CN213918791U - Anti-pollution forming device for processing nanometer non-resin combined MgO-C bricks - Google Patents

Abstract

The utility model discloses an anti-pollution nanometer non-resin combines forming device for MgO-C brick processing, including base, first motor, solenoid valve and second motor, the discharge gate has been seted up on the base, and embedded the installing first motor in the base to the output of first motor is connected with the shaping dish, the embedded movable mounting of shaping dish has seted up the shaping groove in the top of base, and runs through on the shaping dish, the top edge bolt fastening of base has the support, and runs through on the support and install the feeder hopper, the top bolt fastening of support has the second motor, the lower extreme at support top is fixed with the guide post, the guide arm with lead and be provided with the push rod between the fluted disc. This forming device is used in processing of anti-pollution nanometer non-resin combination MgO-C brick realizes automatic compounding unloading, press forming and the ejection of compact operation that lasts, strikes off the material in the feeder hopper simultaneously, avoids the material adhesion.

Description

Anti-pollution forming device for processing nanometer non-resin combined MgO-C bricks

Technical Field

The utility model relates to a MgO-C brick processing technology field specifically is an anti-pollution nanometer non-resin combines forming device for MgO-C brick processing.

Background

The conventional MgO-C brick mainly takes magnesite (such as sintered or fused magnesite) and a carbon source (such as graphite, carbon black and the like) as raw materials, resin, asphalt or tar and the like as a binding agent, and the mixture is pressed and formed by a forming device, but the resin raw materials are used as the binding agent to generate pollution in the process of preparing the MgO-C brick, in the prior art, a nanometer non-resin material is used as the binding agent to effectively reduce the pollution, but the prior forming device has the following problems in use:

when the forming device is used for processing the MgO-C bricks, the existing forming device is inconvenient for mixing and synchronously discharging raw materials, time and labor are wasted due to the adoption of premixing, and meanwhile, when the MgO-C bricks are processed, the existing forming device is inconvenient for synchronously discharging, pressing and discharging, and the processing efficiency is low.

In order to solve the above problems, innovative design based on the original forming device is urgently needed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an anti-pollution nanometer non-resin combines forming device for MgO-C brick processing to solve above-mentioned background art and propose current forming device, inconvenient mix and the synchronous unloading to the raw materials, simultaneously inconvenient carry out the problem of synchronous unloading, suppression and ejection of compact operation.

In order to achieve the above object, the utility model provides a following technical scheme: an anti-pollution forming device for processing nanometer non-resin combined MgO-C bricks comprises a base, a first motor, a solenoid valve and a second motor, wherein a discharge port is formed in the base, the first motor is embedded in the base, the output end of the first motor is connected with a forming disc, the forming disc is movably installed at the top of the base in an embedded mode, a forming groove is formed in the forming disc in a penetrating mode, a support is fixed to the edge of the top of the base through bolts, a feed hopper is installed on the support in a penetrating mode, the solenoid valve is arranged at the bottom of the feed hopper, the second motor is fixed to the top of the support through bolts, the output end of the second motor is connected with a guide gear disc, the guide gear disc is connected to the inside of the top of the support in an embedded mode through a shaft, a limiting column is fixed to the lower end of the top of the support, a guide rod is arranged in the limiting column, and a push rod is arranged between the guide gear disc and the guide rod, and the push rod is connected with the guide rod and the guide fluted disc through universal ball connecting pieces, and the bottom of the guide rod penetrates through the limiting column and is welded with the pressing plate.

Preferably, the embedded movable fluted disc of having placed of feeder hopper, and the upper and lower both ends of movable fluted disc all are fixed with the holding ring to the holding ring is located the constant head tank, and the inside at the feeder hopper is seted up to the constant head tank moreover, install the puddler in the holding ring, and the outside of puddler is fixed with the scraper blade.

Preferably, the push rod forms a rotating structure with the guide fluted disc and the guide rod through the universal ball connecting piece, and the guide rod and the guide fluted disc are eccentrically arranged.

Preferably, the pressing plate and the feeding hopper are circumferentially distributed on the support, and the pressing plate and the feeding hopper correspond to the distribution positions of the forming grooves.

Preferably, the movable fluted disc and the guide fluted disc are meshed with each other, and 2 guide fluted discs are symmetrically arranged on the central axis of the forming disc.

Preferably, the positioning ring is attached to the positioning groove in a rotating mode, and the positioning groove and the movable gear plate share the same central axis.

Compared with the prior art, the beneficial effects of the utility model are that: the anti-pollution forming device for processing the nanometer non-resin combined MgO-C brick;

1. through the meshing contact of the two guide fluted discs and the movable fluted disc, when the second motor drives the guide fluted disc to rotate, the two guide fluted discs synchronously move under the guiding action of the movable fluted disc, further, the reciprocating up-and-down movement of the guide rod and the pressing plate is realized under the guiding action of the universal ball connecting piece and the push rod, and the continuous blanking, pressing and discharging operations are realized through the contact of the pressing plate and the forming groove on the forming disc and the matching of the use of the feeding hopper;

2. through puddler and the scraper blade of setting on the activity fluted disc, when lasting unloading, suppression and ejection of compact operation, can drive the rotation of puddler and scraper blade through the activity fluted disc, continuously stir and scrape the material in the feeder hopper.

Drawings

FIG. 1 is a schematic view of a front cross-sectional structure of the present invention;

FIG. 2 is a schematic view of a top view of the forming plate of the present invention;

FIG. 3 is a schematic view of the cross-sectional structure of the bracket of the present invention from above;

FIG. 4 is an enlarged schematic view of the structure at A of FIG. 1 according to the present invention;

FIG. 5 is a schematic top view of the movable gear of the present invention;

fig. 6 is a schematic view of the top view cross-sectional structure of the guide rod of the present invention.

In the figure: 1. a base; 2. a discharge port; 3. a first motor; 4. forming a disc; 5. forming a groove; 6. a support; 7. a feed hopper; 8. an electromagnetic valve; 9. a second motor; 10. a gear guide disc; 11. a universal ball connection; 12. a push rod; 13. a guide bar; 14. a limiting column; 15. pressing a plate; 16. a movable fluted disc; 17. a positioning ring; 18. positioning a groove; 19. a stirring rod; 20. a scraper.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: an anti-pollution forming device for processing a nanometer non-resin combined MgO-C brick comprises a base 1, a discharge port 2, a first motor 3, a forming disc 4, a forming groove 5, a support 6, a feed hopper 7, an electromagnetic valve 8, a second motor 9, a guide fluted disc 10, a universal ball connecting piece 11, a push rod 12, a guide rod 13, a limit column 14, a pressing plate 15, a movable fluted disc 16, a positioning ring 17, a positioning groove 18, a stirring rod 19 and a scraper 20, wherein the discharge port 2 is arranged on the base 1, the first motor 3 is embedded in the base 1, the output end of the first motor 3 is connected with the forming disc 4, the forming disc 4 is embedded and movably arranged at the top of the base 1, the forming groove 5 is arranged on the forming disc 4 in a penetrating way, the support 6 is fixed at the edge of the top of the base 1 through a bolt, the feed hopper 7 is arranged on the support 6 in a penetrating way, and the electromagnetic valve 8 is arranged at the bottom of the feed hopper 7, the top bolt fastening of support 6 has second motor 9, and the output of second motor 9 is connected with guide gear dish 10, and the embedded axle of guide gear dish 10 is connected in the inside at support 6 top, the lower extreme at support 6 top is fixed with spacing post 14, and place guide arm 13 in spacing post 14, be provided with push rod 12 between guide arm 13 and the guide gear dish 10, and be connected through universal ball connecting piece 11 between push rod 12 and guide arm 13 and the guide gear dish 10, and the bottom of guide arm 13 runs through spacing post 14 welding and has clamp plate 15.

A movable fluted disc 16 is embedded in the feed hopper 7, positioning rings 17 are fixed at the upper end and the lower end of the movable fluted disc 16, and a positioning ring 17 is positioned in a positioning groove 18, and the positioning groove 18 is opened in the feed hopper 7, a stirring rod 19 is installed in the positioning ring 17, and the outer side of the stirring rod 19 is fixed with a scraper 20, the movable fluted disc 16 is meshed with the guide fluted disc 10, and 2 guide toothed discs 10 are symmetrically arranged about the central axis of the forming disc 4, when the second motor 9 drives the guide toothed disc 10 to rotate, the guide toothed disc 10 drives the movable toothed disc 16 to rotate in the feed hopper 7, further, the 2 guide fluted discs 10 and the movable fluted disc 16 rotate simultaneously, and materials in the feed hopper 7 are stirred and scraped through the stirring rod 19 and the scraper 20 at the bottom of the movable fluted disc 16, so that the materials are mixed sufficiently, and the materials are prevented from being adhered to the inner wall of the feed hopper 7;

the push rod 12 forms a rotating structure with the guide fluted disc 10 and the guide rod 13 through the universal ball connecting piece 11, the guide fluted disc 10 and the guide rod 13 are eccentrically arranged, and when the second motor 9 drives the guide fluted disc 10 to rotate, the guide rod 13 can reciprocate up and down in the limiting column 14 under the action of the universal ball connecting piece 11 and the push rod 12;

the pressing plates 15 and the feed hoppers 7 are circumferentially distributed on the bracket 6, the pressing plates 15 and the feed hoppers 7 correspond to the distribution positions of the forming grooves 5, firstly, materials are guided into the forming grooves 5 through the feed hoppers 7, the materials in the forming grooves 5 are pressed and formed through one pressing plate 15, then, the formed brick body is pushed out through the forming grooves 5 and the discharge hole 2 through the other pressing plate 15, and the operations of blanking, pressing and forming and discharging are completed;

the positioning ring 17 is attached to the positioning groove 18 and is rotationally connected with the positioning groove 18, the positioning groove 18 and the movable fluted disc 16 share a central axis, and when the movable fluted disc 16 rotates in the feed hopper 7, the positioning ring 17 rotates along with the positioning groove 18 to keep the movable fluted disc 16 stably rotating.

The working principle is as follows: when the anti-pollution forming device for processing the nanometer non-resin combined MgO-C bricks is used, as shown in fig. 1 and fig. 4-5, firstly, a material is guided into a feed hopper 7 on a bracket 6, a second motor 9 is started, the second motor 9 drives a guide fluted disc 10 to rotate, the guide fluted disc 10 is meshed with a movable fluted disc 16 to drive the movable fluted disc 16 to rotate in the feed hopper 7, the movable fluted disc 16 drives a stirring rod 19 and a scraper 20 to rotate, the material in the feed hopper 7 is stirred and scraped, and meanwhile, when the movable fluted disc 16 rotates in the feed hopper 7, a positioning ring 17 rotates along with a positioning groove 18 to keep the movable fluted disc 16 to stably rotate;

then, as shown in fig. 1-3 and fig. 6, the first motor 3 on the base 1 is started, the first motor 3 drives the forming disc 4 to rotate in a clearance manner, so that the forming grooves 5 on the forming disc 4 respectively reach the lower parts of the feed hopper 7 and the 2 pressing plates 15, the electromagnetic valve 8 at the bottom of the feed hopper 7 is opened, the material enters the corresponding forming groove 5, then the first motor 3 is started again, the forming groove 5 filled with the material is rotated to the lower part of each pressing plate 15, the second motor 9 drives the guide gear disc 10 to rotate, the guide rod 13 can reciprocate up and down in the limit column 14 under the action of the universal ball connecting piece 11 and the push rod 12, the material in the forming groove 5 is firstly pressed and formed by the pressing plate 15 at the bottom of the guide rod 13, then the first motor 3 is continuously started, and the press-formed forming groove 5 is rotated to the position; under the other press plate 15, the formed MgO-C bricks are pushed out from the discharge port 2 and collected through the up-and-down movement of the press plate 15, and the operations of blanking, pressing and discharging are carried out in sequence according to the operations.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides an anti-pollution nanometer non-resin combines forming device for MgO-C brick processing, includes base (1), first motor (3), solenoid valve (8) and second motor (9), its characterized in that: the automatic feeding device is characterized in that a discharge port (2) is formed in the base (1), a first motor (3) is embedded in the base (1), the output end of the first motor (3) is connected with a forming disc (4), the forming disc (4) is movably installed at the top of the base (1) in an embedded mode, a forming groove (5) is formed in the forming disc (4) in a penetrating mode, a support (6) is fixed to the edge of the top of the base (1) through bolts, a feeding hopper (7) is installed on the support (6) in a penetrating mode, an electromagnetic valve (8) is arranged at the bottom of the feeding hopper (7), a second motor (9) is fixed to the top of the support (6) through bolts, the output end of the second motor (9) is connected with a guide toothed disc (10), the guide toothed disc (10) is connected to the inside of the top of the support (6) in an embedded mode, and a limiting column (14) is fixed to the lower end of the top of the support (6), and place guide arm (13) in spacing post (14), be provided with between guide arm (13) and the guiding fluted disc (10) push rod (12), and be connected through universal ball connecting piece (11) between push rod (12) and guide arm (13) and the guiding fluted disc (10) to the bottom of guide arm (13) is run through spacing post (14) and is welded and is had clamp plate (15).

2. The anti-contamination nano non-resin bonded MgO-C brick molding apparatus according to claim 1, wherein: movable fluted disc (16) have been placed to embedded formula in feeder hopper (7), and the upper and lower both ends of movable fluted disc (16) all are fixed with holding ring (17) to holding ring (17) are located constant head tank (18), and the inside in feeder hopper (7) is seted up in constant head tank (18) moreover, install puddler (19) in holding ring (17), and the outside of puddler (19) is fixed with scraper blade (20).

3. The anti-contamination nano non-resin bonded MgO-C brick molding apparatus according to claim 1, wherein: the push rod (12) forms a rotating structure with the guide gear disc (10) and the guide rod (13) through the universal ball connecting piece (11), and the guide rod (13) and the guide gear disc (10) are eccentrically arranged.

4. The anti-contamination nano non-resin bonded MgO-C brick molding apparatus according to claim 1, wherein: the pressing plate (15) and the feed hopper (7) are circumferentially distributed on the support (6), and the pressing plate (15) and the feed hopper (7) correspond to the distribution positions of the forming grooves (5).

5. The anti-contamination nano non-resin bonded MgO-C brick molding apparatus according to claim 2, wherein: the movable fluted disc (16) and the guide fluted disc (10) are meshed with each other, and 2 guide fluted discs (10) are symmetrically arranged around the central axis of the forming disc (4).

6. The anti-contamination nano non-resin bonded MgO-C brick molding apparatus according to claim 2, wherein: the positioning ring (17) is attached to the positioning groove (18) in a rotating mode, and the positioning groove (18) and the movable gear disc (16) share the same central axis.

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