CN210347626U - Wireless water body section observation device - Google Patents

Abstract

The utility model discloses a wireless water section observation device, which comprises a buoyancy body, a wire wheel, a support frame, a probe, a signal wire, a measurement circuit module and a wireless signal antenna; the supporting frame is arranged on the buoyancy body, the signal wire is wound on the wire wheel in a winding mode, and the wire wheel is arranged on the supporting frame in a pivoting mode; the measuring circuit module and the wireless signal antenna are both arranged on the buoyancy body and are in electric signal connection; one end of the signal wire is in electrical signal connection with the measuring circuit module, and the other end of the signal wire is in electrical signal connection with the probe. In the using process, the detection ship can run and be put into seawater at the same time, the detection ship does not need to stop for waiting, and the time is saved; in addition, the device adopts the wireless signal antenna to transmit the ocean information to the receiving equipment on the detection ship, so that the defect that a copper wire for transmitting signals is easy to break under the condition of high sea condition or high ship speed in the prior art is overcome.

Description

Wireless water body section observation device

Technical Field

The utility model relates to a wireless formula water section observation device.

Background

The disposable probe is a measuring device for detecting relevant ocean data, and is also called a profile automatic cycle detector; the existing disposable probe uses a double-strand thin copper wire as a communication means, namely, the disposable probe and a detection ship realize signal connection by the thin copper wire, but the probe is used for uploading measurement data while falling, the detection ship always keeps running, and under the condition of high sea condition or high ship speed, the copper wire is easy to break, so that the data communication is interrupted, and the problem that the ocean profile data of the expected depth cannot be collected is caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a wireless formula water section observation device solves one or more among the above-mentioned prior art problem.

According to one aspect of the utility model, a wireless water body section observation device is provided, which comprises a buoyancy body, a wire wheel, a support frame, a probe, a signal wire, a measuring circuit module and a wireless signal antenna; the supporting frame is arranged on the buoyancy body, the signal wire is wound on the wire wheel in a winding mode, and the wire wheel is arranged on the supporting frame in a pivoting mode; the measuring circuit module and the wireless signal antenna are both arranged on the buoyancy body and are in electric signal connection; one end of the signal wire is in electrical signal connection with the measuring circuit module, and the other end of the signal wire is in electrical signal connection with the probe.

Therefore, in an initial state, at least most of signal wires are wound on the wire wheel, the probe is close to the wire wheel, when a detection ship sails, a user puts the device into seawater, the buoyancy body bears the wire wheel, the support frame, the measuring circuit module and the wireless signal antenna to float on the sea surface, the wire wheel is pivotally arranged on the support frame, the probe draws the signal wires to start submerging under the action of self gravity, and the signal wires draw the wire wheel to rotate to release corresponding lengths to adapt to the submerging depth of the probe; in the process of sinking of the probe, the ocean information (such as depth, temperature and the like) of each section layer is acquired through instrument equipment on the probe, meanwhile, the probe transmits the ocean information to the measuring circuit module in real time through a signal line, then the measuring circuit module transmits the ocean information to receiving equipment on a detection ship through a wireless signal antenna, and in the process, the detection ship can run while putting the device into the seawater, the detection ship does not need to stop for waiting, and the time is saved; in addition, the device adopts the wireless signal antenna to transmit the ocean information to the receiving equipment on the detection ship, so that the defect that a copper wire for transmitting signals is easy to break under the condition of high sea condition or high ship speed in the prior art is overcome.

In some embodiments, the support frame comprises a first support beam, a second support beam, and an intermediate connecting beam; the first supporting beam and the second supporting beam are arranged on two ends of the middle connecting beam in parallel, and a spacing space is arranged between the first supporting beam and the second supporting beam; the wire wheel is characterized by further comprising a rotating shaft and two bearings, the rotating shaft is arranged at the middle shaft of the wire wheel in a penetrating mode, two ends of the rotating shaft are mounted on the first supporting beam and the second supporting beam through the two bearings respectively, and the wire wheel is accommodated in the space.

Like this, through with first supporting beam and second supporting beam parallel arrangement on the both ends of intermediate junction roof beam for be equipped with the interval space that is used for holding the line wheel between first supporting beam and the second supporting beam, and the pivot sets up the axis position at the line wheel with running through, the both ends of pivot still install on first supporting beam and second supporting beam through two bearings respectively, the line wheel rotates on the support frame through pivot and bearing, has realized setting up the wheel on the support frame with pivoting promptly.

In some embodiments, a wire sleeve and a support rod are also included; one end of the supporting rod is arranged on the second supporting beam, the wire sleeve is arranged at the other end of the supporting rod, and one end of the signal wire, which is used for connecting the probe, penetrates through the wire sleeve.

Therefore, when the probe draws the signal wire to start to dive under the action of self gravity, the signal wire is released after being guided by the guide of the wire sleeve, and the signal wire is prevented from deviating from the direction under the disturbance of water flow, so that the phenomena of knotting and winding of the signal wire in the releasing process are avoided.

In some embodiments, a control system and a stepper motor are also included; wherein, step motor sets up to the drive line wheel and rotates, and control system and wireless signal antenna electric signal are connected, and control system and step motor electric signal are connected.

Therefore, the stepping motor is arranged to drive the wire wheel to rotate, and the control system can control the rotating speed of the wire wheel by controlling the rotating speed of the stepping motor, so that the releasing speed of the signal wire is controlled, the submerging speed of the probe is further controlled, and the probe can be controlled to submerge according to the preset speed by the device; in addition, after the probe is submerged, the control system can also instruct the stepping motor to rotate reversely to drive the wire wheel to withdraw the signal wire, so that the probe is driven to float upwards, and in the process of floating the probe, the probe can collect the ocean information of each section layer again, so that the probe can be repeatedly operated to complete multiple times of detection; in addition, because the control system is in electric signal connection with the wireless signal antenna, workers on the detection ship can also instruct the control system to control the rotation of the stepping motor through the wireless signal antenna so as to control the depth speed and the times of the probe submergence detection.

In some embodiments, a salinity detection module is arranged on the probe.

Therefore, the salinity information of each profile layer can be measured in real time through the salinity detection module in the submerging process of the probe, and the device has the function of collecting the salinity information.

Drawings

Fig. 1 is a wireless water profile observation device according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the wireless water body section observation device shown in FIG. 1 in an initial state;

FIG. 3 is a schematic view of the wireless water body profile observation device shown in FIG. 1 with the probe in a sinking state;

fig. 4 is a wireless water profile observation device according to another embodiment of the present invention.

Reference numerals:

1-buoyancy body, 2-wire wheel, 3-support frame, 31-first support beam, 32-second support beam, 33-middle connecting beam, 34-rotating shaft, 4-probe, 5-signal wire, 6-wireless signal antenna, 7-wire sleeve, 71-support rod, 8-stepping motor and 9-detection ship

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 to fig. 3 schematically show the structure of a wireless water body profile observation device according to an embodiment of the present invention.

As shown in fig. 1 to 3, the wireless water body profile observation device comprises a buoyant body 1, a wire wheel 2, a support frame 3, a probe 4, a signal wire 5, a measurement circuit module and a wireless signal antenna 6; wherein, the supporting frame 3 is arranged on the buoyancy body 1, the signal wire 5 is wound on the wire wheel 2, and the wire wheel 2 is pivotally arranged on the supporting frame 3; the measuring circuit module and the wireless signal antenna 6 are both arranged on the buoyancy body 1, and the measuring circuit module is in electric signal connection with the wireless signal antenna 6; one end of the signal wire 5 is in electrical signal connection with the measuring circuit module, and the other end of the signal wire 5 is in electrical signal connection with the probe 4.

In an initial state, at least most of signal wires 5 are wound on the wire wheel 2, the probe 4 is close to the wire wheel 2, when a detection ship 9 sails, a user puts the device into seawater, the buoyancy body 1 bears the wire wheel 2, the support frame 3, the measuring circuit module and the wireless signal antenna 6 and floats on the sea surface, the probe 4 drags the signal wires 5 to dive under the action of self gravity as the wire wheel 2 is pivotally arranged on the support frame 3, and the signal wires 5 drag the wire wheel 2 to rotate to release corresponding length to adapt to the diving depth of the probe 4; in the sinking process of the probe 4, the ocean information (such as depth, temperature and the like) of each section layer is collected through instrument equipment on the probe 4, meanwhile, the probe 4 transmits the ocean information to the measuring circuit module in real time through the signal wire 5, then the measuring circuit module transmits the ocean information to receiving equipment on the detection ship 9 through the wireless signal antenna 6, in the process, the detection ship 9 can run while putting the device into the seawater, the detection ship 9 does not need to stop for waiting, and the time is saved; in addition, as the device adopts the wireless signal antenna 6 to transmit the ocean information to the receiving equipment on the detection ship 9, the defect that a copper wire for transmitting signals is easy to break under the condition of high sea condition or high ship speed in the prior art is overcome.

In detail, in the present embodiment, the support frame 3 includes a first support beam 31, a second support beam 32, and an intermediate connection beam 33; the first support beam 31 and the second support beam 32 are arranged in parallel on both ends of the intermediate connecting beam 33, and a spacing space is provided between the first support beam 31 and the second support beam 32; the drum type pulley device further comprises a rotating shaft 34 and two bearings, wherein the rotating shaft 34 is arranged at the middle shaft part of the drum 2 in a penetrating mode, two ends of the rotating shaft 34 are respectively installed on the first supporting beam 31 and the second supporting beam 32 through the two bearings, and the drum 2 is accommodated in the space. In this way, the first support beam 31 and the second support beam 32 are arranged in parallel at two ends of the intermediate connection beam 33, so that a space for accommodating the reel 2 is provided between the first support beam 31 and the second support beam 32, the rotating shaft 34 is arranged in the middle shaft part of the reel 2 in a penetrating manner, two ends of the rotating shaft 34 are further respectively arranged on the first support beam 31 and the second support beam 32 through two bearings, and the reel 2 rotates on the support frame 3 through the rotating shaft 34 and the bearings, namely, the wheels are arranged on the support frame 3 in a pivoting manner. In other embodiments, the specific structure that allows the wheels to be pivotally arranged on the support frame 3 can also be suitably adapted to the actual situation.

In this embodiment, the wire sleeve 7 and the support rod 71 are also included; one end of the support bar 71 is disposed on the second support beam 32, the wire sleeve 7 is mounted on the other end of the support bar 71, and one end of the signal line 5 for connecting the probe 4 passes through the wire sleeve 7. Therefore, when the probe 4 pulls the signal wire 5 to dive under the action of self gravity, the signal wire 5 is released after being guided by the wire sleeve 7, and the signal wire 5 is prevented from deviating from the direction under the disturbance of water flow, so that the phenomena of knotting and winding of the signal wire 5 in the releasing process are avoided.

In this embodiment, the probe 4 is provided with a salinity detection module. Therefore, the salinity information of each profile layer can be measured in real time by the salinity detection module in the submerging process of the probe 4, so that the device has the function of collecting the salinity information.

Example two:

the difference between this embodiment and the first embodiment is:

fig. 4 schematically shows the structure of a wireless water body profile observation device according to another embodiment of the present invention.

As shown in fig. 4, in the present embodiment, the wireless water body profile observation device further includes a control system and a stepping motor 8; the stepping motor 8 is arranged to drive the wire wheel 2 to rotate, the control system is in electric signal connection with the wireless signal antenna 6, and the control system is in electric signal connection with the stepping motor 8; in detail, the specific structure for realizing that the stepping motor 8 drives the reel 2 to rotate is that a driving shaft of the stepping motor 8 is coaxially connected with a rotating shaft 34, the driving shaft drives the rotating shaft 34 to rotate together, and the rotating shaft 34 drives the reel 2 to rotate together; in other embodiments, the specific structure for realizing that the stepping motor 8 drives the reel 2 to rotate may also be: synchronous gears are respectively arranged on the driving shaft of the stepping motor 8 and the rotating shaft 34, and then synchronous pulleys are respectively meshed and paired with the two synchronous gears. Therefore, the stepping motor 8 is arranged to drive the wire wheel 2 to rotate, and the control system can control the rotating speed of the wire wheel 2 by controlling the rotating speed of the stepping motor 8, so that the releasing speed of the signal wire 5 is controlled, and the submerging speed of the probe 4 is further controlled, and the device can control the probe 4 to submerge according to the preset speed; in addition, after the probe 4 finishes submerging, the control system can also instruct the stepping motor 8 to rotate reversely to drive the wire wheel 2 to withdraw the signal wire 5, so as to drive the probe 4 to float upwards, and in the process of floating the probe 4, the probe 4 can collect the ocean information of each section layer again, so that repeated operation of the probe 4 can finish multiple times of detection; in addition, because the control system is in electric signal connection with the wireless signal antenna 6, workers on the detection ship 9 can also instruct the control system to control the rotation of the stepping motor 8 through the wireless signal antenna 6 so as to control the submerged detection times of the probe 4.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (5)

1. The wireless water body section observation device is characterized by comprising a buoyancy body, a wire wheel, a support frame, a probe, a signal wire, a measurement circuit module and a wireless signal antenna;

the supporting frame is arranged on the buoyancy body, the signal wire is wound on the wire wheel in a winding mode, and the wire wheel is arranged on the supporting frame in a pivoting mode; the measuring circuit module and the wireless signal antenna are both arranged on the buoyancy body and are in electric signal connection;

one end of the signal wire is in electrical signal connection with the measuring circuit module, and the other end of the signal wire is in electrical signal connection with the probe.

2. The wireless water body profile observation device of claim 1, wherein the support frame comprises a first support beam, a second support beam, and an intermediate connecting beam; the first supporting beam and the second supporting beam are arranged at two ends of the middle connecting beam in parallel, and a spacing space is arranged between the first supporting beam and the second supporting beam;

the wire wheel is characterized by further comprising a rotating shaft and two bearings, the rotating shaft is arranged at the middle shaft part of the wire wheel in a penetrating mode, two ends of the rotating shaft are installed on the first supporting beam and the second supporting beam through the two bearings respectively, and the wire wheel is accommodated in the space.

3. The wireless water body profile observation device according to claim 2, further comprising a wire sleeve and a support rod;

one end of the supporting rod is arranged on the second supporting beam, the wire sleeve is arranged at the other end of the supporting rod, and one end of the signal wire, which is used for connecting the probe, penetrates through the wire sleeve.

4. The wireless water body profile observation device according to claim 2 or 3, further comprising a control system and a stepper motor;

the stepping motor is arranged to drive the wire wheel to rotate, the control system is in electric signal connection with the wireless signal antenna, and the control system is in electric signal connection with the stepping motor.

5. The wireless water body profile observation device according to claim 1, wherein a salinity detection module is arranged on the probe.

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