CN216770598U - Cable channel for hydrological monitoring - Google Patents

Abstract

The utility model relates to a cableway for hydrologic monitoring, and belongs to the technical field of hydrologic monitoring equipment. The cableway for hydrological monitoring comprises two towers which are oppositely arranged, wherein a main cable and a circulating cable are arranged between the two towers, and the circulating cable is wound on the two towers; still include the driving, be equipped with the second battery in the driving, hoisting apparatus main part and second motor, the hoisting apparatus main part is used for hanging the fish lead, the driving is installed on the main rope, the one end of patrolling the cable is connected with the first end of driving after locating on one of them pylon, the other end of patrolling the cable is connected with the second end of driving after locating on another pylon, still including setting up the first motor on the pylon, first motor is connected with the transmission of patrolling the cable, still be provided with first battery on the pylon, first battery is connected with first motor electricity. The device saves an operation room for installing the winch, the control console and the power distribution system, does not need to arrange the hoisting cable independently, is simple to arrange, and saves the construction cost.

Description

Cable channel for hydrological monitoring

Technical Field

The utility model relates to a cableway for hydrologic monitoring, and belongs to the technical field of hydrologic monitoring equipment.

Background

Among hydrology tests, river flow tests are one of the most important works for hydrology flood control and water resource management monitoring. The hydrologic monitoring cableway is a facility for conveying hydrologic test sensing instruments such as a current meter and a sand measuring instrument to a specified point of a river through a fish lead hung on the hydrologic monitoring cableway for corresponding test. The traditional hydrological monitoring cableway comprises a steel cable, a tower and a driving device, wherein the steel cable comprises a main cable, a circulating cable, a hoisting cable and the like; the two towers are respectively arranged on two banks of the river channel and are used for supporting a working cable, a fish lead and the like; the driving device comprises a hydrological special winch and a control console which are arranged in the operation room.

The traditional hydrologic monitoring cable channel is required to construct a special operation room on the ground, and a winch, a control console, a power distribution system and the like are arranged in the operation room, so that the hydrologic monitoring cable channel system is complicated to arrange and occupies a large area.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: the cable channel for hydrological monitoring is simple to arrange and small in occupied area.

The technical scheme adopted by the utility model for solving the technical problems is as follows: the cableway for hydrological monitoring comprises two towers which are oppositely arranged, at least two main cables which are horizontally arranged are arranged between the two towers at intervals, and a patrol cable is also arranged between the two towers and wound on the two towers;

the fishing device comprises a hoisting device body and is characterized by further comprising a travelling crane, wherein a second storage battery is arranged in the travelling crane, the hoisting device body and a second motor connected with the hoisting device body, the second storage battery is electrically connected with the second motor, the hoisting device body is used for suspending the lead fish, the second motor is used for driving the hoisting device body so as to enable the lead fish to move in the vertical direction, the travelling crane is installed on a main cable, one end of a strolling cable is connected with the first end of the travelling crane after being wound on one of the towers, the other end of the strolling cable is connected with the second end of the travelling crane after being wound on the other tower, the fishing device further comprises a first motor arranged on the towers, the first motor is in transmission connection with the strolling cable, the first motor is used for enabling the travelling crane to do linear motion along the main cable, the towers are further provided with the first storage battery, and the first storage battery is electrically connected with the first motor.

Furthermore, the two towers are respectively provided with a first support, each first support is rotatably connected with a second pulley, the travelling cable is wound on the two second pulleys, the first motor is arranged on any one tower, the tower provided with the first motor is a first tower, and the first motor is in transmission connection with the second pulleys arranged on the first tower.

Further, still be provided with first solar panel on the first pylon, first solar panel is connected with first battery electricity.

Further, a generator is further arranged on the first tower and electrically connected with the first storage battery.

Furthermore, one side of the first tower frame, which faces the travelling crane, is also provided with a travel switch electrically connected with the first motor, and the setting position of the travel switch is matched with the position of the travelling crane.

Furthermore, the travelling crane comprises a travelling crane main body, the second storage battery, the lifting device main body and the second motor are arranged in the travelling crane main body, travelling wheels are arranged on the travelling crane main body, annular grooves are further formed in the outer peripheral surfaces of the travelling wheels, the annular grooves are formed along the circumferential direction of the travelling wheels, and the main cables are arranged in the annular grooves.

Further, still including setting up the second solar panel on the driving, second solar panel is connected with the second battery electricity.

Furthermore, a charging contact is further arranged on one side, facing the first tower, of the travelling crane, the charging contact is electrically connected with the second storage battery, a charging pile matched with the charging contact is further arranged on one side, facing the travelling crane, of the first tower, the charging pile is electrically connected with the generator, and the setting position of the charging contact is matched with the setting position of the charging pile.

Furthermore, still be provided with the second support on the driving, the detachable is connected with the electric wave current meter on the second support.

Furthermore, a suspension rope is wound on the hoisting device main body and used for hoisting the fish lead, a direction-changing wheel support is further installed in the traveling main body, a direction-changing wheel is further rotatably connected to the direction-changing wheel support, the suspension rope extends out of the traveling main body through the direction-changing wheel, a weightlessness induction switch is further arranged on the traveling main body, the weightlessness induction switch is arranged below the direction-changing wheel support and is in contact with the bottom of the direction-changing wheel support, and the weightlessness induction switch is electrically connected with a second motor.

The utility model has the beneficial effects that:

this application sets up first battery at the pylon, sets up the second battery on the driving, and installs first motor drive driving along the length direction motion of main rope, utilizes driving self hoist and mount fish lead, makes fish lead up-and-down motion, and consequently this device has not only saved the operation room that is used for installing winch, control cabinet and distribution system, and need not to lay the jack-up rope alone, lays simply, and has saved construction cost.

Drawings

FIG. 1 is a first isometric view of the present invention;

FIG. 2 is an enlarged view of the present invention at A;

FIG. 3 is a cross-sectional view of the traveler of the present invention;

FIG. 4 is a second axial side view of the present invention;

FIG. 5 is an enlarged view of the present invention at B.

Labeled as: 1 is a tower, 12 is a fish platform, 14 is a main rope, 16 is a travelling rope, 22 is a generator, 3 is a first motor, 4 is a first storage battery, 52 is a first solar panel, 54 is a second solar panel, 56 is a charging pile, 6 is a travelling crane, 61 is a second storage battery, 62 is a travelling crane main body, 63 is a second motor, 64 is a charging contact, 65 is a travelling wheel, 66 is a hoisting device main body, 68 is a direction-changing wheel, 82 is a second pulley, 84 is a first bracket, 92 is a fish, 94 is a second bracket, 96 is a radio wave current meter, and 98 is a camera.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

As shown in fig. 1 to 5, the cableway for hydrologic monitoring of the present invention comprises two towers 1 arranged oppositely, at least two main cables 14 arranged horizontally are arranged between the two towers 1 at intervals, a travelling cable 16 is further arranged between the two towers 1, and the travelling cable 16 is wound on the two towers 1;

the fishing device also comprises a travelling crane 6, wherein a second storage battery 61, a lifting device main body 66 and a second motor 63 connected with the lifting device main body 66 are arranged in the travelling crane 6, the second storage battery 61 is electrically connected with the second motor 63, the lifting device main body 66 is used for hanging the fish lead 92, the second motor 63 is used for driving the lifting device main body 66, the fishing tackle further comprises a first motor 3 arranged on the towers 1, the first motor 3 is in transmission connection with the patrol cable 16, the first motor 3 is used for enabling the travelling crane 6 to do linear motion along the main cable 14, the towers 1 are further provided with a first storage battery 4, and the first storage battery 4 is electrically connected with the first motor 3.

This application sets up first battery 4 at pylon 1, sets up second battery 61 on driving 6, and installs first motor 3 drive driving 6 and move along the length direction of main rope 14, utilizes driving 6 self hoist and mount fish lead 92, makes fish lead 92 up-and-down motion, has consequently not only saved the operation room that is used for installing winch, control cabinet and distribution system by this device, and need not to lay the jack-up rope alone, lays simply, and has saved construction cost.

Preferably, the two towers 1 are respectively provided with a first bracket 84, each first bracket 84 is rotatably connected with a second pulley 82, the strolling rope 16 is wound on the two second pulleys 82, the first motor 3 is arranged on any one tower 1, the tower 1 provided with the first motor 3 is a first tower, and the first motor 3 is in transmission connection with the second pulleys 82 arranged on the first tower.

Specifically, a first mounting platform is arranged on the first tower, and the first motor 3 and the first storage battery 4 are arranged on the first mounting platform. The two towers 1 are respectively provided with a first bracket 84, the first brackets 84 are arranged on a first mounting platform, the first brackets 84 on the two towers 1 are respectively connected with a rotating shaft in a rotating way, the two rotating shafts are respectively and fixedly connected with a second pulley 82, the strolling cable 16 is wound on the second pulleys 82 on the two towers 1, the rotating shaft on the first tower is also fixedly connected with a third pulley, the third pulley is sleeved with a steel cable, and the steel cable is also sleeved on the output end of the first motor 3; in this way, the rotation of the first motor 3 can drive the travelling cable 16 to move back and forth, and the travelling cable 16 pulls the travelling crane 6 to move back and forth on the main cable 14.

Preferably, a first solar panel 52 is further disposed on the first tower, and the first solar panel 52 is electrically connected to the first battery 4.

Specifically, the first solar panel 52 is disposed on the top of the tower 1, and the first solar panel 52 is disposed to charge the first battery 4 and maintain the electric energy in the first battery 4.

Preferably, a generator 22 is further provided on the first tower, and the generator 22 is electrically connected to the first battery 4.

Specifically, a second mounting platform is further arranged on the first tower, the second mounting platform is arranged below the first mounting platform, the generator 22 is placed on the second mounting platform, the generator 22 can be a gasoline generator, and when the electric energy in the first storage battery 4 is insufficient, the generator 22 can be started to charge the first storage battery 4.

The tower frame 1 is further provided with a fish lead 92 platform 12, the fish lead 92 platform 12 extends towards the direction close to the travelling crane 6, and the top surface of the fish lead 92 platform 12 is coplanar with the top surface of the second mounting platform.

Preferably, a travel switch electrically connected with the first motor 3 is further arranged on one side of the first tower frame facing the traveling crane 6, and the setting position of the travel switch is matched with the position of the traveling crane 6.

Specifically, travel switch accessible support erects on first mounting platform, and is unusual when the drive of first motor 3, probably makes driving 6 operation transfinites, and driving 6 triggers travel switch this moment, and travel switch is the back of starting for first motor 3 closes, so can avoid driving 6 transfinites.

Preferably, the traveling crane 6 includes a traveling crane main body 62, the second battery 61, the lifting device main body 66 and the second motor 63 are disposed in the traveling crane main body 62, a traveling wheel 65 is disposed on the traveling crane main body 62, an annular groove is further disposed on an outer peripheral surface of the traveling wheel 65, the annular groove is disposed along a circumferential direction of the traveling wheel 65, and the main cable 14 is disposed in the annular groove.

Specifically, the hoisting device body 66 is a winch, and the hoisting device body 66 may also be an electric hoist. The traveling wheels 65 are rotatably connected with the traveling crane main body 62, and the traveling wheels 65 can also be fixedly connected with the traveling crane main body 62, but the traveling wheels 95 are fixedly connected with the traveling crane main body 62, so that when the traveling crane 6 travels, the friction between the traveling crane 6 and the main cable 14 is large, and the rotation connection is adopted in the preferable scheme.

Preferably, the solar energy collecting device further comprises a second solar panel 54 arranged on the travelling crane 6, and the second solar panel 54 is electrically connected with the second storage battery 61.

Specifically, the second solar panel 54 is disposed on the top of the traveling crane 6, and the second solar panel 54 is disposed to charge the second battery 61 and maintain the power of the second battery 61.

Preferably, a charging contact 64 is further arranged on one side of the travelling crane 6 facing the first tower, the charging contact 64 is electrically connected with the second storage battery 61, a charging pile 56 matched with the charging contact 64 is further arranged on one side of the first tower facing the travelling crane 6, the charging pile 56 is electrically connected with the generator 22, and the setting position of the charging contact 64 is matched with the setting position of the charging pile 56.

Specifically, the charging pile 56 is disposed on the first mounting platform, when the electric quantity of the second storage battery 61 is insufficient, the traveling crane 6 travels towards the first tower, and when the charging contact 64 contacts the charging pile 56, the generator 22 charges the second storage battery 61.

Preferably, the traveling crane 6 is further provided with a second bracket 94, and the second bracket 94 is detachably connected with a radio wave current meter 96.

Specifically, among the traditional hydrology monitoring cableway system, be provided with electric wave current meter 96 cableway specially, so will increase the construction volume of laying, this scheme installs electric wave current meter 96 on driving 6, can save electric wave current meter 96 cableway.

Preferably, a suspension rope is wound on the hoisting device main body 66 and used for hoisting the lead fish 92, a bend wheel support is further mounted in the traveling crane main body 62, a bend wheel 68 is further rotatably connected to the bend wheel support, the suspension rope extends out of the traveling crane main body 62 through the bend wheel 68, a weightlessness induction switch is further arranged on the traveling crane main body 62, the weightlessness induction switch is arranged below the bend wheel support and is in contact with the bottom of the bend wheel support, and the weightlessness induction switch is electrically connected with the second motor 63.

Specifically, a fish lead 92 is hung at the bottom of the suspension rope of the lifting device main body 66, and the weightlessness sensing switch is located below the direction-changing wheel bracket, namely: the suspension rope always applies acting force to the weightlessness induction switch, the first state is before the lead fish 92 contacts the river bottom, the second state is when the lead fish 92 contacts the river bottom, and the acting force applied to the suspension rope by the lead fish in the first state and the second state is different, so that the acting force applied to the weightlessness induction switch by the suspension rope is different. After the weightlessness inductive switch detects that the fish lead 92 touches the bottom, the weightlessness inductive switch is turned off, and the second motor 63 can only rotate in one direction, namely: only the wire rope of the hoisting device main body 66 can be wound up; the fish lead 92 does not touch the bottom, the weightlessness sensing switch is turned on, and the second motor 63 can rotate forwards and backwards.

The traveling crane is also provided with a camera 98, and the camera 98 can be used for observing the condition in the river and observing the condition of the fish lead 92.

While the present invention has been described in detail with reference to the preferred embodiments, it should be understood that the above description should not be taken as limiting the utility model. Various modifications and alterations to this invention will become apparent to those skilled in the art upon reading the foregoing description. Accordingly, the scope of the utility model should be limited only by the attached claims. In addition, all technical schemes of the utility model can be combined. The word "comprising" does not exclude the presence of other devices or steps than those listed in a claim or the specification; the terms "first," "second," and the like are used merely to denote names, and not any particular order. In this context, "parallel," "perpendicular," and the like are not strictly mathematical and/or geometric limitations, but also encompass tolerances as would be understood by one skilled in the art and permitted by fabrication or use.

Claims (10)

1. The cableway for hydrological monitoring comprises two oppositely arranged towers (1), at least two horizontally arranged main cables (14) are arranged between the two towers (1) at intervals, a patrol cable (16) is further arranged between the two towers (1), and the patrol cable (16) is wound on the two towers (1);

the method is characterized in that: still include driving (6), be equipped with second battery (61), hoisting device main part (66) in driving (6) and with second motor (63) that hoisting device main part (66) are connected, second battery (61) with second motor (63) electricity is connected, hoisting device main part (66) are used for hanging fish lead (92), second motor (63) are used for driving hoisting device main part (66) so that fish lead (92) move in the vertical direction, driving (6) are installed on main cable (14), the one end of patrolling cable (16) is connected with the first end of driving (6) after around locating on one of them pylon (1), the other end of patrolling cable (16) is connected with the second end of driving (6) after locating on another pylon (1), still include first motor (3) that set up on pylon (1), the first motor (3) is in transmission connection with the travelling cable (16), the first motor (3) is used for enabling the travelling crane (6) to move linearly along the main cable (14), a first storage battery (4) is further arranged on the tower (1), and the first storage battery (4) is electrically connected with the first motor (3).

2. Cableway for hydrographic monitoring according to claim 1, characterized in that: all be provided with first support (84) on two pylon (1), every all rotate on first support (84) and be connected with second pulley (82), patrol cable (16) around establishing two on second pulley (82), first motor (3) set up on arbitrary one pylon (1), and pylon (1) that is provided with first motor (3) is first pylon, first motor (3) with set up second pulley (82) transmission on the first pylon is connected.

3. Cableway for hydrographic monitoring according to claim 2, characterized in that: the first tower is further provided with a first solar panel (52), and the first solar panel (52) is electrically connected with the first storage battery (4).

4. Cableway for hydrographic monitoring according to claim 2, characterized in that: the first tower is also provided with a generator (22), and the generator (22) is electrically connected with the first storage battery (4).

5. Cableway for hydrographic monitoring according to claim 2, characterized in that: one side of the first tower, which faces the travelling crane (6), is also provided with a travel switch electrically connected with the first motor (3), and the setting position of the travel switch is matched with the position of the travelling crane (6).

6. Cableway for hydrographic monitoring according to claim 4, characterized in that: the driving vehicle (6) is including driving vehicle main part (62), second battery (61) hoisting device main part (66) reach second motor (63) are located in driving vehicle main part (62), be equipped with walking wheel (65) on driving vehicle main part (62), still be provided with the annular groove on the outer peripheral face of walking wheel (65), the annular groove is followed the circumference setting of walking wheel (65), main rope (14) are located in the annular groove.

7. Cableway for hydrographic monitoring according to claim 6, characterized in that: the solar energy collecting device is characterized by further comprising a second solar panel (54) arranged on the travelling crane (6), wherein the second solar panel (54) is electrically connected with the second storage battery (61).

8. Cableway for hydrographic monitoring according to claim 6, characterized in that: driving a vehicle (6) orientation still be provided with charging contact (64) on one side of first tower, charging contact (64) with second battery (61) electricity is connected, first tower orientation driving a vehicle (6) one side still be provided with charging contact (64) looks adaptation fill electric pile (56), fill electric pile (56) with generator (22) electricity is connected, the position that sets up of charging contact (64) with fill the position phase-match of electric pile (56).

9. Cableway for hydrographic monitoring according to claim 6, characterized in that: the travelling crane (6) is also provided with a second support (94), and the second support (94) is detachably connected with an electric wave current meter (96).

10. Cableway for hydrographic monitoring according to claim 6, characterized in that: the lifting device is characterized in that a suspension rope is wound on the lifting device main body (66) and used for lifting a fish lead (92), a direction-changing wheel support is further mounted in the traveling crane main body (62), a direction-changing wheel (68) is further rotatably connected to the direction-changing wheel support, the suspension rope extends out of the traveling crane main body (62) through the direction-changing wheel (68), a weightlessness induction switch is further arranged on the traveling crane main body (62), the weightlessness induction switch is arranged below the direction-changing wheel support and is in contact with the bottom of the direction-changing wheel support, and the weightlessness induction switch is electrically connected with the second motor (63).

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