CN216764664U

CN216764664U - Movable sludge dewatering equipment

Info

Publication number: CN216764664U
Application number: CN202220025701.0U
Authority: CN
Inventors: 王超; 胡艳玲
Original assignee: Fuzhou Fuda Zhongjian Bioengineering Co ltd
Current assignee: Fuzhou Fuda Zhongjian Bioengineering Co ltd
Priority date: 2022-01-06
Filing date: 2022-01-06
Publication date: 2022-06-17
Anticipated expiration: 2032-01-06

Abstract

The utility model discloses a movable sludge dewatering device, which structurally comprises a sealing cover, a feeding box, a dewatering box, a movable wheel, an inflow connecting pipe, a movable box body and a temporary storage tank, wherein the inflow connecting pipe is used for conveying sludge to enter the feeding box, the sludge enters the dewatering box for dewatering processing, and finally the temporary storage tank is used for storing, when the sludge passes through the inflow connecting pipe, the sludge is impacted by a buffering structure on a shell to expand the buffering sleeve under stress and buffer the sludge, and an engaging plate on the buffering sleeve is stressed to drive an engaging rod to transmit acting force to an elastic sleeve for buffering, so that the impact force caused by the conveyed sludge can be better buffered when the dewatering device is used by improving the structure of the device, and the impact of the sludge on the sealing structure of the inflow connecting pipe is reduced, it has a better protection effect.

Description

Movable sludge dewatering equipment

Technical Field

The utility model relates to a movable sludge dewatering device, belonging to the technical field of sludge processing equipment.

Background

Portable silt dewatering equipment is a convenient removal, can dewater the processing to silt, makes things convenient for its equipment of carrying out the transportation, and its convenient to use, the removal performance is good, the efficiency of the silt clearance operation of great improvement, but prior art still has following defect:

when the existing dewatering equipment is used, the inflow pipeline of the existing dewatering equipment is subjected to larger impact when being communicated with sludge and sewage, and a larger water hammer effect is generated, so that the sealing structure of the inflow pipe is subjected to larger impact for a long time, the damage of the inflow pipe is accelerated, and the sealing performance of the inflow pipe is influenced.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide a movable sludge dewatering device to solve the problems that when the existing dewatering device in the prior art is in operation, an inflow pipeline of the existing dewatering device is subjected to larger impact when being communicated with sludge and sewage, larger water hammer effect is generated, the sealing structure of an inflow pipe is subjected to larger impact for a long time, the damage of the sealing structure is accelerated, and the sealing performance of the sealing structure is influenced.

In order to achieve the purpose, the utility model is realized by the following technical scheme: a movable sludge dewatering device structurally comprises a sealing cover, a feeding box, a dewatering box, a movable wheel, an inflow connecting pipe, a movable box body and a temporary storage tank, the sealing cover is embedded and arranged on the top end of the movable box body, the bottom end of the feeding box is welded with the top end of the dewatering box, the movable wheel is arranged on the bottom end of the movable box body, the rear end of the inflow connecting pipe and the front end of the feeding box are of an integrated structure, the temporary storage tank is embedded in the movable box body, the inflow connecting pipe comprises a butt joint thread, a shell, a sealing ring cylinder, a flow distribution plate and a buffer structure, the butt joint thread and the left end part of the shell are of an integrated structure, the sealing ring cylinder is embedded in an inner ring of the shell, the flow distribution plate is positioned on the right side of the buffer structure, the outer ring of the buffer structure is welded with the inner ring of the shell, and the rear end of the shell and the front end of the feeding box are of an integrated structure.

Preferably, buffer structure includes linkage plate, buffering sleeve, links up pole, elastic sleeve, support, connecting shell, linkage plate and buffering sleeve be integral structure, the left end in the connecting shell is installed in the embedding of linkage pole, elastic sleeve's right-hand member bonds with the left end of support, connecting shell and support be integral structure.

Preferably, the feed box is located below the closure.

Preferably, the sealing ring cylinder adopts a ring cylinder structure, is made of rubber materials, has elasticity, and can slightly deform when being subjected to external force.

Preferably, the buffer sleeve is of a round platform hollow shell structure, the middle part of the buffer sleeve is hollow, the left end and the right end of the buffer sleeve are provided with openings which are communicated with each other, the buffer sleeve is made of rubber materials, and the buffer sleeve has the characteristics of elasticity and corrosion resistance, and can expand and deform when being subjected to external force.

Advantageous effects

The utility model relates to a mobile sludge dewatering device, which is characterized in that sludge is conveyed through an inflow connecting pipe and enters a feeding box, the sludge enters a dewatering box for dewatering processing, and is stored in a temporary storage tank, when the sludge passes through the inflow connecting pipe, the sludge firstly passes through a buffer structure on a shell to impact a buffer sleeve on the shell, so that the stress of the buffer sleeve is expanded, the impact force of the sludge is buffered, and a connecting plate on the buffer sleeve is stressed to drive a connecting rod to transfer the stress to an elastic sleeve for buffering.

Drawings

Other features, objects and advantages of the utility model will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural view of a mobile sludge dewatering apparatus of the present invention;

FIG. 2 is a cross-sectional detail structure diagram of the front view of the inflow adapter of the present invention;

FIG. 3 is a cross-sectional detail view of a front view of the cushioning structure of the present invention;

fig. 4 is a cross-sectional detail structure diagram of the front view of the buffering structure of the present invention after operation.

In the figure: the device comprises a sealing cover-1, a feeding box-2, a dewatering box-3, a moving wheel-4, an inflow connecting pipe-5, a moving box-6, a temporary storage tank-7, a butt joint screw-51, an outer shell-52, a sealing ring barrel-53, a flow distribution plate-54, a buffering structure-55, a connecting plate-551, a buffering sleeve-552, a connecting rod-553, an elastic sleeve-554, a support-555 and a connecting shell-556.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the utility model easy to understand, the utility model is further described with the specific embodiments.

Referring to fig. 1, 2, 3 and 4, the present invention provides a technical solution of a mobile sludge dewatering device: the structure of the device comprises a sealing cover 1, a feeding box 2, a dewatering box 3, a moving wheel 4, an inflow connecting pipe 5, a moving box 6 and a temporary storage tank 7, wherein the sealing cover 1 is embedded and installed on the top end of the moving box 6, the bottom end of the feeding box 2 is welded with the top end of the dewatering box 3, the moving wheel 4 is arranged on the bottom end of the moving box 6, the rear end of the inflow connecting pipe 5 and the front end of the feeding box 2 are of an integrated structure, the temporary storage tank 7 is embedded and installed in the moving box 6, the inflow connecting pipe 5 comprises a butt joint thread 51, an outer shell 52, a sealing ring cylinder 53, a flow distribution plate 54 and a buffer structure 55, the butt joint thread 51 and the left end part of the outer shell 52 are of an integrated structure, the sealing ring cylinder 53 is embedded and installed on the inner ring of the outer shell 52, the flow distribution plate 54 is positioned on the right side of the buffer structure 55, the outer ring of the buffer structure 55 is welded with the inner ring of the outer shell 52, the rear end of the outer shell 52 and the front end of the feeding box 2 are of an integrated structure, the buffering structure 55 comprises a connecting plate 551, a buffering sleeve 552, a connecting rod 553, an elastic sleeve 554, a support 555 and a connecting shell 556, the connecting plate 551 and the buffering sleeve 552 are of an integrated structure, the connecting rod 553 is embedded and installed at the left end of the connecting shell 556, the right end of the elastic sleeve 554 is bonded with the left end of the support 555, the connecting shell 556 and the support 555 are of an integrated structure, the feeding box 2 is positioned below the sealing cover 1, the sealing ring 53 is of a ring tube structure, is made of rubber, has elasticity, can slightly deform when being subjected to external force, and can better enhance the sealing performance of a connecting pipeline, the buffering sleeve 552 is of a round platform hollow shell structure, the middle part is hollow, the left end and the right end are communicated with each other through an opening, and is made of rubber and has elasticity, the corrosion-resistant characteristic can take place to expand when receiving external force and warp, carries out preliminary buffering to the impact force that silt was carried.

When needs use equipment to process, carry silt through influent stream takeover 5, make it come into feed box 2, come into dehydration in the dehydration tank 3 and carry out dehydration, store in jar 7 that keeps in at last, silt is through influent stream takeover 5, can be earlier through buffer structure 55 on the shell 52, cause the impact to the buffer sleeve 552 on it, make its atress take place the expansion, cause the buffering to the silt impact force simultaneously, and the linking plate 551 atress on the buffer sleeve 552 drives linking pole 553 atress and conducts the effort to elastic sleeve 554 on, cushions.

The utility model solves the problems that when the existing dewatering equipment in the prior art is in operation, the inflow pipeline is often subjected to larger impact when being communicated with sludge and sewage, so that a larger water hammer effect is generated, the sealing structure of the inflow pipe is subjected to larger impact for a long time, the damage of the inflow pipe is accelerated, and the sealing performance of the inflow pipe is influenced, the sludge is conveyed through the inflow connecting pipe 5 through the mutual combination of the components, the sludge enters the feeding box 2 and the dewatering box 3 for dewatering processing, and finally the sludge is stored in the temporary storage tank 7, when the sludge passes through the inflow connecting pipe 5, the sludge firstly passes through the buffer structure 55 on the shell 52 to impact the buffer sleeve 552 on the buffer sleeve 552, so that the sludge is stressed and expanded, and simultaneously, the impact force of the sludge is buffered, and the connecting plate 551 on the buffer sleeve 552 drives the connecting rod 553 to be stressed and transmit the acting force to the elastic sleeve 554, buffering, through the structure of improvement equipment, make dewatering equipment when using, the impact force that the silt that can be better led to the fact buffers, reduces its impact to inflow takeover seal structure, plays a better guard action to it.

While there have been shown and described what are at present considered the fundamental principles and essential features of the utility model and its advantages, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. The utility model provides a portable silt dewatering equipment, its structure includes closing cap (1), feed box (2), dewatering box (3), removes wheel (4), influent flow takeover (5), removes box (6), jar (7) of keeping in, its characterized in that:

the sealing cover (1) is embedded in the top end of the movable box body (6), the bottom end of the feeding box (2) is welded with the top end of the dewatering box (3), the movable wheel (4) is arranged on the bottom end of the movable box body (6), the rear end of the inflow connecting pipe (5) and the front end of the feeding box (2) are of an integrated structure, the temporary storage tank (7) is embedded in the movable box body (6), the inflow connecting pipe (5) comprises a butt joint thread (51), a shell (52), a sealing ring cylinder (53), a flow distribution plate (54) and a buffering structure (55), the butt joint thread (51) and the left end of the shell (52) are of an integrated structure, the sealing ring cylinder (53) is embedded in the inner ring of the shell (52), the flow distribution plate (54) is located on the right side of the buffering structure (55), the outer ring of the buffering structure (55) is welded with the inner ring of the shell (52), the rear end of the shell (52) and the front end of the feeding box (2) are of an integrated structure.

2. The mobile sludge dewatering apparatus of claim 1, wherein: the buffer structure (55) comprises a connecting plate (551), a buffer sleeve (552), a connecting rod (553), an elastic sleeve (554), a support (555) and a connecting shell (556), the connecting plate (551) and the buffer sleeve (552) are of an integrated structure, the connecting rod (553) is embedded into the left end of the connecting shell (556), the right end of the elastic sleeve (554) is bonded with the left end of the support (555), and the connecting shell (556) and the support (555) are of an integrated structure.

3. A mobile sludge dewatering apparatus according to claim 1, wherein: the feeding box (2) is positioned below the sealing cover (1).

4. The mobile sludge dewatering apparatus of claim 1, wherein: the sealing ring cylinder (53) is of a ring cylinder structure, is made of rubber materials and has elasticity.

5. A mobile sludge dewatering apparatus according to claim 2, wherein: the buffer sleeve (552) is of a round platform hollow shell structure, the middle part of the buffer sleeve is hollow, and the left end and the right end of the buffer sleeve are communicated through openings.