CN213768909U - Glass fiber reinforced plastic composite water flow monitoring ship - Google Patents

Abstract

The utility model belongs to rivers monitoring ship field specifically is glass steel composite current monitoring ship, including hull and monitoring cabin, monitoring cabin fixed mounting is at the upper surface of hull, the inside in monitoring cabin is equipped with frequency measurement ware, rivers velometer and wind detector respectively, one side fixed mounting in monitoring cabin has the measurement motor, the bottom of hull one side is equipped with changes the leaf, the both sides fixed mounting of hull has the buoyancy case. When the monitoring ship is used, the floating block is matched with the telescopic rod to change the height according to the draught degree of a ship body, and data are transmitted to the water flow velometer to be analyzed through the position sensor at the upper end of the floating block. When the monitoring ship is running, wind power received in the running process is collected through a wind vane and a wind detector, the wind power is transmitted to a water flow velometer, meanwhile, water flow drives a rotating blade to rotate, the rotating frequency of the rotating blade is fed back to a frequency measuring device through a rotating shaft and a measuring motor, and the frequency measuring device transmits data to the water flow velometer to be analyzed.

Description

Glass fiber reinforced plastic composite water flow monitoring ship

Technical Field

The utility model relates to a rivers monitoring ship field especially relates to compound rivers monitoring ship of glass steel.

Background

The water flow monitoring ship is a device for measuring the speed of water flow, and the measurement of the flow speed of water flow in a river channel has great significance in hydrological measurement, agricultural irrigation, flood control and protection, river channel maintenance and other aspects. Water is a valuable resource essential for human production and life, but its naturally occurring state does not completely meet the needs of human beings. Only when hydraulic engineering is built, water flow can be controlled, flood disasters are prevented, and water quantity is adjusted and distributed to meet the requirements of people on water resources in life and production.

The existing water flow velocity measuring device has the defects of high price, large volume, inconvenient movement and use and the like, and meanwhile, the buoyancy of the water flow measuring ship in the prior art cannot be adjusted when the water flow measuring ship is used in different water areas.

In order to solve the problems, the application provides a glass fiber reinforced plastic composite water flow monitoring ship.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a compound rivers monitoring ship of glass steel to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: compound rivers monitoring ship of glass steel, including hull and monitoring cabin, monitoring cabin fixed mounting is at the upper surface of hull, the inside in monitoring cabin is equipped with frequency measurement ware, rivers velometer and wind detector respectively, one side fixed mounting in monitoring cabin has measuring motor, the bottom of hull one side is equipped with the commentaries on classics leaf, the both sides fixed mounting of hull has the buoyancy tank.

Preferably, the bottom of buoyancy tank is equipped with the kicking block, the upper end fixedly connected with telescopic link of kicking block, the one end fixed mounting of telescopic link is on the top of buoyancy tank, the upper end fixed mounting of kicking block has position sensor.

Preferably, the number of the telescopic rods is two, and the telescopic rods are symmetrically distributed on two sides of the upper end of the floating block.

Preferably, the mounting panels are welded on two sides of the ship body, slotted holes are formed in one side of the buoyancy tank and the mounting panels, bolts are arranged in the slotted holes, and the buoyancy tank is fixedly mounted on the mounting panels through the bolts.

Preferably, a wind vane is fixedly mounted at the upper end of the ship body and is matched with a wind power detector inside the monitoring cabin.

Preferably, the rotating blade is fixedly installed at one end of the rotating shaft, the other end of the rotating shaft is fixedly connected with the measuring motor, and the measuring motor is fixedly connected with the frequency measuring device through a connecting rod.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses, this monitoring ship is when using, according to the draft of hull, changes the height of buoyancy tank floating block, and floating block cooperation telescopic link carries out the change of height, has position sensor at the upper end fixed mounting of floating block simultaneously, carries out the analysis in data transmission to the rivers velometer through position sensor.

2. The utility model discloses, when the monitoring ship was when going, collect the wind-force that the in-process received of going through wind vane and wind detector, transmit it to the rivers velometer, rivers drive the commentaries on classics leaf and rotate simultaneously, through axis of rotation and during measuring motor will change the rotational frequency feedback to the frequency meter of leaf, the frequency meter carries out the analysis with data transmission in the rivers velometer.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic top view of the present invention;

fig. 3 is a schematic structural view of the buoyancy tank of the present invention.

In the figure: 1. a hull; 2. rotating the leaves; 3. a rotating shaft; 4. measuring the motor; 5. a connecting rod; 6. a frequency measuring device; 7. a monitoring cabin; 8. a water flow velometer; 9. a wind detector; 10. a wind vane; 11. a buoyancy tank; 12. mounting a plate; 13. a bolt; 14. a telescopic rod; 15. floating blocks; 16. a position sensor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: compound rivers monitoring ship of glass steel, including hull 1 and monitoring cabin 7, monitoring cabin 7 fixed mounting is at the upper surface of hull 1, monitoring cabin 7's inside is equipped with frequency measuring ware 6 respectively, rivers velometer 8 and wind detector 9, one side fixed mounting of monitoring cabin 7 has measuring motor 4, the bottom of hull 1 one side is equipped with commentaries on classics leaf 2, the both sides fixed mounting of hull 1 has buoyancy tank 11, place hull 1 on the surface of water, buoyancy tank 11 through 1 both sides fixed mounting of hull floats hull 1 on the surface of water, rivers drive commentaries on classics leaf 2 and rotate, 2 pivoted frequencies of commentaries on classics leaf transmit among the rivers velometer 8 after measuring out through frequency measuring ware 6 and carry out the analysis, promote hull 1 and move along with the rivers direction when commentaries on classics leaf 2 pivoted.

In this embodiment, buoyancy tank 11's bottom is equipped with kicking block 15, the upper end fixedly connected with telescopic link 14 of kicking block 15, the one end fixed mounting of telescopic link 14 is on buoyancy tank 11's top, the upper end fixed mounting of kicking block 15 has position sensor 16, when the draft of hull 1 deepens, kicking block 15 in buoyancy tank 11 highly rises, it stretches out and draws back to drive telescopic link 14 of fixed mounting in kicking block 15 upper end to take place, kicking block 15 upper end fixed mounting has position sensor 16, height variation is monitored to position sensor 16, carry out the analysis in arriving rivers velometer 8 with data transmission.

In this embodiment, the telescopic link 14 is equipped with two, and the symmetric distribution is in the both sides of kicking block 15 upper end, and the kicking block 15 height in buoyancy tank 11 rises, drives telescopic link 14 of fixed mounting in kicking block 15 upper end and takes place to stretch out and draw back, and kicking block 15 upper end fixed mounting has position sensor 16, and position sensor 16 monitors the change of kicking block 15 height.

In this embodiment, mounting plates 12 are welded to two sides of the hull 1, slotted holes are formed in both one side of the buoyancy tank 11 and the mounting plate 12, bolts 13 are arranged in the slotted holes, the buoyancy tank 11 is fixedly mounted on the mounting plate 12 through the bolts 13, the bolts 13 penetrate through the slotted holes formed in the buoyancy tank 11 and the mounting plate 12, and the buoyancy tank 11 is fixedly mounted on two sides of the hull 1 through the bolts 13.

In this embodiment, a wind vane 10 is fixedly installed at the upper end of the ship body 1, the wind vane 10 is matched with a wind detector 9 inside the monitoring cabin 7, in the moving process of the ship body 1, wind blows a fan blade at the upper end of the wind vane 10 to rotate, the rotating speed of the fan blade is measured by the wind detector 9 according to the wind force received by the ship body 1 when moving along water flow, and data of the wind force analyzed by the wind detector 9 is transmitted to the water flow velometer 8.

In this embodiment, 2 fixed mounting of commentaries on classics leaf is in the one end of axis of rotation 3, 4 fixed connection of motor are measured to the other end of axis of rotation 3, measure motor 4 and 6 fixed connection of frequency measurement ware through connecting rod 5, rivers drive the rotation of commentaries on classics leaf 2, the 3 rotations of axis of rotation of connecting 2 one ends of commentaries on classics leaf are driven, 3 rotations of axis of rotation make measure motor 4 start, and then feed back rotational frequency to frequency measurement ware 6 through measuring motor 4, frequency measurement ware 6 is used for testing the frequency of measuring motor 4, thereby 2 pivoted speeds of commentaries on classics leaf are calculated out, and then calculate the velocity of water flow.

The utility model discloses a theory of operation and use flow: this monitoring ship is when using, in the slotted hole that sets up on bolt 13 passed buoyancy case 11 and the mounting panel 12, through bolt 13 with buoyancy case 11 fixed mounting in the both sides of hull 1, place hull 1 on the surface of water, rivers drive the rotation of commentaries on classics leaf 2, the rotation axis 3 that drives connection commentaries on classics leaf 2 one end rotates, rotation axis 3 rotates and makes measuring motor 4 start, and then feed back the rotational frequency to frequency measurement ware 6 through measuring motor 4 on, frequency measurement ware 6 is used for testing measuring motor 4's frequency, thereby the speed of commentaries on classics leaf 2 pivoted is calculated out, and then calculate the velocity of water. The floating block 15 in the buoyancy tank 11 can change along with the change of the water level condition, when the draft of the ship body 1 becomes deep, the floating block 15 in the buoyancy tank 11 rises highly, the telescopic rod 14 fixedly installed at the upper end of the floating block 15 is driven to stretch, the position sensor 16 is fixedly installed at the upper end of the floating block 15, the position sensor 16 monitors the height change of the floating block 15, and data is transmitted to the water flow velometer 8 for analysis. Rivers drive 2 commentaries on classics leaf 2 pivoted of commentaries on classics leaf and promote hull 1 and take place to remove along rivers simultaneously, at hull 1 removal in-process, the flabellum rotation of wind indicator 10 upper end is blown to wind-force, the wind-force size that the flabellum pivoted speed received when moving along rivers through wind detector 9 measurement hull 1, with the data transmission of the wind-force size of analysis in wind detector 9 to rivers velometer 8, through the rotational frequency of the commentaries on classics leaf 2 received in rivers velometer 8, the altitude variation of floating block 15 and the wind-force size that wind indicator 10 received, and then calculate the regional velocity of water that department's hull 1 was used.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (6)

1. Compound rivers monitoring ship of glass steel, including hull (1) and monitoring cabin (7), its characterized in that, monitoring cabin (7) fixed mounting is at the upper surface of hull (1), the inside of monitoring cabin (7) is equipped with frequency measurement ware (6), rivers velometer (8) and wind detector (9) respectively, one side fixed mounting of monitoring cabin (7) has measurement motor (4), the bottom of hull (1) one side is equipped with commentaries on classics leaf (2), the both sides fixed mounting of hull (1) has buoyancy tank (11).

2. The glass reinforced plastic composite water flow monitoring ship according to claim 1, characterized in that a floating block (15) is arranged at the bottom end of the buoyancy tank (11), a telescopic rod (14) is fixedly connected to the upper end of the floating block (15), one end of the telescopic rod (14) is fixedly connected to the top end of the buoyancy tank (11), and a position sensor (16) is fixedly mounted at the upper end of the floating block (15).

3. The glass fiber reinforced plastic composite water flow monitoring ship as claimed in claim 2, wherein the number of the telescopic rods (14) is two, and the telescopic rods are symmetrically distributed on two sides of the upper end of the floating block (15).

4. The glass fiber reinforced plastic composite water flow monitoring ship according to claim 1, wherein mounting plates (12) are welded on two sides of the ship body (1), slotted holes are formed in one side of the buoyancy tank (11) and the mounting plates (12), bolts (13) are arranged in the slotted holes, and the buoyancy tank (11) is fixedly mounted on the mounting plates (12) through the bolts (13).

5. The glass fiber reinforced plastic composite water flow monitoring ship according to claim 1, characterized in that a wind vane (10) is fixedly installed at the upper end of the ship body (1), and the wind vane (10) is matched with a wind detector (9) inside the monitoring cabin (7).

6. The glass reinforced plastic composite water flow monitoring ship according to claim 1, wherein the rotating blade (2) is fixedly installed at one end of a rotating shaft (3), the other end of the rotating shaft (3) is fixedly connected with a measuring motor (4), and the measuring motor (4) is fixedly connected with a frequency measuring device (6) through a connecting rod (5).

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