CN219867165U - Laboratory vibration monitoring device - Google Patents

Abstract

The utility model provides a laboratory vibration monitoring device, which relates to the technical field of vibration monitoring, wherein a sliding block is also connected in a longitudinal groove formed in a bracket in a sliding manner, an electric push rod A is connected with the sliding block, and the inner sides of the two sliding blocks are fixedly connected with guide rails, so that the problem that the conventional vibration monitoring device can only realize detection of a fixed position when a workbench is subjected to vibration detection due to the lack of an effective multidirectional adjusting structure in use, and further has limitation is solved.

Description

Laboratory vibration monitoring device

Technical Field

The utility model belongs to the technical field of vibration monitoring, and particularly relates to a laboratory vibration monitoring device.

Background

When laboratory is inside to be tested, corresponding workbench is generally used for bearing various instruments, and when the laboratory is tested, whether the workbench vibrates and the vibration condition is detected generally in order to ensure the precision of the test, a corresponding vibration monitoring device is needed, and when the vibration monitoring device is used, due to the fact that the vibration monitoring device lacks an effective multidirectional adjusting structure, only fixed-position detection can be realized when the workbench is subjected to vibration detection, and further limitations exist.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a laboratory vibration monitoring device to solve the problem that the existing vibration monitoring device is limited because of the lack of an effective multidirectional adjusting structure when in use, so that only detection of a fixed position can be realized when a workbench is subjected to vibration detection.

The purpose and the efficacy of the laboratory vibration monitoring device are achieved by the following specific technical means:

the laboratory vibration monitoring device comprises a bracket, wherein two parts are arranged on the bracket, longitudinal grooves are formed in the two parts of the bracket, an electric push rod A is arranged in the longitudinal grooves, sliding connection is further arranged in the longitudinal grooves formed in the bracket, the electric push rod A is connected with the sliding blocks, and guide rails are fixedly connected on the inner sides of the two parts of the sliding blocks.

Further, the support legs are respectively and fixedly connected to four corners of the bottom end face of the base, a transverse groove is formed in the guide rail, and an electric push rod B is mounted in the transverse groove.

Further, support structure has been constituteed jointly to support and bottom plate, fixedly connected with stabilizer blade on the bottom end face of base, and the stabilizer blade is equipped with everywhere altogether, when set up vibration sensor on mounting panel top and fixed connection at the bottom end face of the bottom plate on two support tops can, and when the bottom plate appears vibrating, can detect the back through vibration sensor, carries out continuous detection operation through utilizing the controller that sets up on the base top with the vibration that current device during operation produced, and then reaches more practical purpose.

Further, the support and the bottom plate form a bearing structure together, the inside of the bottom plate is provided with through grooves in a linear array, and the top end face of the base is also provided with a controller.

Further, a movable seat is slidably connected in a transverse groove formed in the guide rail, an electric push rod B is connected with the movable seat, a bedplate is fixedly connected to the top end of the movable seat, an electric push rod C is mounted on the top end of the bedplate, a mounting plate is mounted on the top end of the electric push rod C, and a vibration sensor is mounted on the top end of the mounting plate.

Further, two the support respectively fixed connection is in the left and right sides position of base terminal surface, and the top fixedly connected with bottom plate of two support when the bottom plate appears vibrating, can detect the back through vibration sensor, carries out continuous detection operation through utilizing the controller that sets up on the base top with the produced vibration of current device during operation, and then reaches more practical purpose.

Compared with the prior art, the utility model has the following beneficial effects:

1. when carrying out the experiment, can be through carrying out the contact with the stabilizer blade and the working face of fixed connection in the base bottom in advance so as to support, and when the vibration amplitude of bottom plate detects when the experiment needs, can promote the slider through starting the electric putter A of installing in the support, and drive fixed connection and carry out vertical promotion at its inboard guide rail through the slider, and drive the vibration sensor who installs on the mounting panel top through the longitudinal displacement of guide rail and carry out synchronous displacement adjustment, this design can carry out quick adaptation adjustment according to the difference of the current required detection position, and then reach the purpose that is convenient for follow-up detection use more.

2. When the transverse position of the vibration sensor needs to be adjusted, the transverse position of the movable seat can be adjusted by starting the electric push rod B installed in the guide rail, and after the transverse position adjustment of the movable seat is completed, the mounting plate and the vibration sensor installed at the top end of the mounting plate are synchronously adjusted in height by starting the electric push rod C installed at the top end of the bedplate until the vibration sensor arranged at the top end of the mounting plate is contacted with the bottom end surface of the bottom plate fixedly connected with the top ends of the two brackets, and when the bottom plate vibrates, the vibration generated during the operation of the current device can be continuously detected by utilizing the controller arranged at the top end of the base after the vibration sensor is detected, so that the aim of more practicability is achieved.

Drawings

Fig. 1 is a schematic view of a front side view in a partially cut-away state of the structure of the present utility model.

Fig. 2 is a schematic diagram of the front side view of the present utility model.

FIG. 3 is a schematic diagram showing the structure of the base to controller of the present utility model.

FIG. 4 is a schematic diagram showing the structure of the slider-to-vibration sensor of the present utility model.

In the figure, the correspondence between the component names and the drawing numbers is:

1. a base; 2. a support leg; 3. a bracket; 4. a bottom plate; 5. an electric push rod A; 6. a slide block; 7. a guide rail; 8. an electric push rod B; 9. a controller; 10. a movable seat; 11. a platen; 12. an electric push rod C; 13. a mounting plate; 14. a vibration sensor.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Examples:

as shown in fig. 1 to 4:

the utility model provides a laboratory vibration monitoring device, which comprises a bracket 3, wherein two positions are arranged in the bracket 3, longitudinal grooves are formed in the two positions of the bracket 3, an electric push rod A5 is arranged in the longitudinal grooves, a sliding block 6 is also connected in the longitudinal grooves formed in the bracket 3 in a sliding manner, the electric push rod A5 is connected with the sliding block 6, guide rails 7 are fixedly connected with the inner sides of the two sliding blocks 6, a movable seat 10 is connected in the transverse grooves formed in the guide rails 7 in a sliding manner, an electric push rod B8 is connected with the movable seat 10, a platen 11 is fixedly connected with the top end of the movable seat 10, an electric push rod C12 is arranged at the top end of the platen 11, a mounting plate 13 is arranged at the top end of the electric push rod C12, and a vibration sensor 14 is arranged at the top end of the mounting plate 13.

Wherein, two places support 3 are fixed connection respectively in the left and right sides position of the terminal surface of base 1, the top fixedly connected with bottom plate 4 of two places support 3, the bearing structure has been constituteed jointly to support 3 and bottom plate 4, the inside of bottom plate 4 is the linear array and has seted up logical groove, still install controller 9 on the terminal surface of base 1, when carrying out the experiment, can be through contacting stabilizer blade 2 of fixed connection in the base 1 bottom with the working face in advance in order to support, and when need detect the vibration amplitude of bottom plate 4 when the experiment, can come to promote slider 6 through starting the electric putter A5 of installing in support 3, and drive the guide rail 7 of fixed connection in its inboard through slider 6 and carry out vertical promotion, and drive the vibration sensor 14 of installing at mounting panel 13 top through the longitudinal displacement of guide rail 7 and carry out synchronous displacement adjustment, this design can carry out quick adaptation adjustment according to the difference of the present required detection position, and then reach the purpose that is convenient for follow-up detection and use.

Wherein, support 3 and bottom plate 4 have formed bearing structure jointly, fixedly connected with stabilizer blade 2 on the bottom end face of base 1, stabilizer blade 2 is equipped with everywhere altogether, stabilizer blade 2 is fixed connection in the four corners position of base 1 bottom end face respectively everywhere, transverse groove has been seted up to the inside of guide rail 7, the internally mounted in this transverse groove has electric putter B8, when need adjust the transverse position of vibration sensor 14, can adjust the transverse position of movable seat 10 through the electric putter B8 that starts to install in guide rail 7, and after the transverse position adjustment of movable seat 10 is accomplished, the electric putter C12 of rethread start-up installation at platen 11 top carries out synchronous altitude mixture control with mounting panel 13 and the vibration sensor 14 of installing at the mounting panel 13 top, until when the vibration sensor 14 that sets up at the mounting panel 13 top and the bottom surface of bottom plate 4 of fixed connection at two support 3 tops contact, and when vibration appears at bottom plate 4, can detect the back through vibration sensor 14, through utilizing the controller 9 that sets up at the base 1 top and the detection that produces when the device work, carry out the vibration and then reach the purpose that is continuous more practical.

Specific use and action of the embodiment:

when the device is used, in the laboratory experiment process, the experiment operation can be carried out by placing the instrument to be controlled on the bottom plate 4 fixedly connected with the top ends of the two brackets 3;

when an experiment is carried out, the support legs 2 fixedly connected to the bottom end of the base 1 can be contacted with the working surface in advance to support, when the vibration amplitude of the bottom plate 4 is detected when the experiment is required, the electric push rod A5 arranged in the bracket 3 can be started to push the slide block 6, the slide block 6 drives the guide rail 7 fixedly connected to the inner side of the slide block to longitudinally push the slide block, and the vibration sensor 14 arranged at the top end of the mounting plate 13 is driven to synchronously carry out displacement adjustment through the longitudinal displacement of the guide rail 7;

when the transverse position of the vibration sensor 14 needs to be adjusted, the transverse position of the movable seat 10 can be adjusted by starting the electric push rod B8 installed in the guide rail 7, and after the transverse position adjustment of the movable seat 10 is completed, the height adjustment of the mounting plate 13 and the vibration sensor 14 installed at the top end of the mounting plate 13 is synchronously performed by starting the electric push rod C12 installed at the top end of the bedplate 11 until the vibration sensor 14 installed at the top end of the mounting plate 13 is contacted with the bottom end surface of the bottom plate 4 fixedly connected with the top ends of the two brackets 3, and when the bottom plate 4 vibrates, the vibration generated during the operation of the current device can be continuously detected by utilizing the controller 9 arranged at the top end of the bedplate 1 after the detection of the vibration by the vibration sensor 14, so that the aim of more practicability is achieved.

Claims (6)

1. Laboratory vibration monitoring device, its characterized in that: including support (3), support (3) are equipped with two altogether, and the inside of two support (3) has all been seted up longitudinal groove, and the internally mounted in this longitudinal groove has electric putter A (5), and the inside sliding connection that still has slider (6) of longitudinal groove of seting up in support (3), electric putter A (5) are connected with slider (6), the inboard fixedly connected with guide rail (7) of two slider (6).

2. The laboratory vibration monitoring apparatus of claim 1, wherein: the two brackets (3) are respectively and fixedly connected to the left side and the right side of the top end face of the base (1), and the bottom plates (4) are fixedly connected to the top ends of the two brackets (3).

3. The laboratory vibration monitoring apparatus of claim 2, wherein: the support (3) and the bottom plate (4) form a bearing structure together, through grooves are formed in the bottom plate (4) in a linear array, and a controller (9) is further arranged on the top end face of the base (1).

4. A laboratory vibration monitoring apparatus according to claim 3, wherein: the support (3) and the bottom plate (4) form a supporting structure together, the bottom end face of the base (1) is fixedly connected with the support legs (2), and the support legs (2) are arranged everywhere.

5. The laboratory vibration monitoring apparatus of claim 4, wherein: four support legs (2) are respectively and fixedly connected to four corners of the bottom end face of the base (1), transverse grooves are formed in the guide rail (7), and electric push rods B (8) are arranged in the transverse grooves.

6. The laboratory vibration monitoring apparatus of claim 5, wherein: the automatic vibration control device is characterized in that a movable seat (10) is slidably connected in a transverse groove formed in the guide rail (7), an electric push rod B (8) is connected with the movable seat (10), a table plate (11) is fixedly connected to the top end of the movable seat (10), an electric push rod C (12) is mounted on the top end of the table plate (11), a mounting plate (13) is mounted on the top end of the electric push rod C (12), and a vibration sensor (14) is mounted on the top end of the mounting plate (13).