RU63528U1 - MULTI-DIRECTED TEST VIBROSTEND - Google Patents

Abstract

The utility model relates to the field of vibration testing of structures, specifically to the construction of multidirectional test vibration stands. This technical solution is aimed at creating a vibration bench that creates three-component linear vibrations on the test product using one vibration exciter that creates vibrations along its axis, which allows to increase the accuracy of the test modes, simplify the design of the vibration bench, and eliminate the need to create a synchronous control system for several vibration exciters. To achieve the specified technical result in a test stand including a vibration exciter, a platform having a base for connecting to a vibration exciter table and a base with nodes for mounting the test object, the plane of the platform base with nodes for mounting the test object forms with the base plane for connecting with

exciter table dihedral angle , where n ₁ , n ₂ and n ₃ are the components of the given vibration accelerations in the central orthogonal axes of the test object, while the attachment points are configured to install the object so that one of its central orthogonal axes coinciding with the direction of vibration acceleration n ₁ forms an angle with the edge of the dihedral angle .

Description

The utility model relates to the field of vibration testing of structures, specifically to the construction of multidirectional test vibration stands.

Known vibration stands, any of which can be taken as a prototype, in which the platform for installing the test object, made in the form of a parallelogram, is connected through intermediate nodes to tables of three vibration exciters installed in mutually perpendicular directions (A.S. USSR No. 849030, class G01M 7/00; AS USSR No. 1035445, class G01M 7/00; Collection “Vibration Technique” - M, Moscow House of Scientific and Technical Propaganda, 1976, 100 s, Dzenkevich V.I., Stepanov V. I. “Vibration stands”).

The essential features of the prototype, which coincide with the essential features of the proposed technical solution, are the presence of a vibration exciter in the test stand, which creates vibration along its axis and platform for installing the test object with intermediate nodes connecting the platform to the exciter table.

The disadvantages of vibration stands, any of which can be taken as a prototype, are the complexity and bulkiness of the design, the difficulty in obtaining the required accuracy of the reproduction of test modes associated with the inevitably non-identical vibration exciters and intermediate connection nodes causing phase shifts between orthogonal vibration components, the need to create synchronous control system of several vibration exciters.

This technical solution is aimed at creating a vibration bench that creates three-component linear vibrations on the test person.

the product using a single vibration exciter, creating vibrations along its axis, which allows to increase the accuracy of the test modes, simplify the design of the vibration stand, eliminate the need to create a synchronous control system for several vibration exciters.

To achieve the specified technical result in a test stand, including a vibration exciter, a platform having a base for connecting to the vibration exciter table and a base with nodes for mounting the test object, the plane of the platform base with nodes for mounting the test object forms a dihedral angle with the base plane for connecting to the vibration exciter table , where n ₁ , n ₂ and n ₃ are the components of the given vibration accelerations in the central orthogonal axes of the test object, while the attachment points are configured to install the object so that one of its central orthogonal axes coinciding with the direction of vibration acceleration n ₁ forms an angle with the edge of the dihedral angle .

Distinctive features of the declared test bench are the following - the base plane with the nodes for mounting the test object forms a dihedral angle with the base plane for connecting to the exciter table where n ₁ , n ₂ and n ₃ are the components of the given vibration accelerations in the central orthogonal axes of the test object, while the attachment points are made so that one of its central orthogonal axes coinciding with the direction of vibration acceleration n ₁ forms an angle with the edge of the dihedral angle .

Due to the presence of these distinctive features in conjunction with the known features (prototype), the claimed test vibrator allows you to create flat and spatial linear vibrations, shock and vibration with specified components with one vibrator on the test objects. The capabilities of single-component vibration stands are expanding. External mechanical influences can be reproduced as fully as possible without distortion, the set of equipment used is reduced, the vibration test control system is simplified, and energy saving is increased. Test times can be reduced to a minimum.

The proposed solution can find application in instrumentation, engineering and other industries where it is necessary to check products for resistance to flat and spatial mechanical stresses.

The proposed technical solution is illustrated in the figure.

The figure shows the platform of the test bench. The platform consists of a rectangular prism 1 with a base 2 for attaching a vibrator 4 to the table 3 and a base 5 for attaching the test object 6. In the particular case, for example, for the ratio of the spatial vibration components and characteristic of the mode of automobile transportation, the stand platform is performed with angles θ = 45 ° and φ = 39.5 °.

The claimed test bench works as follows: the components of spatial vibration determine the amplitude of the acceleration along the working axis of the vibrator . The test object is installed on the basis of the platform. Vibration stand along the axis of the vibrator create vibration acceleration with an amplitude of n.

To minimize the lateral component loads on the vibrator, it is advisable to install the test object so that its center of mass is on the axis of the vibrator.

For the above ratio of accelerations along the axes, we have n = 1.32n ₂ = 1.32n _y .

Claims (1)

A multidirectional test vibration bench including a vibration exciter, a platform having a base for connecting to a vibration exciter table and a base with nodes for mounting the test object, characterized in that the plane of the platform base with nodes for mounting the test object forms a dihedral angle with the base plane for connecting to the vibration exciter table

, where n ₁ , n ₂ and n ₃ are the components of the given vibration accelerations in the central orthogonal axes of the object, while the attachment nodes are configured to install the object so that one of the central orthogonal axes of the object coincides with the direction of vibration

forms an angle with the edge of the dihedral angle

.