CN212506180U - Formula of relying on oneself river course clearance floater's intercepting device - Google Patents

Abstract

The utility model provides an intercepting device of formula of relying on oneself river course clearance floater, relates to the cleaning equipment field, concretely relates to intercepting device of formula of relying on oneself river course clearance floater, includes: a collection belt for collecting the floating in the river; the conveying belt is used for conveying the floating objects collected by the collecting belt to other places; the water wheel is used for transmitting power for the collecting belt and the transmission belt; the transmission belt sets up in the terminal below of collection belt, form the contained angle between collection belt and the transmission belt, the utility model discloses an utilize the mobility of rivers for collecting belt and transmission belt provide power, saved the consumption of resource, collect belt and transmission belt moreover and transport the floater in the river course to the bank limit at the in-process of work, need not the workman and get into clearance in the river course, the step of the clearance of greatly convenient.

Description

Formula of relying on oneself river course clearance floater's intercepting device

Technical Field

The utility model relates to a cleaning equipment field, concretely relates to interception device of formula of relying on oneself river course clearance floater.

Background

Hydraulic engineering is an engineering built for controlling and allocating surface water and underground water in nature to achieve the purposes of removing harmful substances and benefiting. Also known as water engineering. 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. Hydraulic engineering needs to build various types of hydraulic buildings such as dams, dikes, spillways, water gates, water inlets, channels, transition troughs, rafts, fishways and the like so as to achieve the aims.

At present, the river channel is provided with garbage everywhere, the accumulation of a large amount of garbage causes environmental pollution and influences hydroelectric power generation, and the garbage is difficult to clean.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides another kind of thinking of clearance floater.

The technical scheme adopted by the utility model is as follows: the utility model provides a formula of relying on oneself intercepting device of river course clearance floater, includes:

the collecting belt is used for collecting floating objects in the river;

the conveying belt is used for conveying the floating objects collected by the collecting belt to other places;

the water wheel is used for transmitting power for the collecting belt and the transmission belt;

the conveying belt is arranged below the tail end of the collecting belt, and an included angle is formed between the collecting belt and the conveying belt.

As a further improvement, the utility model also includes a transmission mechanism, transmission mechanism includes first axis of rotation, for the second axis of rotation of collecting belt transmission power and set up on water wheels and can be along with water wheels pivoted third axis of rotation, chain drive between third axis of rotation and second axis of rotation, second axis of rotation and the first axis of rotation, still be provided with the gear train that is used for changing the direction of transfer of force between the axis of rotation of first axis of rotation and transmission belt, first axis of rotation passes through the motion of gear train drive transmission belt.

As a further improvement, the end of collecting the belt still is provided with the brush of roller shape, the belt setting is collected in the brush laminating, the brush is provided with the gear, gear and second transmission shaft meshing transmission.

As a further improvement, the utility model also comprises a collecting hopper which is arranged between the end of the collecting belt and the transmission belt.

As a further improvement, the top of collecting the belt still is provided with the first supporting legs that is used for the adjustment to collect the belt height, first supporting legs sets up the both sides at collecting the belt, transmission belt is provided with the second supporting legs of adjustment transmission belt height, the second supporting legs sets up the both sides at transmission belt's direction of motion.

As a further improvement of the utility model, the collection belt and/or the transmission belt are provided with the hole of permeating water that is used for the waterlogging caused by excessive rainfall.

The utility model has the advantages that: the utility model discloses an utilize the mobility of rivers for collecting belt and transmission belt provide power, saved the consumption of resource, collect the floater transportation to the bank limit of belt and transmission belt in the in-process of work in the river course moreover, need not the step of clearance, the convenient clearance greatly in the workman gets into the river course.

Drawings

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

Fig. 1 is a first perspective view of the present invention;

fig. 2 is a second perspective view of the present invention.

Detailed Description

The self-operated intercepting device for cleaning floating materials in a river channel, as shown in fig. 1-2, comprises a collecting belt 1, a transmission belt 2 and a water wheel 3, wherein the collecting belt 1 is used for collecting floating materials in the river channel, the collecting belt 1 is arranged in the river channel in a counter-current manner, and the rotation direction of the collecting belt 1 is the same as the flowing direction of the river channel. The tail end of the collecting belt 1 is provided with a transmission belt 2 for accommodating floating objects transported by the collecting belt 1. The water wheel 3 is a device for generating power by using water flow, and is also called a water wheel. The water wheel 3 provides power for the collecting belt 1 and the transmission belt 2, so that the self-operated driving is realized by utilizing the impulsive force of water flow, and the conventional electric power, manpower and other modes are not needed for driving. An included angle is formed between the collecting belt 1 and the transmission belt 2, so that the floating objects can be conveniently transported to the bank.

Particularly, the power is transmitted between the collection belt 1 and the transmission belt 2 and the water wheel 3 through the transmission mechanism, wherein the transmission mechanism comprises a first rotating shaft 4, a second rotating shaft 11 for transmitting the power through the collection belt 1 and a third rotating shaft 31 which is arranged on the water wheel 3 and can rotate along with the water wheel 3, chain transmission is adopted between the third rotating shaft 31 and the second rotating shaft 11 and between the second rotating shaft 11 and the first rotating shaft 4, a gear set for changing the force transmission direction is further arranged between the first rotating shaft 4 and the rotating shaft of the transmission belt 2, and the first rotating shaft 4 drives the transmission belt 2 to move through the gear set.

In the present embodiment, it is preferable that the collection belt 1 is perpendicular to the projection of the transfer belt 2 on the bottom surface. The change of the force transmission direction by means of a gear train is a relatively common means, and in this embodiment, the force transmission direction is changed by engaging two bevel gears perpendicular to each other, wherein one bevel gear is connected to the first rotating shaft 4 and is driven by the first rotating shaft 4 to rotate, and the other bevel gear is connected to the rotating shaft of the transmission belt 2 and drives the rotating shaft of the transmission belt 2 to rotate.

The tail end of the collecting belt 1 is further provided with a roller-shaped brush 5, the brush 5 is attached to the collecting belt 1, the brush 5 and the collecting belt 1 rotate relatively, impurities on the surface of the collecting belt 1 are swept away, and the brush 5 is in meshing transmission with the second transmission shaft through gears arranged on two sides. In this embodiment, the third rotating shaft 31 is driven by a chain to the second rotating shaft 11, the second rotating shaft 11 and the brush 5 are driven by meshing, and the connection mode can be further changed to that the third rotating shaft is driven by a chain to the brush 5, and the brush 5 and the second rotating shaft 11 are driven by meshing, and the two driving modes are substantially the same and belong to common alternatives in the art.

In order to prevent floating objects from flying when the collecting belt 1 transfers the floating objects to the conveying belt, a collecting hopper 6 is arranged below the tail end of the collecting belt 1, the collecting hopper 6 is of a structure with a large upper part and a small lower part, and the tail end of the collecting hopper 6 is arranged at the conveying belt. The starting end of the collecting belt 1 is also provided with a first supporting leg 71 for adjusting the height of the collecting belt 1, the first supporting leg 71 is arranged on two sides of the collecting belt 1, the conveying belt 2 is provided with a second supporting leg 72 for adjusting the height of the conveying belt 2, and the second supporting leg 72 is arranged on two sides of the moving direction of the conveying belt 2. The first support leg 71 and the second support leg 72 serve to maintain the stability of the device.

Preferably, the collection belt 1 and/or the transmission belt 2 are/is provided with water permeable holes for draining, so that the condition that the picked-up floating objects have excessive water volume and are inconvenient for subsequent treatment is avoided. +

The above description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Claims (6)

1. The utility model provides an intercepting device of formula of relying on oneself river course clearance floater which characterized in that: the method comprises the following steps:

a collection belt (1) for collecting floating materials in the river;

the conveying belt (2) is used for conveying the floating objects collected by the collecting belt (1) to other places;

the water wheel (3) is used for transmitting power to the collecting belt (1) and the transmission belt (2); the conveying belt (2) is arranged below the tail end of the collecting belt (1), and an included angle is formed between the collecting belt (1) and the conveying belt (2).

2. The self-operated intercepting device for river course cleaning floating objects according to claim 1, wherein: still include drive mechanism, drive mechanism includes first axis of rotation (4), for second axis of rotation (11) and setting on water wheels (3) of collecting belt (1) transmission power and can be along with water wheels (3) pivoted third axis of rotation (31), chain drive between third axis of rotation (31) and second axis of rotation (11), second axis of rotation (11) and first axis of rotation (4), still be provided with the gear train that is used for changing the direction of transmission of force between the axis of rotation of first axis of rotation (4) and transmission belt (2), first axis of rotation (4) are through gear train drive transmission belt (2) motion.

3. The self-operated intercepting device for river course cleaning floating objects according to claim 2, wherein: the tail end of the collecting belt (1) is further provided with a roller-shaped brush (5), the brush (5) is attached to the collecting belt (1), the brush (5) is provided with a gear, and the gear is in meshing transmission with the second transmission shaft.

4. The self-operated intercepting device for river course cleaning floating objects according to claim 1, wherein: the device is characterized by further comprising a collecting hopper (6), wherein the collecting hopper (6) is arranged between the tail end of the collecting belt (1) and the conveying belt (2).

5. The self-operated intercepting device for river course cleaning floating objects according to claim 1, wherein: the starting end of collecting belt (1) still is provided with first supporting legs (71) that are used for the adjustment to collect belt (1) height, first supporting legs (71) set up in the both sides of collecting belt (1), transmission belt (2) are provided with second supporting legs (72) of adjustment transmission belt (2) height, second supporting legs (72) set up the both sides at the direction of motion of transmission belt (2).

6. The self-operated intercepting device for river course cleaning floating objects according to claim 1, wherein: the collection belt (1) and/or the transmission belt (2) are provided with water permeable holes for draining.

Images