CN210893115U - Wave sensor detection device - Google Patents

Abstract

The utility model discloses a wave sensor detection device, including driver, first sliding shaft, second sliding shaft, connecting block and fixed plate, the driver can drive the connecting block along first sliding shaft reciprocating motion, and when the connecting block along first sliding shaft reciprocating motion, second sliding shaft reciprocating motion is followed to first sliding shaft. During the test, will wait to detect the wave sensor and install on the fixed plate, start the driver, the driver drives the connecting block along the perpendicular reciprocating motion of first sliding shaft, and the horizontal reciprocating motion of second sliding shaft is followed to first sliding shaft, realizes the sinusoidal characteristic motion of static simulation wave, and in the testing process, the fixed plate remains the horizontality all the time, improves the testing process stability, the utility model discloses a wave sensor detection device, structural design is reasonable, and the working process is stable, and tests wave sensor before wave buoy assembly accomplishes, has improved testing result accuracy and detection efficiency.

Description

Wave sensor detection device

Technical Field

The utility model relates to an ocean observation equipment and peripheral supporting facility technical field especially relate to a wave sensor detection device.

Background

The marine observation system can collect data related to oceanography, monitor environmental pollution, climate change and transmit long-distance images. With the continuous development of the technology, the accuracy requirement of wave buoys is higher and higher in various countries, namely the accuracy requirement of wave sensors is higher and higher. At present, wave sensors based on the acceleration principle are widely applied.

Before assembling the wave buoy, the wave sensor needs to be detected, the condition that secondary assembly is generated under the condition that whether the wave sensor is damaged or the accuracy requirement is met is avoided, and therefore efficiency is improved, and energy and labor are saved. The existing wave sensor calibrating devices are large and heavy after the wave buoy is integrally assembled, and the used transmission mode is belt transmission or chain transmission, so that the precision is not high, the transmission stability is poor, certain impact is caused, and the wave sensor calibrating devices are easy to wear.

Therefore, how to change the current situation that in the prior art, the wave sensor test is performed after the wave buoy is assembled, and the stability of the test process is poor becomes a problem to be solved urgently by the technical staff in the field.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a wave sensor detection device to solve the problem that above-mentioned prior art exists, make testing arrangement can test wave sensor before the wave buoy assembly is accomplished, improve the test result accuracy.

In order to achieve the above object, the utility model provides a following scheme: the utility model provides a wave sensor detection device, which comprises a driver, a first sliding shaft, a second sliding shaft, a connecting block and a fixing plate, one end of the first sliding shaft is connected with the second sliding shaft in a sliding way, the second sliding shaft is fixed on the horizontal platform, the first sliding shaft is arranged perpendicular to the horizontal platform, the connecting block is arranged on the first sliding shaft in a sliding manner, the fixed plate is connected with the connecting block and can fix the wave sensor to be detected, the fixing plate is parallel to the horizontal platform, the driver is in transmission connection with the connecting block and can drive the connecting block to reciprocate along the first sliding shaft, and the first sliding shaft reciprocates along the second sliding shaft while the connecting block reciprocates along the first sliding shaft.

Preferably, the driver is a motor, the driver is connected with the connecting block through a rocker, the first end of the rocker is connected with the output end of the driver, the driver can drive the rocker to rotate, one end, close to the driver, of the connecting block is connected with a rotating shaft, the rotating shaft is rotatably connected with the rocker, and the connecting position of the rotating shaft and the rocker can be adjusted.

Preferably, a balancing weight is arranged on the rocker and detachably connected with the rocker.

Preferably, the connection point of the driver and the rocker is located between the counterweight and the rotating shaft.

Preferably, the rocker is of a cuboid structure.

Preferably, a bearing seat is arranged between the rotating shaft and the rocker, a mounting groove is formed in one end, connected with the rotating shaft, of the rocker, and a plurality of mounting positions matched with the bearing seat are arranged in the mounting groove.

Preferably, the wave sensor detection device further comprises a motor base, the driver is arranged on the motor base and connected with the rocker through a transmission shaft, one end of the transmission shaft is in key connection with the driver, and the end, connected with the rocker, of the transmission shaft is subjected to milling flattening treatment.

Preferably, a linear bearing and a linear bearing seat are arranged between the connecting block and the first sliding shaft and between the first sliding shaft and the second sliding shaft.

Preferably, a shock pad is arranged on the fixing plate, and the shock pad is made of a flexible material.

The utility model discloses for prior art gain following technological effect: the utility model discloses a wave sensor detection device, including the driver, first sliding shaft, the second sliding shaft, connecting block and fixed plate, the one end slidable ground of first sliding shaft links to each other with the second sliding shaft, the second sliding shaft is fixed in on the horizontal platform, first sliding shaft perpendicular to horizontal platform sets up, set up on first sliding shaft connecting block slidable ground, the fixed plate links to each other with the connecting block, the fixed plate can fix and wait to detect wave sensor, the fixed plate is on a parallel with horizontal platform and sets up, the driver links to each other with the connecting block transmission, the driver can drive the connecting block along first sliding shaft reciprocating motion, and when the connecting block was along first sliding shaft reciprocating motion, first sliding shaft is along second sliding shaft reciprocating motion. During the test, will wait to detect the wave sensor and install on the fixed plate, start the driver, the driver drives the connecting block along the perpendicular reciprocating motion of first sliding shaft, and the horizontal reciprocating motion of second sliding shaft is followed to first sliding shaft, realizes the sinusoidal characteristic motion of static simulation wave, and in the testing process, the fixed plate remains the horizontality all the time, improves the testing process stability, the utility model discloses a wave sensor detection device, structural design is reasonable, and the working process is stable, and tests wave sensor before wave buoy assembly accomplishes, has improved testing result accuracy and detection efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor.

Fig. 1 is a schematic structural view of a wave sensor detection device according to the present invention;

fig. 2 is a schematic structural view of a transmission shaft of the wave sensor detection device of the present invention;

wherein, 1 is the driver, 2 is first slip axle, 3 is the second slip axle, 4 are the connecting block, 5 are the fixed plate, 6 are the rocker, 7 are the pivot, 8 are the balancing weight, 9 are the mounting groove, 10 are the motor cabinet, 11 are the transmission shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model aims at providing a wave sensor detection device to solve the problem that above-mentioned prior art exists, make testing arrangement can test wave sensor before the wave buoy assembly is accomplished, improve the test result accuracy.

In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.

Please refer to fig. 1-2, wherein fig. 1 is a schematic structural diagram of a wave sensor detection device of the present invention, and fig. 2 is a schematic structural diagram of a transmission shaft of the wave sensor detection device of the present invention.

The utility model provides a wave sensor detection device, including driver 1, first sliding shaft 2, second sliding shaft 3, connecting block 4 and fixed plate 5, first sliding shaft 2's one end slidable links to each other with second sliding shaft 3, second sliding shaft 3 is fixed in on the horizontal platform, first sliding shaft 2 perpendicular to horizontal platform sets up, connecting block 4 slidable sets up on first sliding shaft 2, fixed plate 5 links to each other with connecting block 4, fixed plate 5 can fix and wait to detect wave sensor, fixed plate 5 is on a parallel with horizontal platform and sets up, driver 1 links to each other with connecting block 4 transmission, driver 1 can drive connecting block 4 along 2 reciprocating motion of first sliding shaft, and when connecting block 4 along 2 reciprocating motion of first sliding shaft, first sliding shaft 2 is along 3 reciprocating motion of second sliding shaft.

During the test, will wait to detect the wave sensor and install on fixed plate 5, start driver 1, driver 1 drives connecting block 4 along 2 vertical reciprocating motion of first sliding shaft, and 3 horizontal reciprocating motion of second sliding shaft are followed to first sliding shaft 2, realize the motion of the sinusoidal characteristic of static simulation wave, and in the test process, fixed plate 5 remains the horizontality throughout, improves test procedure stability, the utility model discloses a wave sensor detection device, structural design is reasonable, and the working process is stable, and tests wave sensor before wave buoy assembly accomplishes, has improved testing result accuracy and detection efficiency. It should be noted that the horizontal platform is a horizontal platform in the prior art, and the horizontal platform is well known to those skilled in the art and will not be described herein again.

Wherein, driver 1 is the motor, driver 1 links to each other with connecting block 4 through rocker 6, the first end of rocker 6 links to each other with driver 1's output, driver 1 can drive rocker 6 and rotate, connecting block 4 is close to the one end of driver 1 and is connected with pivot 7, pivot 7 rotationally links to each other with rocker 6, driver 1 rigidity, driver 1 drives connecting block 4 and the motion of first sliding shaft 2 through rocker 6, in order to realize the motion of the sinusoidal characteristic of static simulation wave, in addition, pivot 7 can be adjusted with rocker 6's hookup location, adjustment pivot 7 can detect the motion of the sinusoidal characteristic of wave sensor under different wave heights with rocker 6's hookup location. It should be noted here that the fixing position of the actuator 1 is required to satisfy the requirement of the reciprocating motion of the connecting block 4 and the first sliding shaft 2, and the fixing of the actuator 1 is a conventional means for those skilled in the art and will not be described herein. The utility model discloses an among other embodiments, mode such as cylinder can also be adopted to driver 1, all has the contained angle between the axis of cylinder and first sliding shaft 2, the second sliding shaft 3, and cylinder reciprocating motion drives connecting block 4 and 2 reciprocating motion of first sliding shaft.

Specifically, be provided with balancing weight 8 on rocker 6, the counter weight can improve the stationarity of rocker 6 motion process, and balancing weight 8 can be dismantled with rocker 6 and be connected, can select the balancing weight 8 of suitable weight according to the difference that specifically detects wave sensor.

In order to further improve the transmission stability, the connecting point of the driver 1 and the rocker 6 is positioned between the counterweight block 8 and the rotating shaft 7, and an operator can select a proper counterweight according to the weight of the wave sensor carried by the fixed plate 5 and sinusoidal curves with different wave heights so as to ensure the dynamic balance of the rocker 6 in the rotating process.

In this embodiment, the rocker 6 is a rectangular parallelepiped structure, which facilitates the connection of the rocker 6 with the driver 1 and the connecting block 4.

More specifically, set up the bearing frame between pivot 7 and the rocker 6, be provided with the bearing with pivot 7 looks adaptation in the bearing frame, guarantee that pivot 7 rotates smoothly, the one end that rocker 6 links to each other with pivot 7 is provided with mounting groove 9, and mounting groove 9 is provided with a plurality of installation positions with bearing frame looks adaptation, makes it install at different installation positions through the bearing frame to realize the purpose of adjustment pivot 7 and rocker 6 hookup location.

Wave sensor detection device still includes motor cabinet 10, and driver 1 sets up on motor cabinet 10, makes things convenient for driver 1 to fix, and driver 1 links to each other with rocker 6 through transmission shaft 11, and the one end and the 1 key-type connection of driver of transmission shaft 11, the one end that transmission shaft 11 and rocker 6 link to each other do and mill flat processing, be convenient for with 6 location installations of rocker and the great moment of torsion of transmission.

Further, linear bearings and linear bearing seats are arranged between the connecting block 4 and the first sliding shaft 2 and between the first sliding shaft 2 and the second sliding shaft 3, so that smooth movement is ensured.

In order to improve the stability of the detection process, a vibration-proof pad is arranged on the fixing plate 5 and is made of flexible materials, and the vibration-proof pad can absorb part of vibration and improve the flat temperature of the wave sensor. In the present embodiment, the fixing plate 5 is provided with positioning pin holes, and the fixing plate 5 can be made horizontal by the positioning pins.

The utility model discloses a wave sensor detection device during operation starts driver 1, makes under the 1 output shaft of driver at the uniform velocity and rotates, drives rocker 6 and makes at the uniform velocity and rotate to drive connecting block 4 and make vertical reciprocating motion, first sliding shaft 2 along second sliding shaft 3 along first sliding shaft 2 and make horizontal reciprocating sliding. Like this, rocker 6 is in at the uniform velocity pivoted, and fixed plate 5 remains the horizontality throughout, realizes the motion of the sinusoidal characteristic of static simulation wave, the utility model has the advantages of reasonable design, the working process is stable, and the application effect ideal. In order to avoid the influence of the device components on the detection precision, except for the driver 1, other components are made of non-magnetic materials.

The utility model discloses a concrete example is applied to explain the principle and the implementation mode of the utility model, and the explanation of the above example is only used to help understand the method and the core idea of the utility model; meanwhile, for the general technical personnel in the field, according to the idea of the present invention, there are changes in the concrete implementation and the application scope. In summary, the content of the present specification should not be construed as a limitation of the present invention.

Claims (9)

1. A wave sensor detection device characterized in that: including driver, first sliding shaft, second sliding shaft, connecting block and fixed plate, the one end slidable of first sliding shaft with the second sliding shaft links to each other, the second sliding shaft is fixed in on the horizontal platform, first sliding shaft perpendicular to horizontal platform sets up, the connecting block slidable set up in on the first sliding shaft, the fixed plate with the connecting block links to each other, the fixed plate can fix and wait to detect wave sensor, the fixed plate is on a parallel with the horizontal platform setting, the driver with the connecting block transmission links to each other, the driver can drive the connecting block is followed first sliding shaft reciprocating motion, just the connecting block is followed when first sliding shaft reciprocating motion, first sliding shaft is followed second sliding shaft reciprocating motion.

2. The wave sensor detection device of claim 1, wherein: the driver is a motor, the driver is connected with the connecting block through a rocker, the first end of the rocker is connected with the output end of the driver, the driver can drive the rocker to rotate, one end, close to the driver, of the connecting block is connected with a rotating shaft, the rotating shaft is rotatably connected with the rocker, and the connecting position of the rotating shaft and the rocker can be adjusted.

3. The wave sensor detection device of claim 2, wherein: the rocker is provided with a balancing weight, and the balancing weight is detachably connected with the rocker.

4. A wave sensor detection device according to claim 3, characterized in that: the connecting point of the driver and the rocker is positioned between the balancing weight and the rotating shaft.

5. The wave sensor detection device of claim 2, wherein: the rocker is of a cuboid structure.

6. The wave sensor detection device of claim 2, wherein: the bearing seat is arranged between the rotating shaft and the rocker, a mounting groove is formed in one end, connected with the rotating shaft, of the rocker, and a plurality of mounting positions matched with the bearing seat are arranged in the mounting groove.

7. The wave sensor detection device of claim 2, wherein: the motor base is further included, the driver is arranged on the motor base and is connected with the rocker through a transmission shaft, one end of the transmission shaft is connected with the driver in a key mode, and the end, connected with the rocker, of the transmission shaft is milled flat.

8. The wave sensor detection device of claim 1, wherein: and a linear bearing seat are arranged between the connecting block and the first sliding shaft and between the first sliding shaft and the second sliding shaft.

9. The wave sensor detecting device according to any one of claims 1-8, characterized in that: the fixing plate is provided with a shockproof pad, and the shockproof pad is made of flexible materials.

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