RU183940U1 - VIBROSTEND FOR STUDY OF METHODS OF PROTECTION AGAINST VIBRATIONS - Google Patents

Abstract

The claimed technical solution relates to electrodynamic vibration stands and can be used in the educational process to study the influence of the rigidity of a plane-type system on the nature of vibration under external vibrational influences. The test plate on each side is fixed in the support nodes that provide the main types of fastening - rigid pinching and free support, or lack of fixing. The vibration mode of the test plate is provided using a low-frequency generator and an electromagnet that creates an electromagnetic field. The vibration of the test plate is controlled by a vibrometer by means of a vibration sensor fixed to the plate. The technical result consists in providing the possibility of studying the influence of the rigidity of the planar type system on the nature of the vibration in the presence of external vibrational influences. 5 cp f-ly, 5 ill.

Description

The utility model relates to electrodynamic vibration stands and can be used in the educational process to study the influence of the rigidity of a planar type system on the nature of vibration under external vibrational influences.

From the prior art known vibrostand [Patent PM No. 15609, G01M 7/06. Vibrostend / Rogov V.A. - Published: 10/27/2000. Bull. No. 30], containing a plate on which a movable table is mounted, rigidly connected to a mechanism for moving along mutually perpendicular axes in a horizontal plane and resting on a plate through damped rolling bearings of translational motion, each of which consists of a base mounted on the plate, a separator with balls and separator centering means, characterized in that the plate is mounted on columns, the table moving mechanism is fixed on the plate, and the separator centering means is made in the form of a wave differently curved spring tape placed on the base around the separator.

A similar vibrostand is also known [Patent PM No. 17731, G01M 17/06. Vibrostend / Rogov V.A. - Published: 04/20/2001, Bull. No. 11], comprising a box bed, an upper plate located on the bed, on which a movable table is mounted, resting on the plate through damped rolling bearings of translational motion, a table movement mechanism along two mutually perpendicular axes in a horizontal plane, including guides and a pneumatic cylinder for each axis of movement while the mechanism for moving the table is fixed to the plate, and the plate is connected to one of the walls of the box frame by means of a hinge.

Both stands are designed to test vehicles, namely, to determine the vehicle’s backlash.

Known vibration stand [RF Patent No. 2441213 G01M 7/06. Vibrostend / Glushkov V.F. - Published: 01/27/2012, Bull. No. 3], comprising a housing, a working horizontal platform, vibration displacement exciters and an electrical control system. The case is made in the form of a glass, in which at least two cylindrical channels are made above the level of the bottom of the glass, and vibration exciters in the form of inductors with plungers are located in them. The working horizontal platform is made in the form of a hollow cylindrical figure containing a table with fasteners, a base and a corrugated metal element connecting them. At the base there are channels for moving the plungers, coaxial with the channels of the bottom of the glass, as well as an opening connecting the internal volume of the hollow cylindrical figure, filled with working fluid, with these channels. The stand is designed to test products with high sensitivity to the effects of a magnetic field, mainly magnetometric and electronic equipment.

The disadvantage of all of these stands from the point of view of the declared scope is that they relate to the type of objects for a specific purpose, which complicates their use in the educational process to study the effect of changes in the rigidity of the plane-type system on the nature of the vibration.

The problem to which the claimed device is directed is to expand the arsenal of technical means in this field and to provide the possibility of studying the influence of the stiffness of the plate-like structure on vibration parameters

This goal is achieved due to the fact that the vibrostand includes a base with installed support nodes in which the test steel plate is fixed, and the design of the support nodes provides rigid jamming of the corresponding side of the plate, its free support or lack of fixation, an electromagnet mounted on the base under the test plate, connected to a low-frequency generator, a vibrometer and a vibration sensor connected to it, mounted on the surface of the test plate.

Additionally, the support nodes are two fixing plates, between which the test plate is fixed, mounted on the frame by means of a threaded rod fixed in the base, and holes in the fixing plates, while the fixing plates on the surfaces facing each other have two types of profile, joint use which allows for rigid clamping or free support of the test plate, and the fixing plates are fastened with a nut screwed onto the threads a hairpin, and the absence of fixing plates on either side of the test plate provides a free, non-fixed state of this side of the test plate.

Additionally, the test plate is made of magnetic material.

Additionally, the test plate is made of non-magnetic material, while the vibration sensor is mounted on the test plate by a screw made of magnetic material, and the vibration sensor is located above the location of the electromagnet.

Additionally, the test plate is made of non-magnetic material, while an element of magnetic material is fixed on the test plate in the area corresponding to the installation location of the electromagnet.

Additionally, the element of magnetic material is made in the form of a rod and is the core of the electromagnet.

In FIG. 1 is a diagram of a vibrating stand in FIG. 2 - reference nodes. In FIG. 3 - shows the installation of the vibration sensor on the test plate, in FIG. 4 shows the placement of a flat metal plate on a test plate; FIG. 5 - shows the placement on the test plate of the core of the electromagnet.

The vibrostand consists of a test plate 1, a signal generator 2, an electromagnet 3, a base 4, a vibration sensor 5 and a vibrometer 6. The support unit 7 consists of two rotary plates 8, a stud 9 and a nut 10. The stud 9 is rigidly fixed in the base 4.

The vibration sensor 5 can be mounted on the test plate 1 with a screw 11. An element of magnetic material in the form of a core 12 of the electromagnet 3 can be fixed on the test plate 1 with a screw 13. An element 14 of magnetic material can be additionally placed on the test plate 1.

The technical result provided by the given set of features is to provide the possibility of studying the influence of the rigidity of a plane-type system on the nature of vibration in the presence of external vibrational influences in an educational process.

The stand structure is based on the method of changing the structural rigidity of the element under study.

The device operates as follows. The signal from the generator 2 is fed to an electromagnet 3, which forms an alternating electromagnetic field, into which the test plate 1 falls. Due to the fixation of the test plate 1 in the support nodes 7 installed on the base 4, the alternating electromagnetic field provides forced vibration vibrations of the test plate 1 s frequency of the generator 2.

Installed on the plate 1, the vibration sensor 6 converts the vibrational vibrations of the plate 1 into an electrical signal, which is fed to the input of the vibrometer 6.

When the plates 7 are rotated 180 ° (in the horizontal plane), the fixing conditions change. For example, when fixing according to fig. 4a - we have a hard pinch, and when secured according to Fig. 4, b - option corresponding to the articulated (free) bearing.

In the absence of fixing on either side of the plate, the supports on the frame (on this side of the plate) are not installed.

The shape of the plates 8 included in the support nodes 7, rotation of the plates through 180 ° (in the horizontal plane), allows you to change the conditions for fixing the test plate 1. For example, when installed according to the variant of FIG. 2a, clamping of the test plate 1 over the entire plane of the edge of the plate is ensured, which simulates the option of hard jamming. When installed according to the embodiment of FIG. 2b, the test plate 1 is clamped along the entire length of the edge with the narrow protrusions of the plate 8, which simulates the freer state of the edge of the plate 1, denoted as free support. In both versions, the plates 8 are mounted on the base 4 using the stud 9 and fix the test plate 1 through the nut 10.

In the absence of fixing on either side of the test plate 1, the support plates 8 on the stud (on this side of the plate 1) are not installed.

In the case of using the test plate 1 of non-magnetic material, the vibration sensor 5 is mounted on the plate 1 using a screw 11 made of magnetic material. The installation of the sensor 5 on the plate 1 is carried out in the area above the core of the electromagnet 3. When the electromagnet 3 creates an alternating electromagnetic field, a screw 11 appears in the zone of its action, which leads to oscillations of the entire system consisting of a plate 1, a vibration sensor 5 and a screw 11.

When using the test plate 1 of non-magnetic material, the function of the element that provides the vibrations of the plate 1 can be performed by a small plate 14 made of magnetic material, mounted on the plate 1 so that it is above the core of the electromagnet 3.

When fixing the core 12 of the electromagnet 12 on the test plate 1, it is fixed with a screw 13. The location of the core 12 must strictly correspond to the location of the electromagnet 3 on the base 4, so that when the test plate 1 is installed in the support nodes 7, the core enters the electromagnet and can return - translational motion without friction on the inner wall of the hole of the coil of the electromagnet 3.

Changing the amplitude and frequency of vibration of the test plate 1 is carried out by changing the amplitude and frequency of the signal at the output of the signal generator 2.

The change in the vibration parameters of the test plate 1 is evaluated according to various options for fixing it in the support nodes 7 according to the readings of the vibrometer 6.

Information sources

1. Patent PM No. 15609, G01M 7/06. Vibrostend / Rogov V.A. - Published: 10/27/2000. Bull. Number 30

2. Patent PM No. 17731, G01M 17/06. Vibrostend / Rogov V.A. - Published: 04/20/2001, Bull. Number 11

3. RF patent No. 2441213 G01M 7/06. Vibrostend / Glushkov V.F. - Published: 01/27/2012, Bull. Number 3.

Claims (6)

1. A vibration stand, characterized in that it includes a base with installed support nodes in which the test steel plate is fixed, and the design of the support nodes provides a rigid jamming of the corresponding side of the plate, its free support or lack of fixation, an electromagnet mounted on the base under the test plate, connected to a low-frequency generator, a vibrometer and a vibration sensor connected to it, mounted on the surface of the test plate. 2. The vibration stand according to claim 1, characterized in that the support nodes are two fixing plates, between which the test plate is fixed, mounted on the frame by means of a threaded rod fixed in the base, and holes in the fixing plates, while the fixing plates are facing each other to the other surfaces there are two types of profiles, the joint use of which allows for rigid pinching or free support of the test plate, and the fixing plates are fastened with a nut, screwed onto a threaded rod, and the absence of fixing plates on either side of the test plate provides a free, unsecured state of this side of the test plate. 3. The vibration stand according to claim 1, characterized in that the test plate is made of magnetic material. 4. The vibration stand according to claim 1, characterized in that the test plate is made of non-magnetic material, and the vibration sensor is mounted on the test plate with a screw made of magnetic material, and the vibration sensor is located above the location of the electromagnet. 5. The vibration stand according to claim 1, characterized in that the test plate is made of non-magnetic material, while an element of magnetic material is fixed on the test plate in the area corresponding to the installation location of the electromagnet. 6. The vibration stand according to claim 5, characterized in that the element of magnetic material is made in the form of a rod and is the core of the electromagnet.

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