CN220467415U - Double-track traction type radar wave current measurement carrying cableway system - Google Patents

Abstract

The utility model discloses a double-track traction type radar wave flow measurement carrying cableway system which comprises a hydrological cableway, a flow measurement device, a bearing power system, a circulating power system and a cableway control box, wherein the hydrological cableway comprises a bearing rope which is horizontally arranged, a circulating rope which is vertically arranged, a steering pulley block, a left bank base and a right bank base, the flow measurement device is hoisted on the hydrological cableway, and a data acquisition and feedback device is arranged in the cableway control box. The utility model belongs to the technical field of hydrologic monitoring, and particularly relates to a double-track traction type radar wave current measurement carrying cableway system.

Description

Double-track traction type radar wave current measurement carrying cableway system

Technical Field

The utility model belongs to the technical field of hydrologic monitoring, and particularly relates to a double-track traction type radar wave current measurement carrying cableway system.

Background

The river flow test is an important component of hydrologic work, and the acquisition of various data plays an important role in flood control, drought resistance and disaster reduction, water resource management, long-term implementation of rivers (lakes), water ecological protection and sustainable development of society and economy.

The water-based flow test device has the characteristics of numerous water-based monitoring sites of middle and small rivers, wide distribution, particularly rapid converging speed of mountain stream rivers, steep rising and falling of flood water and the like, and the traditional manual flow test of the current meter, the navigation type ADCP current meter and the like has high intensity, low efficiency and high danger, and is difficult. In recent years, various automatic flow measurement systems are sequentially researched, wherein the contact method mainly comprises H-ADCP flow measurement, VADCP flow measurement, suspended ADCP automatic flow measurement, ultrasonic time difference method flow measurement and the like, the non-contact method mainly comprises radar wave automatic flow measurement, the automatic flow measurement systems all need manual comparison observation, the comparison test is required to cover high, medium and low water, and finally, the correlation coefficient between the automatic flow measurement and manual comparison measurement is established.

The non-contact radar wave flow rate meter is applied to on-line monitoring of medium and small river flow and on-line monitoring of conventional hydrological station flow in mountain river channels, has good adaptability, and the operation mode mainly comprises a fixed installation mode, a self-driven mode and the like, but has certain defects on the adaptability to the environment. The bridge fixing type requires the testing environment to have a bridge building, and is inconvenient to adjust in later period after fixing. The self-driven equipment of track has very big difficulty to overhaul, leads to the test to stagnate easily, often lacks to survey big flood.

Disclosure of Invention

In order to solve the problems, the utility model provides a double-track traction type radar wave current measurement carrying cableway system.

In order to realize the functions, the technical scheme adopted by the utility model is as follows: the double-track traction type radar wave current-measuring carrying cableway system comprises a hydrological cableway, a current measuring device, a bearing power system, a circulating power system and a cableway control box, wherein the hydrological cableway comprises a bearing rope which is horizontally arranged, a circulating rope which is vertically arranged, a steering pulley block, a left shore base and a right shore base, the current measuring device is hoisted on the hydrological cableway, and a data acquisition and feedback device is arranged in the cableway control box;

the flow measuring device comprises a radar crane, a radar probe and an angle indicator;

the radar crane comprises a fixed baffle, a pulley block, a support frame and rope fasteners, wherein the pulley block is arranged on the fixed baffle and is provided with four groups, the support frame is arranged below the fixed baffle, the rope fasteners are arranged at the bottom end of the support frame, the pulley block of the radar crane is connected onto a bearing rope, and the rope fasteners are in fastening connection with a circulating rope.

Preferably, the radar probe is mounted on the probe support, and the angle indicator is mounted on the support frame and connected with the radar probe.

Preferably, the bearing power system comprises a hand winch, a fixed pulley and a tension sensor, wherein the hand winch and the fixed pulley are arranged on a left bank base, the steering pulley block is arranged on a right bank base, one end of the bearing cable is connected with the fixed pulley, the other end of the bearing cable is connected with the hand winch, the bearing cable bypasses the steering pulley block, and the tension sensor is connected to the bearing cable.

Preferably, the circulating power system comprises a motor, a driving wheel set, a branching wheel and a coding counter, wherein the motor is arranged on a left bank base, the driving wheel set and the branching wheel are both arranged on the left bank base, and the circulating cable bypasses the steering pulley block and is connected with the branching wheel.

As a preferred embodiment of the utility model, the code counter is in pressure contact with the endless cable via a counter wheel.

As a preferred technical scheme of the utility model, the cableway control box is connected with the motor and the driving pulley block in a signal control manner.

The utility model adopts the structure to obtain the beneficial effects as follows: according to the double-track traction type radar wave flow measurement carrying cableway system, the circulating cable is driven to rotate, so that a radar crane hoisted on the bearing cable is driven to travel on the hydrological cableway, the two groups of rope mechanisms ensure the stability of operation, and the positioning accuracy of a radar wave speed measurement probe is greatly improved by matching with the counting wheel; the radar wave flow measurement position is guaranteed to be flexible, meanwhile, the equipment cost is effectively controlled, and the energy consumption is reduced.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a dual-track traction type radar wave current measurement carrying cableway system according to the present utility model;

fig. 2 is a schematic diagram of a radar traveling crane of a double track traction type radar wave current measurement carrying cableway system according to the present utility model.

The device comprises a left shore base, a hand winch, a fixed pulley, a tension sensor, a 5, a bearing cable, a 6, a radar crane, a 7, a steering pulley block, a 10, a right shore base, a 11, a circulating cable, a 12, a motor, a 13, a branching wheel, a 16, a coding counter, a 18, a cableway control box, a 19, a pulley block, a 20, a fixed baffle, a 21, a support frame, a 22, an angle indicator, a 23, a radar probe, a 24, a rope fastener, a 25 and a driving pulley group.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The present utility model will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1-2, the double-track traction type radar wave current-measuring carrying cableway system provided by the utility model comprises a hydrological cableway, a current measuring device, a bearing power system, a circulating power system and a cableway control box 18, wherein the hydrological cableway comprises a horizontally arranged bearing cable 5, a circulating cable 11 which is arranged up and down, a steering pulley block 7, a left shore base 1 and a right shore base 10, the current measuring device is hoisted on the hydrological cableway, and a data acquisition and feedback device is arranged in the cableway control box 18; the flow measuring device comprises a radar travelling crane 6, a radar probe 23 and an angle indicator 22;

the radar driving 6 comprises a fixed baffle 20, a pulley block 19, a supporting frame 21 and a rope fastener 24, wherein the pulley block 19 is arranged on the fixed baffle 20 and is provided with four groups, the supporting frame 21 is arranged under the fixed baffle 20, the rope fastener 24 is arranged at the bottom end of the supporting frame 21, the pulley block 19 of the radar driving 6 is connected onto a bearing rope 5, the rope fastener 24 is fixedly connected with a circulating rope 11, the bearing rope 5 supports the fixed baffle 20 and ensures that the bearing rope is in a horizontal state, a radar probe 23 is arranged on a probe support, an angle indicator 22 is arranged on the supporting frame 21 and is connected with the radar probe 23, the angle indicator 22 can adjust the radar probe 23 to form a fixed oblique angle with the horizontal direction, and the measurement direction of the radar wave velocity measuring probe is ensured to be fixed.

The bearing power system comprises a hand winch 2, a fixed pulley 3 and a tension sensor 4, wherein the hand winch 2 and the fixed pulley 3 are arranged on a left bank base 1, a steering pulley block 7 is arranged on a right bank base 10, one end of a bearing rope 5 is connected with the fixed pulley 3, the other end of the bearing rope 5 is connected with the hand winch 2, the bearing rope 5 bypasses the steering pulley block 7, the tension sensor 4 is connected to the bearing rope 5, the tension sensor 4 measures the tension of the bearing rope 5, and the hand winch 2 accurately adjusts the tension of the bearing rope 5 to achieve the purpose of adjusting the sag of the bearing rope 5.

The circulating power system comprises a motor 12, a driving wheel group 25, a branching wheel 13 and a coding counter 16, wherein the motor 12 is arranged on the left bank base 1, the driving wheel group 25 and the branching wheel 13 are arranged on the left bank base 1, a circulating cable 11 bypasses a steering pulley block 7 and is connected with the branching wheel 13, the motor 12 is provided with a speed reducer, the alternating current motor 12 rotates positively and negatively to drive the driving wheel group 25 to rotate positively and negatively, the circulating cable 11 is driven to advance forwards and backwards, the radar travelling crane 6 is driven to move forwards and backwards, the coding counter 16 is in pressure contact with the circulating cable 11 through the counting wheel, and pulse data are collected to calculate the revolution of the driving wheel, so that the moving distance of the radar travelling crane 6 is calculated and displayed.

The cableway control box 18 is connected with the motor 12 and the driving pulley block 19 in a signal control way.

When the cableway control box 18 is specifically used, the operation of the motor 12 and the driving pulley block 19 is controlled through sending instructions, so that the operation of the circulating cable 11 is controlled, the motor 12 is provided with a speed reducer, the alternating current motor 12 rotates positively and negatively to drive the driving pulley group 25 to rotate positively and negatively, the circulating cable 11 is driven to move forwards and backwards to drive the radar travelling crane 6 to move forwards and backwards, when the circulating cable 11 stops operating, the circulating cable 11 holds the radar travelling crane 6 at a fixed position on the bearing cable 5, the code counter 16 is in pressure contact with the circulating cable 11 through the counting wheel, pulse data are collected to calculate the revolution of the driving wheel, the moving distance of the radar travelling crane 6 is calculated and displayed, the tension sensor 4 measures the tension of the bearing cable 5, the hand winch 2 accurately adjusts the tension of the bearing cable 5, so that the sag of the bearing cable 5 is adjusted, the angle indicator 22 adjusts the radar probe 23 to form a fixed oblique angle with the horizontal direction, and the measuring direction of the radar speed measuring probe is ensured to be fixed.

The utility model and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (6)

1. A dual track towed radar wave current measurement carrying cableway system, characterized by: the hydraulic cableway comprises a hydraulic cableway, a flow measuring device, a bearing power system, a circulating power system and a cableway control box (18), wherein the hydraulic cableway comprises a bearing rope (5) which is horizontally arranged, a circulating rope (11) which is vertically arranged, a steering pulley block (7), a left shore base (1) and a right shore base (10), the flow measuring device is hoisted on the hydraulic cableway, and a data acquisition and feedback device is arranged in the cableway control box (18);

the flow measuring device comprises a radar crane (6), a radar probe (23) and an angle indicator (22);

the radar crane (6) comprises a fixed baffle (20), a pulley block (19), a support frame (21) and rope fasteners (24), wherein the pulley block (19) is arranged on the fixed baffle (20) and is provided with four groups, the support frame (21) is arranged under the fixed baffle (20), the rope fasteners (24) are arranged at the bottom end of the support frame (21), the pulley block (19) of the radar crane (6) is connected onto a bearing rope (5), and the rope fasteners (24) are fixedly connected with a circulating rope (11).

2. A dual track towed radar wave current sensing carrying cableway system according to claim 1, wherein: the radar probe (23) is arranged on the probe bracket, and the angle indicator (22) is arranged on the supporting frame (21) and is connected with the radar probe (23).

3. A dual track towed radar wave current sensing carrying cableway system according to claim 2, wherein: the bearing power system comprises a hand winch (2), a fixed pulley (3) and a tension sensor (4), wherein the hand winch (2) and the fixed pulley (3) are arranged on a left bank base (1), a steering pulley block (7) is arranged on a right bank base (10), one end of a bearing cable (5) is connected with the fixed pulley (3), the other end of the bearing cable (5) is connected with the hand winch (2), the bearing cable (5) bypasses the steering pulley block (7), and the tension sensor (4) is connected to the bearing cable (5).

4. A dual track towed radar wave current sensing carrying cableway system according to claim 3, wherein: the circulating power system comprises a motor (12), a driving wheel set (25), a branching wheel (13) and a coding counter (16), wherein the motor (12) is arranged on a left bank base (1), the driving wheel set (25) and the branching wheel (13) are arranged on the left bank base (1), and a circulating rope (11) bypasses a steering pulley block (7) and is connected with the branching wheel (13).

5. A dual track towed radar wave current sensing carrying cableway system according to claim 4, wherein: the coding counter (16) is in pressure contact with the circulating cable (11) through a counting wheel.

6. A dual track towed radar wave current sensing carrying cableway system according to claim 5, wherein: the cableway control box (18) is in signal control connection with the motor (12) and the driving pulley block (19).