CN115235198B - Washing and drying device based on waste glass fiber recovery - Google Patents

Abstract

The invention relates to a washing and drying device, in particular to a washing and drying device based on waste glass fiber recovery. The washing and drying device based on waste glass fiber recovery, which can recover the filtered glass fibers through the screen, prevents material waste, is provided. Washing drying device based on useless glass fiber is retrieved, including washing frame, electronic conveying component, water injection pipe, stoving mechanism and recovery mechanism, washing frame top is connected with electronic conveying component, and electronic conveying component top is connected with three water injection pipe, and washing frame left side is equipped with the stoving mechanism that is used for drying glass fiber, is equipped with on the washing frame and is used for collecting recovery mechanism to the waste material. According to the invention, the heat air flow generated in the air heater is guided into the drying box through the air pump, so that the effect of recovering and drying is achieved, the glass fiber is further collected by the screen mesh, and the waste of materials is prevented.

Description

Washing and drying device based on waste glass fiber recovery

Technical Field

The invention relates to a washing and drying device, in particular to a washing and drying device based on waste glass fiber recovery.

Background

The glass fiber is an artificial inorganic fiber, adopts natural ores such as quartz sand, limestone, dolomite and the like as main raw materials, and is matched with chemical raw materials such as sodium carbonate, borax and the like to be melted into glass, and is blown by external force to be thrown into flocculent fine fibers in a melted state, so that the glass cotton can be regarded as a porous material, has good heat insulation, sound absorption and sound insulation performances, and can take away more glass fibers containing water and organic matters to form waste cotton in the production and manufacturing process of the glass cotton.

Therefore, a washing and drying device based on waste glass fiber recovery, which can recover the filtered glass fibers through a screen and prevent material waste, is developed.

Disclosure of Invention

In order to overcome the defect that the existing device is mostly buried as solid waste in treatment mode, the invention aims to provide a flushing and drying device based on waste glass fiber recovery, which can recover filtered glass fibers through a screen and prevent material waste.

The technical scheme is as follows: washing drying device based on useless glass fiber is retrieved, including washing frame, electronic conveying component, water injection pipe, stoving mechanism and recovery mechanism, washing frame top is connected with electronic conveying component, and electronic conveying component top is connected with three water injection pipe, and washing frame left side is equipped with the stoving mechanism that is used for drying glass fiber, is equipped with on the washing frame and is used for collecting recovery mechanism to the waste material.

As the improvement of above-mentioned scheme, stoving mechanism is including stoving case, air guide pipe support, air pump, air heater and take out the board, and the welding of washing frame left portion has the stoving case, is connected with the air guide pipe support between the stoving case left and right sides, and stoving bottom of the case portion slidingtype is connected with takes out the board, and the stoving case rear side has the air pump through bolted connection, and the stoving case rear side is connected with air heater.

As the improvement of above-mentioned scheme, retrieve the mechanism including first sliding sleeve, support frame, screen cloth and first compression spring, wash the inside front and back both sides of frame and all be connected with first sliding sleeve, sliding type is connected with the support frame between the first sliding sleeve, and the support frame top is connected with the screen cloth, is connected with the first compression spring of fore-and-aft symmetry between first sliding sleeve and the support frame, and first compression spring is all around on the support frame.

As the improvement of above-mentioned scheme, still including feed divider, feed divider is including dividing material pole, bull stick, drive wheel and belt, and stoving incasement upper portion rotation is connected with three feed divider, and the feed divider front portion all is connected with the drive wheel, and downside drive wheel front side is connected with the bull stick, winds between the drive wheel has the belt.

As the improvement of above-mentioned scheme, still including quantitative mechanism, quantitative mechanism is including electric putter, rotating turret, apron and torsion spring, and electric putter has been passed through bolted connection to electric conveying assembly left part upside, and electric conveying assembly left part upside welding has the rotating turret, and the rotation is connected with the apron on the rotating turret, is connected with the torsion spring of fore-and-aft symmetry between apron and the rotating turret, and torsion spring all winds on the rotating turret.

As the improvement of above-mentioned scheme, still including circulation mechanism, circulation mechanism is connected with the guide rail of fore-and-aft symmetry including guide rail, water pump, back flow and flow distribution plate in the washing frame, and sliding connection has the flow distribution plate between the guide rail, and the upper side of the right part in the washing frame is connected with the water pump through the bolt, is connected with the back flow between water pump and the electronic conveying component.

As the improvement of above-mentioned scheme, still including anti-clogging mechanism, anti-clogging mechanism is including second sliding sleeve, scrape pole, ejector pin and second compression spring, washes the frame front portion and is connected with the second sliding sleeve, and sliding connection has the pole of scraping on the second sliding sleeve, scrapes the pole left side and is connected with the ejector pin, is connected with the second compression spring between ejector pin and the second sliding sleeve, and the second compression spring winds on scraping the pole.

As an improvement of the scheme, the distributing rods are distributed in an inverted triangle shape, so that batch discharging is facilitated.

The invention has the advantages that: 1. according to the invention, the heat air flow generated in the air heater is guided into the drying box through the air pump, so that the effect of recovering and drying is achieved, the glass fiber is further collected by the screen mesh, and the waste of materials is prevented.

2. According to the invention, the rotating rod is rotated, so that the three material distribution rods are rotated, the effect of drying glass fibers in batches is achieved, and the reduction of drying efficiency caused by the fact that glass fibers are fully accumulated and dried is avoided.

3. According to the invention, the opening at the left side of the electric conveying assembly is blocked by the cover plate, so that people can control the amount of glass fibers entering the drying box each time, and further the drying recovery efficiency is improved.

4. The water pump is used for recycling the water at the bottom in the flushing rack, so that excessive waste of water resources is avoided, and the utilization efficiency of the water resources is improved.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of a first perspective structure of the drying mechanism of the present invention.

Fig. 3 is a schematic view of a second perspective structure of the drying mechanism of the present invention.

Fig. 4 is a schematic perspective view of a first embodiment of the recovery mechanism of the present invention.

Fig. 5 is a schematic view showing a second perspective structure of the recovery mechanism of the present invention.

Fig. 6 is a schematic perspective view of a material distributing mechanism according to the present invention.

FIG. 7 is a schematic perspective view of the quantitative mechanism of the present invention.

Fig. 8 is a schematic perspective view of a circulation mechanism according to the present invention.

Fig. 9 is a schematic view of a first perspective structure of the anti-clogging mechanism of the present invention.

Fig. 10 is a schematic view of a second perspective of the anti-clogging mechanism of the present invention.

Reference numerals in the figures: 1. the washing rack, 2, the electric conveying component, 3, the water injection pipe, 4, the drying mechanism, 41, the drying box, 42, the air guide pipe rack, 43, the air pump, 44, the air heater, 45, the drawing plate, 5, the recovery mechanism, 51, the first sliding sleeve, 52, the supporting frame, 53, the screen, 54, the first compression spring, 6, the material distributing mechanism, 61, the material distributing rod, 62, the rotating rod, 63, the driving wheel, 64, the belt, 7, the quantitative mechanism, 71, the electric push rod, 72, the rotating rack, 73, the cover plate, 74, the torsion spring, 8, the circulation mechanism, 81, the guide rail, 82, the water pump, 83, the return pipe, 84, the splitter plate, 9, the anti-blocking mechanism, 91, the second sliding sleeve, 92, the scraping rod, 93, the push rod, 94 and the second compression spring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

The utility model provides a wash drying device based on useless glass fiber retrieves, as shown in FIG. 1, including washing frame 1, electronic conveying component 2, water injection pipe 3, drying mechanism 4 and recovery mechanism 5, washing frame 1 top is connected with electronic conveying component 2, a used for carrying useless glass fiber, electronic conveying component 2 is including servo motor, screw conveyer pole and conveyer pipe, the conveyer pipe is connected in washing frame 1 upper portion, screw conveyer pole is connected with the conveyer pipe rotation, servo motor connects on the conveyer pipe right side, servo motor output shaft is connected with screw conveyer pole, electronic conveying component 2 top is connected with three water injection pipe 3, be used for introducing rivers, washing frame 1 left side is equipped with and is used for carrying out the stoving mechanism 4 to glass fiber, be equipped with on washing frame 1 and be used for collecting the recovery mechanism 5 of waste material.

As shown in fig. 1-3 and fig. 6, the drying mechanism 4 comprises a drying box 41, an air guide pipe frame 42, an air pump 43, an air heater 44 and a drawing plate 45, the left part of the flushing frame 1 is welded with the drying box 41, the air guide pipe frame 42 is connected between the left side and the right side of the drying box 41, the bottom of the drying box 41 is connected with the drawing plate 45 in a sliding manner, the rear side of the drying box 41 is connected with the air pump 43 through a bolt, the air pump 43 is connected with the air guide pipe frame 42, the rear side of the drying box 41 is connected with the air heater 44 for heating, the air heater 44 is positioned at the left side of the air pump 43, and the air heater 44 is connected with the air pump 43.

As shown in fig. 1, fig. 4 and fig. 5, the recovery mechanism 5 comprises a first sliding sleeve 51, a supporting frame 52, a screen 53 and a first compression spring 54, the front side and the rear side of the inside of the flushing frame 1 are respectively connected with the first sliding sleeve 51, the supporting frame 52 is connected between the first sliding sleeves 51 in a sliding manner, the top of the supporting frame 52 is connected with the screen 53 for collecting filtered impurities, the first compression springs 54 which are symmetrical front and rear are connected between the first sliding sleeve 51 and the supporting frame 52, the first compression springs 54 are wound on the supporting frame 52, and the first compression springs 54 play a buffering and resetting role on the supporting frame 52.

Waste glass is limited and poured into the electric conveying assembly 2, clean water is added into the conveying pipe through the water injection pipe 3, the servo motor is started immediately, the threaded conveying rod rotates, so that waste glass fibers continuously move leftwards in the flushing process, at the moment, smaller impurities and part of glass fibers can fall onto the screen 53 through the conveying pipe under the drive of water flow, meanwhile, along with the continuous rotation of the threaded conveying rod, the glass fibers can flow out of the outlet at the left end of the conveying pipe and fall into the drying box 41, the air heater 44 and the air pump 43 are started, the air pump 43 can enable hot air flow generated by the air heater 44 to enter the drying box 41 through the air guide pipe frame 42, so that the glass fibers in the drying box 41 are dried, after the drying is finished, the air heater 44 and the air pump 43 are closed, the drawing plate 45 is drawn out, the dried glass fibers are taken out, the drawing plate 45 is pushed back to reset, the screen 53 is pushed left and right, the support frame 52 slides left and right, and then the first compression spring 54 is in a forced compression and reset state, so that impurities on the screen 53 are screened out and fall off, the glass fibers remained on the screen 53 are recovered, the electric conveying assembly 2 is closed, the injection of clear water is stopped, and in sum, the air pump 43 is used for guiding the heat air flow generated in the air heater 44 into the drying box 41, so that the effect of recovering and drying is achieved, and the glass fibers are further collected through the screen 53, so that the material waste is prevented.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and 6, the automatic feeding and discharging device further comprises a feeding mechanism 6, wherein the feeding mechanism 6 comprises feeding rods 61, rotating rods 62, driving wheels 63 and a belt 64, three feeding rods 61 are rotatably connected to the upper portion in a drying box 41 and used for enabling materials to fall off in batches, the feeding rods 61 are distributed in an inverted triangle shape and are convenient for batch discharging, driving wheels 63 are connected to the front portions of the feeding rods 61, the front sides of the lower driving wheels 63 are connected with the rotating rods 62, and the belt 64 is wound between the driving wheels 63 and used for enabling the feeding rods 61 to synchronously rotate.

As the water flow brings the glass fibers into the drying box 41, a large amount of glass fibers are blocked by the material distributing rods 61, after the air heater 44 is started, the glass fibers and the water flow are dried under the action of hot air flow guided out by the air guide pipe frame 42, moisture evaporates through the top of the drying box 41, then the rotating rod 62 is rotated, so that the lower material distributing rods 61 rotate, the lower driving wheel 63 rotates, under the action of the driving wheel 63 and the belt 64, the three material distributing rods 61 rotate, the dried glass fibers are thrown off, the drawing plate 45 can be drawn out after the glass fibers fall off, the dried glass fibers are taken out, the drawing plate 45 is pushed back to reset after being taken out, and then the rotating rod 62 is continuously rotated after the next glass fibers fall into.

As shown in fig. 1 and 7, the quantitative device 7 is further included, the quantitative device 7 includes an electric push rod 71, a rotating frame 72, a cover plate 73 and a torsion spring 74, the upper side of the left part of the electric conveying component 2 is connected with the electric push rod 71 through a bolt, the rotating frame 72 is welded on the upper side of the left part of the electric conveying component 2, the rotating frame 72 is located on the left side of the electric push rod 71, the cover plate 73 is rotatably connected with the cover plate 73, the cover plate 73 can block the left opening of the electric conveying component 2, the electric push rod 71 can be in contact with the cover plate 73, the torsion spring 74 which is symmetrical around is connected between the cover plate 73 and the rotating frame 72, the torsion spring 74 is wound on the rotating frame 72, and the torsion spring 74 plays a buffering and resetting role on the cover plate 73.

In order to avoid disposable stoving a large amount of glass fiber for drying efficiency slows down, consequently, need carry out the separation at electric conveying component 2 left side opening, make glass fiber batch entering stoving case 41 carry out the stoving, this moment need people pile up after a certain degree at glass fiber, start electric putter 71, thereby make electric putter 71 promote apron 73 left, apron 73 receives electric putter 71's promotion clockwise rotation to open, torsion spring 74 all atress deformation, at this moment glass fiber no longer receives the blocking, after right amount glass fiber gets into the stoving, control electric putter 71 shrink reset, thereby under torsion spring 74's effect, cover 73 anticlockwise rotation resets, in sum up, carry out the separation through apron 73 to electric conveying component 2 left side opening, make people can control the amount of glass fiber that gets into stoving case 41 at every turn, and then improved stoving recovery's efficiency.

As shown in fig. 1 and 8, the water-saving flushing device further comprises a circulating mechanism 8, wherein the circulating mechanism 8 comprises guide rails 81, a water pump 82, a return pipe 83 and a flow dividing plate 84, the guide rails 81 which are symmetrical in front and back are connected to the bottom in the flushing frame 1, the flow dividing plate 84 is connected between the guide rails 81 in a sliding mode and used for blocking sundries, the water pump 82 is connected to the upper side of the right portion in the flushing frame 1 through bolts, and the return pipe 83 is connected between the water pump 82 and the electric conveying assembly 2 and used for guiding water flow in the flushing frame 1.

In order to improve the utilization ratio of water resources, along with a large amount of rivers get into in washing frame 1, people can start water pump 82 for water pump 82 is with the rivers in washing frame 1 in pumping back pipe 83, later send into in the electronic conveying assembly 2 by back pipe 83, accomplish cyclic utilization of water resources, in the operation of water pump 82, in order to prevent debris jam water pump 82, people can promote flow distribution plate 84 to the left, make debris around water pump 82 be obstructed, after the operation finishes, close water pump 82, in sum, carry out recycle with the water of washing frame 1 inner bottom through water pump 82, avoid too much extravagant of water resources, improve the utilization efficiency of water resources.

As shown in fig. 1, 9 and 10, the anti-blocking mechanism 9 is further included, the anti-blocking mechanism 9 includes a second sliding sleeve 91, a scraping rod 92, a push rod 93 and a second compression spring 94, the front portion of the flushing frame 1 is connected with the second sliding sleeve 91, the scraping rod 92 is connected to the second sliding sleeve 91 in a sliding manner, so that the electric conveying assembly 2 is prevented from being blocked, the push rod 93 is connected to the left side of the scraping rod 92, the push rod 93 can be contacted with the supporting frame 52 and the cover plate 73, the second compression spring 94 is connected between the push rod 93 and the second sliding sleeve 91, the second compression spring 94 is wound on the scraping rod 92, and the second compression spring 94 plays a buffering and resetting role on the scraping rod 92.

As the cover plate 73 rotates clockwise to open, the cover plate 73 pushes the ejector rod 93 to move leftwards, at this time, the ejector rod 93 pushes the supporting frame 52 to slide leftwards, the first compression springs 54 are compressed under force, the supporting frame 52 drives the screen 53 to move leftwards, meanwhile, the scraping rod 92 is driven to slide leftwards along with the ejector rod 93, the second compression springs 94 are compressed under force, the scraping rod 92 can scrape the bottom surface of the electric conveying assembly 2 along with the leftward sliding of the scraping rod 92, the impurities are prevented from blocking and accumulating, the ejector rod 93 loses the thrust of the cover plate 73 along with the anticlockwise rotating reset of the cover plate 73, the scraping rod 92 slides rightwards to reset under the action of the second compression springs 94, meanwhile, the scraping rod 92 drives the ejector rod 93 to move rightwards to reset, the supporting frame 52 loses pushing along with the ejector rod 93 to reset under the action of the first compression springs 54, the screen 53 is driven rightwards to reset by the supporting frame 52, the screen 53 can screen and filter carried sundries and glass fibers in the reciprocating process, and in the above, the impurities are scraped on the surface of the electric conveying assembly 2 through the scraping rod 92, and the blocking of the electric conveying assembly 2 is prevented.

The above embodiments are only preferred embodiments of the present invention and are not intended to limit the scope of the present invention, so that all equivalent modifications made by the appended claims shall be included in the scope of the present invention.

Claims (7)

1. The utility model provides a wash drying device based on useless glass fiber is retrieved, including washing frame (1), electronic conveying component (2) and water injection pipe (3), wash frame (1) top and be connected with electronic conveying component (2), electronic conveying component (2) top is connected with three water injection pipe (3), characterized by, still including stoving mechanism (4) and recovery mechanism (5), wash frame (1) left side and be equipped with stoving mechanism (4) that are used for carrying out stoving to glass fiber, wash and be equipped with on frame (1) and be used for carrying out recovery mechanism (5) that collect to the waste material;

the drying mechanism (4) comprises a drying box (41), an air duct frame (42), an air pump (43), an air heater (44) and a drawing plate (45), wherein the drying box (41) is welded at the left part of the washing frame (1), the air duct frame (42) is connected between the left side and the right side of the drying box (41), the bottom of the drying box (41) is connected with the drawing plate (45) in a sliding manner, the air pump (43) is connected to the rear side of the drying box (41) through bolts, and the air heater (44) is connected to the rear side of the drying box (41).

2. The washing and drying device based on waste glass fiber recovery of claim 1, wherein the recovery mechanism (5) comprises a first sliding sleeve (51), a supporting frame (52), a screen (53) and a first compression spring (54), the first sliding sleeve (51) is connected to the front side and the rear side of the inside of the washing frame (1), the supporting frame (52) is connected between the first sliding sleeves (51) in a sliding mode, the screen (53) is connected to the top of the supporting frame (52), the first compression spring (54) which is symmetrical in the front-back mode is connected between the first sliding sleeve (51) and the supporting frame (52), and the first compression spring (54) is wound on the supporting frame (52).

3. The washing and drying device based on waste glass fiber recovery, as claimed in claim 2, further comprising a distributing mechanism (6) for batch drying glass fibers, wherein the distributing mechanism (6) comprises a distributing rod (61), a rotating rod (62), a driving wheel (63) and a belt (64), three distributing rods (61) are rotatably connected to the upper part in the drying box (41), driving wheels (63) are connected to the front parts of the distributing rods (61), a rotating rod (62) is connected to the front side of the lower driving wheel (63), and the belt (64) is wound between the driving wheels (63).

4. The washing and drying device based on waste glass fiber recovery as claimed in claim 3, further comprising a quantifying mechanism (7) for limiting the quantity of discharged materials, wherein the quantifying mechanism (7) comprises an electric push rod (71), a rotating frame (72), a cover plate (73) and a torsion spring (74), the electric push rod (71) is connected to the upper left side of the electric conveying assembly (2) through bolts, the rotating frame (72) is welded to the upper left side of the electric conveying assembly (2), the cover plate (73) is rotatably connected to the rotating frame (72), the torsion springs (74) which are symmetrical in front-back mode are connected between the cover plate (73) and the rotating frame (72), and the torsion springs (74) are wound on the rotating frame (72).

5. The washing and drying device based on waste glass fiber recovery of claim 4, further comprising a circulating mechanism (8) for recycling water resources, wherein the circulating mechanism (8) comprises a guide rail (81), a water pump (82), a return pipe (83) and a flow dividing plate (84), the guide rail (81) which is symmetrical in front and back is connected to the inner bottom of the washing frame (1), the flow dividing plate (84) is connected between the guide rails (81) in a sliding manner, the water pump (82) is connected to the upper side of the right part in the washing frame (1) through bolts, and the return pipe (83) is connected between the water pump (82) and the electric conveying assembly (2).

6. The washing and drying device based on waste glass fiber recovery, as claimed in claim 5, further comprising an anti-blocking mechanism (9) for scraping sundries, wherein the anti-blocking mechanism (9) comprises a second sliding sleeve (91), a scraping rod (92), a push rod (93) and a second compression spring (94), the second sliding sleeve (91) is connected to the front part of the washing frame (1), the scraping rod (92) is connected to the second sliding sleeve (91) in a sliding manner, the push rod (93) is connected to the left side of the scraping rod (92), the second compression spring (94) is connected between the push rod (93) and the second sliding sleeve (91), and the second compression spring (94) is wound on the scraping rod (92).

7. The washing and drying device based on waste glass fiber recovery according to claim 6, wherein the distributing rods (61) are distributed in an inverted triangle shape, so that batch discharging is facilitated.

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