative to the werner. Rotating the Werner fine adjustment, set the specified value of the working gap according to the readings of the measurement unit. After the assembly and sealing of the housing parts, the installation of the known eddy current sensor in the operating position is completed.

For reasons that impede the achievement of the following technical result when using the known device, is the difficulty in setting the working gap.

The task to which the claimed utility model is directed is to simplify the process of installing an eddy current sensor in a working position.

The technical result obtained by the implementation of the claimed utility model is to simplify the design of the sensor.

The specified technical result in the implementation of the utility model is achieved by the fact that in the inventive eddy current displacement transducer, comprising a sleeve-foot of a sealed case with one section of the internal and two sections of the external thread, a movable hollow rod with an external thread and an immersion section tightly fixed to it the end by an eddy current transducer - an inductive coil, an electrical connector connected to it, and a lock nut to fix the position of the movable rod, in contrast e from a known eddy current sensor, the movable rod is made with additional stuffing section and a larger diameter section sequentially located after the immersion and threaded sections, with an electrical connector installed in it and two opposite flats, the threaded section of the movable rod is directly connected to the internal thread section located in the lower parts of the body - sleeve-futorki, and the lock nut is made cape on the upper portion of the external thread of the body of the sleeve and covering a split collet washer and a sealing elastic gasket mating with the surface of the stuffing box portion of the movable rod and the end face of the upper portion of the external thread of the sleeve body.

In FIG. 1 shows the inventive eddy current displacement sensor.

The inventive eddy-current displacement transducer comprises a housing 1 in the form of a foot-sleeve and a hollow movable rod 2 installed in the housing 1 with an eddy current transducer 3 sealed at one end and an inductive coil connected via cable 4 to the hollow rod 2 sealed to the other end electrical connector 5.

The rod 2 contains a sequentially located immersion section 6 with an eddy current transducer 3 at the end, a section with an external thread 7, a stuffing box 8 and a larger diameter section 9 with an electrical connector 5 and with two opposite flats 10 ₁ and 10 ₂ .

The sensor case 1 contains in its lower part a portion with an internal thread 11 mating with a threaded portion 7 of the rod 2, a hexagon 12, and two portions with an external thread 13 and 14 at the upper and lower ends of the housing 1.

The lower portion 14 of the external thread of the housing 1, together with the contact area increasing the contact area 15, is designed for hermetically securing the sensor housing 1 in the thread portion 16 of the hole 17 in the casing 18 of the controlled object.

The upper threaded section 13 is designed to connect with a union lock nut 19, covering a split collet washer 20 and a flexible elastic gasket 21, hermetically mating with the surface of the stuffing box 8 of the movable rod 2 and the end surface of the upper threaded section 13 of the sensor housing 1.

Installation of the eddy current displacement sensor in the working position is as follows.

Rotating the hollow rod 2 in the mating threads 7-11, move its immersion section 6 with the eddy current transducer 3 relative to the housing 1 to a predetermined length, providing the expected working clearance between the transducer 3 and the measured surface (not shown) and excluding mechanical contact eddy current transducer 3 with a measured surface.

Install and using the hexagon 12, hermetically on the end surface of the shoulder 15 secure the housing 1 of the sensor with the lower portion of the thread 14 in a pre-made hole 17 with a portion of the thread 16 on the casing 18 of the controlled object. A measurement unit is connected to the electrical connector 5 (not shown in FIG.) And, taking into account its indications, additionally turn the rod 2 with the eddy current transducer 3 to the required angle, which ensures the required working gap is set. Then, holding the rod 2 in its stationary position by its flats 10 ₁ and 10 ₂ , screw the lock nut 19 onto the upper threaded section 13 of the housing 1. Moving the lock nut 19, covering the split collet washer 20 and the elastic sealing strip 21, simultaneously fixes the position of the rod 2 exposed working gap and sealing the gap between the housing 1 and the stuffing surface 8 of the rod 2 - i.e. provide practical sealing of the internal cavity of the controlled mechanism.

Thus, it is seen that the above information confirms the possibility of implementing the described utility model, achieving the specified technical result and solving the problem.

Claims (1)

Eddy current displacement sensor, including the sleeve-foot of the sealed case with one section of the internal and two sections of the external thread, a movable hollow rod with an external thread and an immersion section with an eddy current transducer — an inductive coil, sealed on its end, an electrical connector connected to it and lock nut for fixing the position of the movable rod, characterized in that the movable rod is made with sequentially located after the immersion and thread of additional sections with an additional stuffing box and a larger diameter section with an electrical connector installed in it and two opposite flats, the threaded section of the movable rod is mated directly with the internal thread section located in the lower part of the body-sleeve-foot, and the lock nut is made on the upper section the external thread of the sleeve body and covering the split collet washer and elastic sealing gasket mating with the surface of the stuffing box portion of the movable rzhnya and the upper end portion of the male thread, the hub body.

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