CN216954147U - A energy-concerving and environment-protective type cooling device for gesso production - Google Patents

Abstract

The utility model provides an energy-saving and environment-friendly cooling device for gypsum powder production, which comprises a circulating pump, an overhaul baffle, a plate-type ultrafiltration membrane, a microporous ceramic filter plate, a cooling branch pipe, a first dispersion plate and a conical air guide shell, wherein the circulating pump is assembled at the lower side of the left end surface of a cooling box body, the microporous ceramic filter plate is plugged at the lower side in the cooling box body, the plate-type ultrafiltration membrane is plugged below the microporous ceramic filter plate, the overhaul baffle is installed at the lower side of the right end surface of the cooling box body, the conical air guide shell is welded at the upper side of the left end surface of the cooling box body, the first dispersion plate is installed at the lower end surface of a box cover plate, the cooling branch pipe is welded at the lower end surface of the first dispersion plate, the design solves the problems that the cooling effect of the original gypsum powder cooler is poor and the cooling pipeline is easy to block.

Description

A energy-concerving and environment-protective type cooling device for gesso production

Technical Field

The utility model relates to an energy-saving and environment-friendly cooling device for gypsum powder production, and belongs to the technical field of gypsum powder processing.

Background

Gypsum is a monoclinic mineral and is a hydrate whose main chemical component is calcium sulfate (CaSO 4). Gypsum is a widely used industrial and building material. It can be used for cement retarder, gypsum building product, model making, medical food additive, sulfuric acid production, paper filler, paint filler, etc., and the microporous structure and heat dehydration property of gypsum and its product make it possess excellent sound-insulating, heat-insulating and fire-resisting properties.

In the gesso cooler use, do not have cooling water cooling circulation mechanism in the past, consequently make the waste of cooling water comparatively serious, current cooling structure is comparatively dispersed, and the use volume is great, not only needs more space, inconvenient dismouting maintenance moreover, and the practicality is not good enough, now urgently needs an energy-concerving and environment-protective type cooling device who is used for the gesso production to solve the above-mentioned problem that appears.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide an energy-saving and environment-friendly cooling device for producing gypsum powder, which is used for solving the problems in the background art.

In order to achieve the purpose, the utility model is realized by the following technical scheme: an energy-saving and environment-friendly cooling device for producing gypsum powder comprises a cooling box body, a drain valve, a circulating cooling assembly and a box cover plate, wherein the box cover plate is arranged on the upper end face of the cooling box body, the drain valve is arranged on the lower side of the right end face of the cooling box body, the circulating cooling assembly is arranged in the cooling box body and comprises a circulating pump, an overhauling baffle, a plate-type ultrafiltration membrane, a microporous ceramic filter plate, a flow guide shell, a second dispersion plate, a cooling branch pipe, a protective ventilation screen plate, a first dispersion plate, a flow collection shell and a conical air guide shell, the circulating pump is assembled on the lower side of the left end face of the cooling box body, the microporous ceramic filter plate is stuffed in the lower side of the cooling box body, the plate-type ultrafiltration membrane is stuffed in the lower side of the microporous ceramic filter plate, the overhauling baffle is installed on the lower side of the right end face of the cooling box body, the protective ventilation screen plate is installed on the upper side of the right end face of the cooling box body, the cooling box body is characterized in that a conical air guide shell is welded on the upper side of the left end face of the cooling box body, a first dispersion plate is installed on the lower end face of the box cover plate, a flow collection shell is arranged on the upper end face of the first dispersion plate, a cooling branch pipe is welded on the lower end face of the first dispersion plate, a second dispersion plate is welded on the lower end face of the cooling branch pipe, and a flow guide shell is welded on the lower end face of the second dispersion plate.

Furthermore, a liquid feeding pipe is welded on the lower side of the left end face of the cooling box body, and an observation window is installed on the lower side of the front end face of the cooling box body.

Furthermore, the cooling branch pipes are welded in multiple groups in an equal-specification mode, and the multiple groups of cooling branch pipes are communicated with the first dispersion disc and the second dispersion disc respectively.

Furthermore, the conical air guide shell is connected with an air outlet end of an external industrial air cooler through a heat insulation pipeline, and the drain valve is connected with an inlet of an external wastewater treatment pool through a pipeline.

Furthermore, the flow collecting shell is connected with a cooling liquid outlet in an external cooling machine through a pipeline, the circulating pump is connected with a cooling liquid inlet in the external cooling machine through a pipeline, and the circulating pump is connected with an external control switch through a lead.

Furthermore, the maintenance baffle, the box cover plate, the first dispersion disc and the protective ventilation net plate are all of detachable structures.

The utility model has the beneficial effects that: according to the energy-saving environment-friendly cooling device for gypsum powder production, due to the fact that the circulating pump, the maintenance baffle, the plate-type ultrafiltration membrane, the microporous ceramic filter plate, the flow guide shell, the second dispersion plate, the cooling branch pipes, the protective ventilation screen plate, the first dispersion plate, the flow collecting shell and the conical air guide shell are added, the circulating pump can be electrified and rotated to generate suction force to convey cooling liquid in the cooling box body to the inside of an external cooling machine, so that gypsum powder in the inside can be cooled, the cooling liquid absorbing heat can flow into the flow collecting shell and then is divided into a plurality of groups of cooling branch pipes through the first dispersion plate, meanwhile, an external industrial air cooler is electrified to work to convey cold air to the conical air guide shell, and then the cold air can be guided into the cooling box body, so that the plurality of groups of cooling branch pipes can be cooled.

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 an energy-saving and environment-friendly cooling device for producing gypsum powder according to the present invention;

FIG. 2 is a front sectional view of a circulating cooling assembly in an energy-saving and environment-friendly cooling device for gypsum powder production according to the present invention;

FIG. 3 is an enlarged view of A in FIG. 2;

in the figure: 1-cooling box body, 11-liquid feeding pipe, 2-water discharging valve, 3-circulating cooling component, 4-box cover plate, 31-circulating pump, 32-maintenance baffle, 33-plate type ultrafiltration membrane, 34-microporous ceramic filter plate, 35-flow guide shell, 36-second dispersion plate, 37-cooling branch pipe, 38-protective ventilation screen plate, 39-first dispersion plate, 311-flow collecting shell and 312-conical air guide shell.

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. 1-3, the present invention provides a technical solution: the utility model provides an energy-concerving and environment-protective type cooling device for gesso production, includes cooling box 1, drain valve 2, circulative cooling subassembly 3 and case lid board 4, and case lid board 4 is installed to 1 up end of cooling box, and drain valve 2 is installed to 1 right-hand member face downside of cooling box, and 1 inside circulative cooling subassembly 3 that is provided with of cooling box.

The circulating cooling component 3 comprises a circulating pump 31, an overhaul baffle 32, a plate-type ultrafiltration membrane 33, a microporous ceramic filter plate 34, a flow guide shell 35, a second dispersion plate 36, a cooling branch pipe 37, a protective ventilation screen plate 38, a first dispersion plate 39, a flow collecting shell 311 and a conical air guide shell 312, the circulating pump 31 is assembled on the lower side of the left end face of the cooling box body 1, the microporous ceramic filter plate 34 is plugged in the lower side of the inside of the cooling box body 1, the plate-type ultrafiltration membrane 33 is plugged in the lower side of the microporous ceramic filter plate 34, the overhaul baffle 32 is installed on the lower side of the right end face of the cooling box body 1, the protective ventilation screen plate 38 is installed on the upper side of the right end face of the cooling box body 1, the conical air guide shell 312 is welded on the upper side of the left end face of the cooling box body 1, the first dispersion plate 39 is installed on the lower end face of the box cover plate 4, the flow collecting shell 311 is arranged on the upper end face of the first dispersion plate 39, and the cooling branch pipe 37 is welded on the lower end face of the first dispersion plate 39, the lower terminal surface welding of cooling branch pipe 37 has second dispersion dish 36, and the lower terminal surface welding of second dispersion dish 36 has water conservancy diversion casing 35, and this design has solved that original gypsum powder is not good enough with cooling structure cooling effect to the problem that cooling pipeline blockked up easily.

The liquid feeding pipe 11 is welded on the lower side of the left end face of the cooling box body 1, the observation window is arranged on the lower side of the front end face of the cooling box body 1, the liquid feeding pipe 11 is convenient to pour a proper amount of cooling liquid into the lower side of the interior of the cooling box body 1, and the observation window is convenient for workers to observe the liquid level height of the cooling liquid in the interior of the cooling box body 1.

The cooling branch pipes 37 are welded in a plurality of groups in an equal-specification mode, the groups of cooling branch pipes 37 are communicated with the first dispersion disc 39 and the second dispersion disc 36 respectively, and the groups of cooling branch pipes 37 are convenient for rapidly dissipating heat and reducing temperature of the cooling liquid after absorbing heat.

Toper wind-guiding shell 312 is connected with external industry air-cooler air-out end through the heat preservation pipeline, drain valve 2 is connected with external waste water treatment pond entry through the pipeline, toper wind-guiding shell 312 conveniently carries air conditioning to the inside upside of cooling box 1, so as to cool down multiunit cooling branch 37, and drain valve 2 conveniently discharges the inside coolant liquid of cooling box 1 and changes, mass flow shell 311 is connected with the coolant liquid export in the external cooling machine through the pipeline, circulating pump 31 is connected with the coolant liquid entry in the external cooling machine through the pipeline, circulating pump 31 is connected with external control switch through the wire, mass flow shell 311 conveniently leads the coolant liquid after the heat absorption to in first dispersion dish 39, and circulating pump 31 conveniently carries the coolant liquid to the external cooling machine, so as to cool down inside gesso.

Overhaul baffle 32, case apron 4, first dispersion dish 39 and protection ventilation otter board 38 are detachable construction, overhaul baffle 32 and conveniently carry out the dismouting to board-like milipore filter 33 and micropore ceramic filter 34, case apron 4 conveniently carries out the dismouting to first dispersion dish 39 to conveniently wash multiunit cooling branch pipe 37, and protection ventilation otter board 38 conveniently will cool off 1 inside air discharge of box to the outside, avoid cooling 1 inside production of heat of box to pile up.

As an embodiment of the present invention: the working personnel firstly pour a proper amount of cooling liquid into the lower side of the interior of the cooling box body 1 through the liquid feeding pipe 11, then the circulating pump 31 and the external industrial air cooler can be respectively started, at the moment, the circulating pump 31 can be electrified and rotated to generate suction force to convey the cooling liquid in the cooling box body 1 into the external cooling machine so as to cool the gypsum powder in the interior, and the cooling liquid absorbing heat can flow into the collecting shell 311 and then is shunted to the multiple groups of cooling branch pipes 37 through the first dispersion disc 39; meanwhile, the external industrial air cooler is electrified to work to convey cold air to the conical air guide shell 312, then the cold air is guided to the interior of the cooling box body 1, so that the plurality of groups of cooling branch pipes 37 are cooled, the temperature of the cooling liquid in the cooling branch pipes 37 is reduced, then the cooling liquid flows through the second dispersion disc 36 to enter the air guide shell 35, then the air guide shell 35 concentrates the cooling liquid to flow downwards to the lower side to be subjected to primary filtration by the microporous ceramic filter plate 34, and then secondary filtration is performed by the plate-type ultrafiltration membrane 33, so that insoluble impurities in the cooling liquid are blocked, the blocking condition of the inner wall of the cooling branch pipe 37 is avoided, and the cooling liquid subjected to secondary filtration flows into the lower side of the interior of the cooling box body 1 again to be recycled, so that the usage amount of the cooling liquid is reduced; in the later stage use, tear down maintenance baffle 32 alright take plate-type milipore filter 33 and micropore ceramic filter 34 out and wash or change, and open drain valve 2 alright change with the inside coolant liquid discharge of cooling tank 1.

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 (6)

1. The utility model provides an energy-concerving and environment-protective type cooling device for gesso production, includes cooling box, drain valve, circulative cooling subassembly and case lid board, its characterized in that: a box cover plate is arranged on the upper end face of the cooling box body, a drain valve is arranged on the lower side of the right end face of the cooling box body, and a circulating cooling assembly is arranged in the cooling box body;

the circulating cooling assembly comprises a circulating pump, an overhauling baffle, a plate-type ultrafiltration membrane, a microporous ceramic filter plate, a flow guide shell, a second dispersion plate, a cooling branch pipe, a protective ventilation screen plate, a first dispersion plate, a flow collection shell and a conical air guide shell, wherein the circulating pump is assembled at the lower side of the left end face of the cooling box body, the microporous ceramic filter plate is stuffed in the lower side of the inner part of the cooling box body, the plate-type ultrafiltration membrane is stuffed in the lower side of the microporous ceramic filter plate, the overhauling baffle is installed at the lower side of the right end face of the cooling box body, the protective ventilation screen plate is installed at the upper side of the right end face of the cooling box body, the conical air guide shell is welded at the upper side of the left end face of the cooling box body, the first dispersion plate is installed at the lower end face of the box cover plate, the flow collection shell is arranged at the upper end face of the first dispersion plate, the cooling branch pipe is welded at the lower end face of the cooling branch pipe, and a flow guide shell is welded on the lower end face of the second dispersion disc.

2. The energy-saving and environment-friendly cooling device for producing the gypsum powder as claimed in claim 1, is characterized in that: the welding of cooling box left end face downside has the liquid pipe of throwing, the observation window is installed to terminal surface downside before the cooling box.

3. The energy-saving and environment-friendly cooling device for producing the gypsum powder as claimed in claim 1, is characterized in that: the cooling branch pipes are welded in an equal-specification mode to form multiple groups, and the multiple groups of cooling branch pipes are communicated with the first dispersion disc and the second dispersion disc respectively.

4. The energy-saving and environment-friendly cooling device for producing the gypsum powder as claimed in claim 1, is characterized in that: the conical air guide shell is connected with an air outlet end of an external industrial air cooler through a heat insulation pipeline, and the drain valve is connected with an inlet of an external wastewater treatment pool through a pipeline.

5. The energy-saving and environment-friendly cooling device for producing the gypsum powder as claimed in claim 1, is characterized in that: the flow collecting shell is connected with a cooling liquid outlet in an external cooler through a pipeline, the circulating pump is connected with a cooling liquid inlet in the external cooler through a pipeline, and the circulating pump is connected with an external control switch through a lead.

6. The energy-saving and environment-friendly cooling device for producing the gypsum powder as claimed in claim 1, is characterized in that: the maintenance baffle, the box cover plate, the first dispersion disc and the protective ventilation screen plate are all of detachable structures.

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