CN214597602U - Hydraulic engineering silt treatment facility - Google Patents

Abstract

The utility model discloses a hydraulic engineering silt treatment facility, which belongs to the technical field of silt treatment, and comprises a treatment frame, the upper end rigid coupling of the treatment frame is provided with a stirring box and a servo motor, the upper end of the stirring box is provided with a feed inlet, the lower end of the stirring box is provided with a valve, the output shaft rigid coupling of the servo motor is provided with a first bevel gear, the first bevel gear is meshed with a second bevel gear, the second bevel gear is fixedly connected to one side of a stirring mechanism, the other side of the stirring mechanism is fixedly connected with a first gear, the first gear is meshed with a second gear through a gear belt, and the lower surface rigid coupling inside the treatment frame is provided with a filtering mechanism; and then drive the stirring leaf above first (mixing) shaft and the second (mixing) shaft and rotate for the large granule material in silt carries out one step of smashing, makes the filter screen between two connecting blocks produce the vibration, and then the thin mud and the water in the silt aqueous solution fall to the collection liquid case, and the sand in the silt aqueous solution falls from the husky mouth that falls.

Description

Hydraulic engineering silt treatment facility

Technical Field

The utility model belongs to the technical field of silt is handled, concretely relates to hydraulic engineering silt treatment facility.

Background

In daily production activities, silt treatment in water conservancy projects is an important energy-saving and environment-friendly subject, and people also strive to explore reasonable utilization of water conservancy silt to achieve the aim of environmental friendliness.

At present, at the in-process of water conservancy silt department, current equipment is not good to the effect of the recovery of silt, and can not carry out prefiltering to silt, for this reason we propose a hydraulic engineering silt treatment facility.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a hydraulic engineering silt treatment facility to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a hydraulic engineering silt treatment facility, is including handling the frame, the upper end rigid coupling of handling the frame has agitator tank and servo motor, and the upper end of agitator tank has seted up the feed inlet, and the lower extreme of agitator tank installs the valve, servo motor's output shaft rigid coupling has first bevel gear, and first bevel gear and second bevel gear mesh mutually, and second bevel gear rigid coupling is in one side of rabbling mechanism, the opposite side rigid coupling of rabbling mechanism has first gear, and just first gear has the second gear through the gear area meshing, the lower surface rigid coupling of handling the inside frame has filtering mechanism, and has seted up the mouth that falls husky on handling the lateral wall of frame, and the upper surface rigid coupling of handling the inside frame has a collection liquid case, and one side rigid coupling of second gear has strike mechanism.

The scheme is as follows:

the servo motor is a common component in the prior art, and the adopted models and the like can be customized according to actual use requirements.

As a preferred embodiment, the stirring mechanism comprises a first stirring shaft, a third gear, a fourth gear, a second stirring shaft and stirring blades, a second bevel gear is fixedly connected to one end of the first stirring shaft, the first stirring shaft is rotatably connected to the inner side wall of the stirring box, the third gear is fixedly connected to the outer side wall of the first stirring shaft, the first gear is fixedly connected to the outer wall of the other end of the first stirring shaft, the third gear is meshed with the fourth gear, the fourth gear is fixedly connected to the outer end of the second stirring shaft, the second stirring shaft is rotatably connected to the side wall of the stirring box, and the first stirring shaft and the second stirring shaft are fixedly connected to the inner side wall of the stirring box.

As a preferred embodiment, the filtering mechanism comprises a telescopic sleeve, a sliding rod, a connecting block and a filtering screen, wherein four telescopic sleeves are fixedly connected to the lower end of the interior of the processing frame, the sliding rod is slidably connected in the four telescopic sleeves, the connecting block is fixedly connected to the lower ends of the two sliding rods, and the filtering screen is installed between the two connecting blocks.

In a preferred embodiment, the knocking mechanism comprises a rotating shaft and cams, the rotating shaft is fixedly connected to one side of the second gear, the rotating shaft penetrates through the processing frames and is rotatably connected between the processing frames, and the two cams are fixedly connected to the outer walls of the two ends of the rotating shaft, which are close to the inner side walls of the processing frames.

As a preferred embodiment, a limiting cavity is formed in the inner portion of the telescopic sleeve, a spring is fixedly connected to the upper end of the limiting cavity, a sliding block is fixedly connected to the other end of the spring, the sliding block is slidably connected to the limiting cavity, and a sliding rod is fixedly connected to the lower end of the sliding block.

In a preferred embodiment, the corners of the lower surface of the processing frame are fixedly connected with support rods, and the lower surfaces of the support rods are fixedly connected with wheels.

Compared with the prior art, the utility model provides a hydraulic engineering silt treatment facility includes following beneficial effect at least:

(1) the silt water solution in the stirring tank drives a first bevel gear to rotate at an output shaft of a servo motor, the first bevel gear is meshed with a second bevel gear to drive a first stirring shaft and a third gear to rotate, the third gear is meshed with a fourth gear to further drive stirring blades on the first stirring shaft and the second stirring shaft to rotate, and large granular substances in silt are crushed in one step;

(2) the silt aqueous solution after the stirring falls on the filter screen, and second gear drives axis of rotation and cam and rotates for the cam strikes the connecting block, and the slide bar above the connecting block takes place deformation from top to bottom under the effect of spring, makes the filter screen between two connecting blocks produce the vibration, and then the mud and the water in the silt aqueous solution fall to the collection liquid case, and the sand in the silt aqueous solution falls from the sand mouth that falls.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic side view of the stirring box of the present invention;

fig. 3 is a schematic view of the structure of the telescopic sleeve of the present invention.

In the figure: 1. a processing frame; 2. a stirring box; 3. a servo motor; 4. a feed inlet; 5. a valve; 6. a first bevel gear; 7. a second bevel gear; 8. a stirring mechanism; 81. a first stirring shaft; 82. a third gear; 83. a fourth gear; 84. a second stirring shaft; 85. stirring blades; 9. a filtering mechanism; 91. a telescopic sleeve; 92. a slide bar; 93. connecting blocks; 94. a filter screen; 10. a knocking mechanism; 101. a rotating shaft; 102. A cam; 11. a first gear; 12. a second gear; 13. a gear belt; 14. a sand falling port; 15. a liquid collection tank; 16. a spring; 17. a slider; 18. a support bar; 19. and (7) wheels.

Detailed Description

The present invention will be further described with reference to the following examples.

The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention. The condition in the embodiment can be further adjusted according to concrete condition the utility model discloses a it is right under the design prerequisite the utility model discloses a simple improvement of method all belongs to the utility model discloses the scope of claiming.

Referring to fig. 1-3, the utility model provides a hydraulic engineering silt treatment equipment, which comprises a treatment frame 1, wherein the upper end of the treatment frame 1 is fixedly connected with a stirring tank 2 and a servo motor 3, the lower surface corners of the treatment frame 1 are fixedly connected with support rods 18, and the lower surfaces of the support rods 18 are fixedly connected with wheels 19 (see fig. 1); the wheel 19 can drive the equipment to move around, thereby improving the moving performance of the equipment.

The upper end of the stirring box 2 is provided with a feeding hole 4, the lower end of the stirring box 2 is provided with a valve 5, an output shaft of a servo motor 3 is fixedly connected with a first bevel gear 6, the first bevel gear 6 is meshed with a second bevel gear 7, the second bevel gear 7 is fixedly connected at one side of a stirring mechanism 8, the stirring mechanism 8 consists of a first stirring shaft 81, a third gear 82, a fourth gear 83, a second stirring shaft 84 and a stirring blade 85, the second bevel gear 7 is fixedly connected at one end of the first stirring shaft 81, the first stirring shaft 81 is rotatably connected on the side wall inside the stirring box 2, the outer side wall of the first stirring shaft 81 at the outside of the stirring box 2 is fixedly connected with the third gear 82, the outer wall of the other end of the first stirring shaft 81 is fixedly connected with a first gear 11, the third gear 82 is meshed with the fourth gear 83, the fourth gear 83 is fixedly connected at one end of the second stirring shaft 84 at the outside of the stirring box 2, the second stirring shaft 84 is rotatably connected to the side wall of the stirring box 2, and a plurality of stirring blades 85 (see fig. 1) are fixedly connected to the outer side walls of the first stirring shaft 81 and the second stirring shaft 84 inside the stirring box 2; the large particle substances in the silt are crushed in one step by the rotation of the first stirring shaft 81 and the second stirring shaft 84.

A first gear 11 is fixedly connected to the other side of the stirring mechanism 8, a second gear 12 is meshed with the first gear 11 through a gear belt 13, a filtering mechanism 9 is fixedly connected to the lower surface inside the processing frame 1, the filtering mechanism 9 is composed of a telescopic sleeve 91, a sliding rod 92, a connecting block 93 and a filter screen 94, four telescopic sleeves 91 are fixedly connected to the lower end inside the processing frame 1, a limiting cavity is formed inside each telescopic sleeve 91, a spring 16 is fixedly connected to the upper end of each limiting cavity, a sliding block 17 is fixedly connected to the other end of each spring 16, each sliding block 17 is slidably connected into each limiting cavity, and a sliding rod 92 (see fig. 3) is fixedly connected to the lower end of each sliding block 17; through the use of telescoping sleeve 91 and spring 16, filter 94 may be vibrated after cam 102 is struck.

Sliding rods 92 are slidably connected in the four telescopic sleeves 91, the lower ends of the two sliding rods 92 are fixedly connected with connecting blocks 93, and a filter screen 94 (see fig. 1) is arranged between the two connecting blocks 93; after the cam 102 strikes the filter screen 94, the sludge and water in the aqueous silt solution fall into the liquid collecting tank 15, and the sand in the aqueous silt solution falls through the sand falling port 14.

A sand falling port 14 is formed in one side wall of the processing frame 1, a liquid collecting tank 15 is fixedly connected to the upper surface of the interior of the processing frame 1, a knocking mechanism 10 is fixedly connected to one side of the second gear 12, the knocking mechanism 10 is composed of a rotating shaft 101 and cams 102, the rotating shaft 101 is fixedly connected to one side of the second gear 12, the rotating shaft 101 penetrates through the processing frame 1 and is rotatably connected between the processing frames 1, and two cams 102 are fixedly connected to the outer wall, close to the inner side wall of the processing frame 1, of the two ends of the rotating shaft 101 (see fig. 1); the rotating shaft 101 and the cam 102 are driven to rotate by the second gear 12, so that the cam 102 strikes the connecting block 93, and the sliding rod 92 and the filter screen 94 on the connecting block 93 vibrate up and down under the action of the spring 16.

When the device is used, firstly, the aqueous solution mixed with silt is poured into the stirring box 2 from the feeding hole 4, the servo motor 3 is started, the output shaft of the servo motor 3 drives the first bevel gear 6 to rotate, the first bevel gear 6 is meshed with the second bevel gear 7 to drive the first stirring shaft 81 and the third gear 82 to rotate, the third gear 82 is meshed with the fourth gear 83 to further drive the stirring blades 85 on the first stirring shaft 81 and the second stirring shaft 84 to rotate, so that large granular substances in the silt are further crushed, meanwhile, the first gear 11 drives the second gear 12 to rotate through the gear belt 13, the valve 5 is opened, the stirred silt aqueous solution falls onto the filter screen 94, the second gear 12 drives the rotating shaft 101 and the cam 102 to rotate, so that the cam 102 knocks the connecting block 93, and the sliding rod 92 on the connecting block 93 deforms up and down under the action of the spring 16, so that the filter screen 94 between the two connecting blocks 93 vibrates, and then the sludge and water in the aqueous solution of silt fall into the liquid collecting tank 15, and the sand in the aqueous solution of silt falls from the sand falling port 14.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a hydraulic engineering silt treatment facility, is including handling frame (1), its characterized in that: the upper end of the processing frame (1) is fixedly connected with a stirring box (2) and a servo motor (3), the upper end of the stirring box (2) is provided with a feeding hole (4), the lower end of the stirring box (2) is provided with a valve (5), an output shaft of the servo motor (3) is fixedly connected with a first bevel gear (6), the first bevel gear (6) is meshed with a second bevel gear (7), the second bevel gear (7) is fixedly connected to one side of a stirring mechanism (8), the other side of the stirring mechanism (8) is fixedly connected with a first gear (11), the first gear (11) is meshed with a second gear (12) through a gear belt (13), the lower surface of the interior of the processing frame (1) is fixedly connected with a filtering mechanism (9), a sand falling port (14) is formed in one side wall of the processing frame (1), and the upper surface of the interior of the processing frame (1) is fixedly connected with a liquid collecting box (15), and one side of the second gear (12) is fixedly connected with a knocking mechanism (10).

2. The hydraulic engineering silt treatment equipment of claim 1, characterized in that: the stirring mechanism (8) consists of a first stirring shaft (81), a third gear (82), a fourth gear (83), a second stirring shaft (84) and stirring blades (85), second bevel gear (7) rigid coupling is in the one end of first (mixing) shaft (81), first (mixing) shaft (81) rotate to be connected on the inside lateral wall of agitator tank (2), first (mixing) shaft (81) are located the rigid coupling on the outside lateral wall of agitator tank (2) outside and have third gear (82), the rigid coupling has first gear (11) on the outer wall of first (mixing) shaft (81) other end, third gear (82) and fourth gear (83) mesh mutually, fourth gear (83) rigid coupling is located agitator tank (2) outside one end in second (mixing) shaft (84), second (mixing) shaft (84) rotate to be connected on the lateral wall of agitator tank (2), first (mixing) shaft (81) and second (mixing) shaft (84) are located equal rigid coupling on the inside lateral wall of agitator tank (2) and have a plurality of stirring leaves (85).

3. The hydraulic engineering silt treatment equipment of claim 1, characterized in that: filtering mechanism (9) comprises flexible cover (91), slide bar (92), connecting block (93) and filter screen (94), and the lower extreme rigid coupling of handling frame (1) inside has four flexible covers (91), and sliding connection has slide bar (92) in four flexible covers (91), and the lower extreme rigid coupling of two slide bars (92) has connecting block (93), installs filter screen (94) between two connecting blocks (93).

4. The hydraulic engineering silt treatment equipment of claim 1, characterized in that: knocking mechanism (10) comprises axis of rotation (101) and cam (102), and one side rigid coupling of second gear (12) has axis of rotation (101), and the processing frame (1) and the rotation of running through of axis of rotation (101) are connected between processing frame (1), and the rigid coupling has two cam (102) on the outer wall that axis of rotation (101) both ends are close to processing frame (1) inside wall.

5. The hydraulic engineering silt treatment equipment of claim 3, characterized in that: spacing chamber has been seted up to flexible cover (91) inside, and the upper end rigid coupling in spacing chamber has spring (16), and the other end rigid coupling of spring (16) has slider (17), and slider (17) sliding connection has slide bar (92) in spacing intracavity, the lower extreme rigid coupling of slider (17).

6. The hydraulic engineering silt treatment equipment of claim 1, characterized in that: the lower surface corner of the processing frame (1) is fixedly connected with a support rod (18), and the lower surface of the support rod (18) is fixedly connected with a wheel (19).

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