CN115540551B - High-frequency vibration dewatering equipment - Google Patents

Abstract

The invention discloses high-frequency vibration dehydration equipment, which belongs to the technical field of dehydration equipment and comprises a material supporting base, wherein a first crank and a second crank are assembled on two sides of the material supporting base, a dehydration disc is connected with the material supporting base through a side connecting arm, a draining screen is distributed on the surface of the dehydration disc, one end of the dehydration disc is connected with the first crank through a main rocker arm, two groups of supports are fixedly assembled on the dehydration disc, a material turning cylinder is assembled between the supports, the supports are fixedly distributed on the material supporting base, two groups of follow-up blocks are distributed in the support, the follow-up blocks are in linkage arrangement with the first crank, and the tail ends of the follow-up blocks are connected with an elastic shifting plate.

Description

High-frequency vibration dewatering equipment

Technical Field

The invention belongs to the technical field of dehydration equipment, and particularly relates to high-frequency vibration dehydration equipment.

Background

Vibration dewatering equipment main action is dehydration, desliming, can be used to washed sand, coal slime recovery, tailing dry discharge etc. can pass through the moisture that contains in the quick drop sieve material of high-frequency vibration, and current high-frequency vibration dewatering equipment is when using, because the continuous feed-in of material makes the material that contains water stack up easily in dewatering equipment, leads to the dewatering effect unsatisfactory.

Disclosure of Invention

In view of the defects in the prior art, an embodiment of the present invention is directed to a high-frequency vibration dewatering device, so as to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

a high-frequency vibratory dewatering apparatus comprising:

the base component comprises a material supporting base, a first crank and a second crank, wherein the first crank and the second crank are assembled on two sides of the material supporting base;

the dewatering disc set comprises a dewatering disc, a hollow groove, a draining screen, side connecting arms and a main rocker arm, the dewatering disc is arranged on one side of the material supporting base and movably connected with the material supporting base through the side connecting arms, the hollow groove is arranged on the end face, away from the material supporting base, of one side of the dewatering disc, the draining screen is arranged on the surface of the dewatering disc at intervals, the main rocker arm is further rotatably connected to one end of the dewatering disc, and the tail end of the main rocker arm is connected with the first crank in an assembling mode;

the material vibrating assembly comprises supports, a first sliding block, a material turning cylinder, a second sliding block and a synchronous belt, wherein the two groups of supports are fixedly assembled on the dewatering disc, the first sliding block and the second sliding block are respectively assembled in the two groups of supports in an elastic sliding mode, the material turning cylinder is arranged between the first sliding block and movably connected with the second sliding block, the synchronous belt is further arranged on one side of the second sliding block, one end of the synchronous belt is connected with the material turning cylinder in an assembling mode, and the other end of the synchronous belt is connected with a second crank in a rotating mode and used for driving the material turning cylinder to circumferentially rotate;

the tensioning mechanism is arranged on the synchronous belt and used for elastically tensioning the synchronous belt; and

scraping mechanism, scraping mechanism includes that support, first follow-up block, second follow-up block, driven lever and elasticity are dialled the board, the support is fixed to be laid on holding in the palm material base side end face and towards dewatering tray one side setting, two sets of spouts have been laid to the support inside, and elastic sliding is equipped with first follow-up block and second follow-up block in two sets of spouts respectively, first follow-up block and second follow-up block activity meet mutually and with first crank linkage sets up, equal fixedly connected with driven lever on first follow-up block and the second follow-up block, the driven lever passes hollow groove one side and is connected with the elasticity and dials the board.

As a further aspect of the present invention, the base member further includes:

the guide groove is obliquely arranged on one side of the material supporting base and is arranged towards one end of the dewatering disc; and

and the driving motor is fixedly arranged on one side of the material supporting base, is assembled and connected with the first crank and the second crank and is used for driving the first crank and the second crank to synchronously rotate.

As a further scheme of the invention, a plurality of inclined grooves are distributed among the draining screens which are distributed at intervals, and the inclined grooves are matched with the moving direction of the material.

As a further scheme of the invention, the plurality of side connecting arms are parallelly assembled between the material supporting base and the dewatering disc.

As a further aspect of the present invention, the material vibrating assembly further includes:

the discharge holes are circumferentially distributed on the wall surface of the cylinder body of the turning cylinder;

the feeding pipe is fixedly assembled on the first sliding block, is connected with the material turning cylinder in a rotating mode and is used for inputting materials to be dehydrated into the material turning cylinder; and

and one end of the driving rod is fixedly connected with the material turning barrel and is rotationally connected with the second sliding block, and the other end of the driving rod is assembled and connected with the synchronous belt.

As a further aspect of the present invention, the tension mechanism includes:

one end of the connecting frame is rotatably connected with the driving rod, and the other end of the connecting frame is arranged on one side of the synchronous belt;

the abutting wheels are elastically assembled on two sides of the tail end of the connecting frame and are respectively meshed and connected with the synchronous belts; and

and the limiting buckle is arranged on one side of the butting wheel and one side of the synchronous belt and is used for limiting the synchronous belt in the butting wheel.

As a further aspect of the present invention, the scraping mechanism further includes:

one end of the auxiliary rocker arm is assembled and connected with the first crank, and the other end of the auxiliary rocker arm is assembled and connected with the first follow-up block;

the third crank is rotatably assembled on one side of the second follow-up block; and

and the transmission arm is arranged between the first follow-up block and the second follow-up block and is used for movably connecting the first follow-up block and the third crank.

In summary, compared with the prior art, the embodiment of the invention has the following beneficial effects:

according to the invention, through the dewatering disc movably assembled on the material supporting base and the material turning barrel movably arranged on the dewatering disc, water-absorbing agglomerated materials can be scattered on the dewatering disc under high-frequency vibration, and the materials are continuously dewatered in the movement process through the quick vibration of the dewatering disc, so that the continuous and quick dewatering of the water-containing materials is realized.

Drawings

Fig. 1 is a schematic perspective view of a high-frequency vibration dewatering apparatus according to an embodiment of the present invention.

Fig. 2 is a schematic structural view illustrating a mark a in the high-frequency vibration dewatering apparatus provided in an embodiment of the present invention.

FIG. 3 is a schematic view of the backside structure of the high-frequency vibration dewatering apparatus provided in an embodiment of the present invention.

Fig. 4 is a schematic structural view illustrating a mark B in the high-frequency vibration dewatering apparatus provided in an embodiment of the present invention.

FIG. 5 is a schematic side view of a high-frequency vibration dewatering apparatus according to an embodiment of the present invention.

Reference numerals are as follows: 1-base member, 101-material supporting base, 102-diversion trench, 103-driving motor, 104-first crank, 105-second crank, 2-dewatering disk group, 201-dewatering disk, 202-hollow trench, 203-inclined trench, 204-draining screen, 205-material collecting barrel, 206-side connecting arm, 207-main rocker arm, 3-material vibrating component, 301-bracket, 302-first slider, 303-material turning barrel, 304-discharge hole, 305-material feeding pipe, 306-second slider, 307-driving rod, 308-synchronous belt, 4-tensioning mechanism, 401-connecting frame, 402-butting wheel, 403-limit buckle, 5-material scraping mechanism, 501-support, 502-chute, 503-first follower block, 504-second follower block, 505-auxiliary rocker arm, 506-third crank, 507-driving arm, 508-follower rod and 509-elastic shifting plate.

Detailed Description

To more clearly illustrate the structural features and effects of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1-5, the high-frequency vibration dewatering device in an embodiment of the present invention includes a base member 1, where the base member 1 includes a material supporting base 101, a first crank 104 and a second crank 105, and the first crank 104 and the second crank 105 are assembled on two sides of the material supporting base 101; the dewatering disc set 2 comprises a dewatering disc 201, hollow grooves 202, draining screens 204, side connecting arms 206 and a main rocker arm 207, wherein the dewatering disc 201 is arranged on one side of the material supporting base 101 and movably connected with the material supporting base 101 through the side connecting arms 206, the hollow grooves 202 are arranged on the end face, away from the material supporting base 101, of one side of the dewatering disc 201, the draining screens 204 are arranged on the surface of the dewatering disc 201 at intervals, one end of the dewatering disc 201 is further rotatably connected with the main rocker arm 207, and the tail end of the main rocker arm 207 is assembled and connected with the first crank 104; the material vibrating component 3 comprises supports 301, a first sliding block 302, a material overturning barrel 303, a second sliding block 306 and a synchronous belt 308, the two groups of supports 301 are fixedly assembled on the dewatering disc 201, the first sliding block 302 and the second sliding block 306 are respectively assembled in the two groups of supports 301 in an elastic sliding mode, the material overturning barrel 303 is arranged between the first sliding block 302 and the first sliding block 302, the material overturning barrel 303 is movably connected with the second sliding block 306, the synchronous belt 308 is further arranged on one side of the second sliding block 306, one end of the synchronous belt 308 is assembled and connected with the material overturning barrel 303, and the other end of the synchronous belt 308 is rotatably connected with the second crank 105 and used for driving the material overturning barrel 303 to rotate circumferentially; the tensioning mechanism 4 is arranged on the synchronous belt 308 and used for elastically tensioning the synchronous belt 308; and the scraping mechanism 5 comprises a support 501, a first follow-up block 503, a second follow-up block 504, a driven rod 508 and an elastic shifting plate 509, wherein the support 501 is fixedly arranged on the end surface of one side of the material supporting base 101 and is arranged towards one side of the dewatering disc 201, two sets of sliding grooves 502 are arranged in the support 501, the first follow-up block 503 and the second follow-up block 504 are respectively assembled in the two sets of sliding grooves 502 in an elastic sliding manner, the first follow-up block 503 and the second follow-up block 504 are movably connected and are in linkage with the first crank 104, the driven rod 508 is fixedly connected to each of the first follow-up block 503 and the second follow-up block 504, and the driven rod 508 penetrates through the hollow groove 202 and is connected with the elastic shifting plate 509.

In practical application, when the high-frequency vibration dewatering equipment is used for dewatering, firstly, the first crank 104 and the second crank 105 on one side of the material supporting base 101 are driven to synchronously rotate, so that the main rocker 207 which is rotatably assembled on one side of the second crank 105 drives the dewatering disc 201 to reciprocate on one side of the material supporting base 101, meanwhile, the second crank 105 can drive the synchronous belt 308 to synchronously rotate in the rotating process, the turning cylinder 303 on one side of the synchronous belt 308 rotates under the driving action, because the turning cylinder 303 is elastically and slidably assembled on the bracket 301 through the first sliding block 302 and the second sliding block 306, when the dewatering disc 201 vibrates on one side of the material supporting base 101, the turning cylinder 303 generates vibration in the vertical direction under the inertia action, so that the material to be dewatered which is input into the turning cylinder 303 is turned and longitudinally vibrated in the turning cylinder 303, so that the material containing moisture is vibrated and dropped onto the dewatering tray 201 from the material turning cylinder 303, and the dewatering tray 201 is driven by the main rocker arm 207 to have an oblique projection in the oblique direction of the main rocker arm 207, so that the material dropped onto the dewatering tray 201 can continuously move in the oblique projection direction, thereby realizing the rapid turning and oblique pushing of the material on the dewatering tray 201 by continuous vibration, rapidly dewatering the material by a plurality of dewatering screens 204 arranged on the dewatering tray 201 in the vibration process, sending the dewatered material into the material collecting cylinder 205 for recycling after moving to the tail end position of the dewatering tray 201, and simultaneously, the support 501 arranged on one side of the material supporting base 101 and the first follow-up block 503 and the second follow-up block 504 which are slidably assembled in the support 501, synchronous reciprocating sliding is carried out under the driving action of the first crank 104, and the driven rod 508 and the elastic shifting plate 509 which are arranged on the driven rod are driven to reciprocate and scrape on one side of the dewatering disc 201, so that materials stacked on the dewatering disc 201 are scraped in a reciprocating manner by the two groups of elastic shifting plates 509 in the process of moving along the dewatering disc 201, the materials are uniformly paved on the dewatering disc 201, the dewatering effect of the vibration process on the materials is improved, and continuous vibration dewatering of the materials is realized.

Referring to fig. 1, in a preferred embodiment of the invention, the base member 1 further includes: the diversion trench 102 is obliquely distributed on one side of the material supporting base 101 and is arranged towards one end of the dewatering disc 201; and the driving motor 103 is fixedly arranged on one side of the material supporting base 101, is assembled and connected with the first crank 104 and the second crank 105, and is used for driving the first crank 104 and the second crank 105 to synchronously rotate.

In practical application of the present embodiment, the diversion trench 102 is obliquely disposed on one side of the material supporting base 101, so that the water that is removed by the vibration of the draining screen 204 drops onto the diversion trench 102 and then flows out along the inclined trench surface of the diversion trench 102, thereby preventing the formation of accumulated water.

In one aspect of the present embodiment, the driving motor 103 may be driven by a double-head motor, or may be driven synchronously by a single-head stepping motor in cooperation with the meshing teeth, and is not limited in this respect.

Referring to fig. 1, in a preferred embodiment of the present invention, a plurality of inclined grooves 203 are disposed between the draining screens 204 disposed at intervals, and the inclined grooves 203 are disposed in a manner matching with the moving direction of the material.

In practical application of the embodiment, a plurality of inclined grooves 203 are arranged between the draining screens 204 arranged at intervals, and the included angle between the inclined surface of each inclined groove 203 and the horizontal plane of the dewatering disc 201 is 30-45 degrees.

In one embodiment, since the inclined grooves 203 are inclined planes, when the material is scattered on the inclined grooves 203 under the inclined throwing action, the material can be prevented from reversely sliding on the dewatering tray 201 by gravity, thereby ensuring that the material continuously moves along the dewatering tray 201 under the vibration condition.

Referring to fig. 3, in a preferred embodiment of the present invention, the side connecting arms 206 are installed in parallel between the material supporting base 101 and the dewatering table 201.

In practical application of the present embodiment, the side connecting arms 206 are assembled in parallel between the material supporting base 101 and the dewatering tray 201, and are connected to the material supporting base 101 and the dewatering tray 201 in a rotating manner, so that the main rocker arm 207 can drive the dewatering tray 201 to perform reciprocating vibration around a fixed track in a process of rotating along with the second crank 105, and the side connecting arms 206 can limit a movement track of the dewatering tray 201.

In one case of this embodiment, the amplitude of the side of the dewatering table 201 can be changed by adjusting the length of the side link arm 206, the inclination angle of the main swing arm 207, and the radius of the second crank 105, thereby adjusting the horizontal moving speed and the vertical moving speed of the materials during the vibration.

Referring to fig. 1, in a preferred embodiment of the invention, the material vibrating assembly 3 further includes: the discharge holes 304 are circumferentially distributed on the wall surface of the cylinder body of the turning cylinder 303; the feeding pipe 305 is fixedly assembled on the first sliding block 302, is connected with the turning cylinder 303 in a rotating mode, and is used for inputting materials to be dehydrated into the turning cylinder 303; and a driving rod 307, one end of which is fixedly connected with the turning cylinder 303 and is rotatably connected with the second slide block 306, and the other end of which is assembled and connected with the synchronous belt 308.

In practical application, when the driving rod 307 rotates under the driving action of the synchronous belt 308, the turning cylinder 303 can be driven to rotate synchronously, and the materials are input into the feeding pipe 305 on the other side of the turning cylinder 303 and then pass through the first sliding block 302 to enter the turning cylinder 303, when the turning cylinder 303 rotates in a reciprocating manner, the water-absorbing materials can be driven to turn over continuously, and the water-absorbing materials are vibrated out continuously through the discharging hole 304 by the reciprocating vibration of the dehydration disc 201, so that the water-absorbing agglomerated materials are primarily separated, and are continuously output to the dehydration disc 201 after being refined, and the residual moisture in the materials is vibrated by the reciprocating vibration of the dehydration disc 201.

In one aspect of this embodiment, the mesh size of the draining screen 204 is less than the particle size of the material by default.

Referring to fig. 4, in a preferred embodiment of the invention, the tensioning mechanism 4 includes: one end of the connecting frame 401 is rotatably connected with the driving rod 307, and the other end of the connecting frame 401 is arranged on one side of the synchronous belt 308; the abutting wheels 402 are elastically assembled at two sides of the tail end of the connecting frame 401 and are respectively meshed and connected with the synchronous belts 308; and a limit buckle 403 arranged on one side of the abutting wheel 402 and the synchronous belt 308 and used for limiting the synchronous belt 308 in the abutting wheel 402.

In practical application, when the synchronous belt 308 is in the process of driving the driving rod 307 to rotate, because the distance between the dewatering disc 201 and the supporting base 101 is changed continuously, the tension of the synchronous belt 308 is changed continuously, the connecting frame 401 arranged on one side of the driving rod 307 is rotated, and the abutting wheels 402 arranged on two sides of the connecting frame 401 are assembled in an elastic movable manner, so that the synchronous belt 308 can be elastically abutted to the synchronous belt 308 and meshed with the synchronous belt 308, the synchronous belt 308 is limited on one side of the abutting wheels 402 through the limit buckle 403, the synchronous belt 308 is always kept in a tension state in the movement, the second crank 105 can utilize the synchronous belt 308 to synchronously drive the driving rod 307 to rotate, and the material is turned over by driving the material turning cylinder 303.

Referring to fig. 2, in a preferred embodiment of the invention, the scraping mechanism 5 further includes: one end of the auxiliary rocker arm 505 is assembled and connected with the first crank 104, and the other end of the auxiliary rocker arm 505 is assembled and connected with the first follow-up block 503; a third crank 506 rotatably mounted on one side of the second follower block 504; and a transmission arm 507 arranged between the first follow-up block 503 and the second follow-up block 504 for movably connecting the first follow-up block 503 and the third crank 506.

In practical application, because the first follower block 503 is assembled and connected with the first crank 104 through the auxiliary rocker 505, when the first crank 104 rotates reciprocally, the first follower block 503 can be synchronously driven to slide in the chute 502, and the first follower block 503 and the second follower block 504 are in transmission connection through the third crank 506 and the transmission arm 507, so that the second follower block 504 can move simultaneously with the first follower block 503 and drive the elastic shifting plate 509 assembled at the end of the driven rod 508 to slide on one side of the dewatering tray 201, and thus the material to be dewatered on the surface of the dewatering tray 201 is scraped by the elastic shifting plate 509, and the dewatering effect is prevented from being influenced by continuous accumulation of the material.

In one case of this embodiment, the elastic shifting plate 509 can also prevent the moving distance of the material in the horizontal direction from being too large, and prolong the vibration time of the material on the dewatering tray 201, so as to improve the dewatering effect, and a gap is reserved between the bottom of the elastic shifting plate 509 and the dewatering tray 201, and the elastic shifting plate 509 is preferably made of a flexible material, so as to reduce the mechanical interference with the dewatering tray 201, and facilitate better material leveling.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (2)

1. A high-frequency vibration dewatering apparatus characterized by comprising:

the base component comprises a material supporting base, a first crank and a second crank, wherein the first crank and the second crank are assembled on two sides of the material supporting base;

the dewatering disc set comprises a dewatering disc, a hollow groove, a draining screen, side connecting arms and a main rocker arm, the dewatering disc is arranged on one side of the material supporting base and movably connected with the material supporting base through the side connecting arms, the hollow groove is arranged on the end face, away from the material supporting base, of one side of the dewatering disc, the draining screen is arranged on the surface of the dewatering disc at intervals, the main rocker arm is further rotatably connected to one end of the dewatering disc, and the tail end of the main rocker arm is connected with the first crank in an assembling mode;

the material vibrating assembly comprises supports, a first sliding block, a material turning cylinder, a second sliding block and a synchronous belt, wherein the two groups of supports are fixedly assembled on the dewatering disc, the first sliding block and the second sliding block are respectively assembled in the two groups of supports in an elastic sliding mode, the material turning cylinder is arranged between the first sliding block and movably connected with the second sliding block, the synchronous belt is further arranged on one side of the second sliding block, one end of the synchronous belt is connected with the material turning cylinder in an assembling mode, and the other end of the synchronous belt is connected with a second crank in a rotating mode and used for driving the material turning cylinder to circumferentially rotate;

the tensioning mechanism is arranged on the synchronous belt and used for elastically tensioning the synchronous belt;

the material scraping mechanism comprises a support, a first follow-up block, a second follow-up block, a driven rod and an elastic shifting plate, the support is fixedly arranged on the end face of one side of the material supporting base and is arranged towards one side of the dewatering disc, two groups of sliding grooves are arranged in the support, the first follow-up block and the second follow-up block are respectively assembled in the two groups of sliding grooves in an elastic sliding mode, the first follow-up block and the second follow-up block are movably connected and are arranged in a linkage mode with the first crank, the driven rod is fixedly connected to each of the first follow-up block and the second follow-up block, and the elastic shifting plate is connected to one side, penetrating through the hollow groove, of each driven rod;

the base member further includes:

the guide groove is obliquely arranged on one side of the material supporting base and is arranged towards one end of the dewatering disc;

the driving motor is fixedly arranged on one side of the material supporting base, is assembled and connected with the first crank and the second crank, and is used for driving the first crank and the second crank to synchronously rotate;

the side connecting arms are assembled between the material supporting base and the dewatering disc in parallel;

the material subassembly that shakes still includes:

the discharge holes are circumferentially distributed on the wall surface of the cylinder body of the turning cylinder;

the feeding pipe is fixedly assembled on the first sliding block, is connected with the material turning cylinder in a rotating mode and is used for inputting materials to be dehydrated into the material turning cylinder;

one end of the driving rod is fixedly connected with the material turning cylinder and is rotationally connected with the second sliding block, and the other end of the driving rod is assembled and connected with the synchronous belt;

the tensioning mechanism includes:

one end of the connecting frame is rotatably connected with the driving rod, and the other end of the connecting frame is arranged on one side of the synchronous belt;

the abutting wheels are elastically assembled on two sides of the tail end of the connecting frame and are respectively meshed and connected with the synchronous belts;

the limiting buckle is arranged on one side of the butting wheel and one side of the synchronous belt and is used for limiting the synchronous belt in the butting wheel;

the scraping mechanism further comprises:

one end of the auxiliary rocker arm is assembled and connected with the first crank, and the other end of the auxiliary rocker arm is assembled and connected with the first follow-up block;

the third crank is rotatably assembled on one side of the second follow-up block;

and the transmission arm is arranged between the first follow-up block and the second follow-up block and is used for movably connecting the first follow-up block and the third crank.

2. The high-frequency vibration dewatering equipment according to claim 1, wherein a plurality of inclined grooves are arranged among the draining screens arranged at intervals, and the inclined grooves are matched with the moving direction of the materials.

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