CN217248919U - Glass fiber reinforced plastic reaction kettle for producing water purification material - Google Patents

Abstract

The utility model discloses a glass steel reation kettle is used in water purification material production, including reation kettle, the reation kettle top is connected with the feeder hopper, the reation kettle top is provided with rabbling mechanism, the last drive mechanism that is provided with of rabbling mechanism, reation kettle is inside to be provided with and to be used for the bulk cargo mechanism of breaing up the raw materials, bulk cargo mechanism is located the feed opening below of feeder hopper, bulk cargo mechanism by drive mechanism drives, reation kettle one side is provided with the sampling mechanism who is convenient for collect the sample. The utility model discloses be provided with bulk cargo mechanism, rotate through rabbling mechanism drive mechanism, drive mechanism drive bulk cargo mechanism rotates for rabbling mechanism and bulk cargo mechanism together operate, when carrying out the unloading, break up the raw materials by bulk cargo mechanism, thereby avoid the quick deposit of solid raw materials in the reation kettle bottom, effectively improve mixing efficiency, and through setting up sampling mechanism and break-make mechanism, be convenient for carry out the sample detection, convenient to use.

Description

Glass fiber reinforced plastic reaction kettle for producing water purification material

Technical Field

The utility model relates to a water purification material production technical field especially relates to a water purification material production is with glass steel reation kettle.

Background

Polyaluminium chloride is an inorganic substance, a novel water purifying material and an inorganic high-molecular coagulant, which is polyaluminium for short, the polyaluminium chloride has high electric neutralization and bridging effects on colloids and particles in water, can strongly remove micro-toxicants and heavy metal ions, has stable properties, a reaction kettle is a chemical container which is used for mixing, stirring and reacting in a production process and is equal to one, the polyaluminium chloride is widely applied to industries such as chemical industry, food, medicine, resin synthesis and the like, the raw materials of the polyaluminium chloride need to be poured into the reaction kettle for mixing and stirring in the production process, a large amount of raw materials are usually poured into the reaction kettle rapidly when the existing reaction kettle is used, so that the solid raw materials can be rapidly deposited at the bottom of the reaction kettle, the fixed raw materials need to be stirred for a longer time when the stirring is carried out, and the raw materials can be uniformly mixed, efficiency is reduced to in order to detect the raw materials degree of mixing, need take a sample, present reation kettle is comparatively inconvenient when taking a sample.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems and provide a glass fiber reinforced plastic reaction kettle for producing water purifying materials.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

the utility model provides a water purification material production is with glass steel reation kettle, includes reation kettle, the reation kettle top is connected with the feeder hopper, the reation kettle top is provided with rabbling mechanism, the last drive mechanism that is provided with of rabbling mechanism, reation kettle is inside to be provided with and to be used for the bulk cargo mechanism broken up the raw materials, bulk cargo mechanism is located the feed opening below of feeder hopper, bulk cargo mechanism by drive mechanism drives, reation kettle one side is provided with the sampling mechanism who is convenient for collect the sample, be provided with in the sampling mechanism and be used for making sampling mechanism with reation kettle intercommunication or the break-make mechanism who blocks.

Preferably, rabbling mechanism includes support, agitator motor, (mixing) shaft, rabbling arm, the support pass through the bolt in the reation kettle top, there is agitator motor at the support top through bolted connection, agitator motor's output shaft stretches into inside and through the coupling joint of reation kettle the (mixing) shaft, the welding has a plurality ofly on the (mixing) shaft the rabbling arm.

So set up, be convenient for the support with agitator motor carries out the dismouting, is convenient for the (mixing) shaft carries out the dismouting.

Preferably, drive mechanism includes gear wheel, pinion, pivot, the gear wheel pass through the key-type connect in on agitator motor's the output shaft, the gear wheel is close to one side meshing of feeder hopper has the pinion, the welding of pinion bottom has the pivot, the pivot bottom stretches into in the reation kettle, the pivot with the reation kettle roof passes through the bearing and connects.

So set up, guarantee that power transmission is steady.

Preferably, bulk cargo mechanism includes magazine, bracing piece, arc net, revolving stage, kickoff pole, the welding of magazine top has the bracing piece, the bracing piece top weld in on the roof in the reation kettle, the magazine is close to one side of (mixing) shaft is provided with the arc net, the bottom wall is connected with through the bearing in the magazine the revolving stage, the welding has a plurality ofly on the revolving stage the kickoff pole, the revolving stage top with the pivot is through the key-type connection.

So set up, utilize the revolving stage is thrown away the raw materials, utilizes the setting aside the material pole with the raw materials is broken up.

Preferably, the sampling mechanism includes a sampling box, a material taking cavity, a material taking pipe and a material discharging pipe, the sampling box is connected to one side of the reaction kettle through bolts, at least two material taking cavities are formed in the sampling box, the material taking pipes with the same number as the material taking cavities are arranged in the sampling box, one end of each material taking pipe is communicated with the inside of the reaction kettle, the material discharging pipe is connected to the bottom of the material taking pipe, and the other end of the material discharging pipe is communicated with the material taking cavity.

So set up, place the sample bottle get the material intracavity and be convenient for take a sample.

Preferably, the on-off mechanism worm, worm wheel, lead screw, sleeve pipe, piston, the worm pass through the bearing connect in sample incasement portion, the worm is close to one side meshing that gets the material chamber has the worm wheel, there is the lead screw through the key connection in the worm wheel, the lead screw is kept away from the pumping pipe one end with sample case lateral wall passes through the bearing and is connected, the lead screw is close to the one end of pumping pipe is in through threaded connection sleeve intraduct, sleeve pipe one end stretches into pumping pipe inside and fixedly connected with the piston, the piston with pumping pipe inner wall is hugged closely.

According to the arrangement, the worm drives the worm wheel to rotate, so that the screw rod drives the sleeve to move, and the piston moves.

Preferably, the on-off mechanism includes a piston, a threaded rod, a threaded block, a driving ring and a push-pull rod, the threaded rod is connected to the inside of the sampling box through a bearing, the threaded rod is connected with the threaded block through threads, one side of the material taking cavity is far away from the threaded block, the inner wall of the sampling box is in sliding connection, the threaded block is close to one side of the material taking cavity, the driving ring is welded to one side of the material taking cavity, one end of the push-pull rod is arranged inside the driving ring, the other end of the push-pull rod extends into the inside of the material taking tube and is fixedly connected with the piston, and the piston is tightly attached to the inner wall of the material taking tube.

The arrangement is that the threaded rod drives the threaded block to move, so that the driving ring drives the push-pull rod to move, and the piston moves.

Preferably, the material of reation kettle is glass steel.

So set up, can effectively prevent that reation kettle from being corroded increase of service life.

Preferably, the turntable is a conical cylinder with a small upper part and a large lower part.

So set up, be convenient for the raw materials by the flied.

Preferably, one side of the sampling box, which is close to the thread block, is provided with a sliding chute connected with the thread block.

So set up, guarantee the screw thread piece can stably reciprocate.

Has the advantages that: the utility model discloses be provided with bulk cargo mechanism, rotate through rabbling mechanism drive mechanism, drive mechanism drive bulk cargo mechanism rotates for rabbling mechanism and bulk cargo mechanism together operate, when carrying out the unloading, break up the raw materials by bulk cargo mechanism, thereby avoid the quick deposit of solid raw materials in the reation kettle bottom, effectively improve mixing efficiency, and through setting up sampling mechanism and break-make mechanism, be convenient for carry out the sample detection, convenient to use.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the invention.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a perspective view of a glass fiber reinforced plastic reaction kettle for producing water purification materials according to the present invention;

FIG. 2 is a right side view of a glass fiber reinforced plastic reaction kettle for producing water purification materials according to the present invention;

FIG. 3 is a front view of the internal structure of a glass fiber reinforced plastic reaction kettle for producing water purification materials according to the present invention;

FIG. 4 is a perspective view of a material dispersing mechanism of a glass fiber reinforced plastic reaction kettle for producing water purification materials according to the present invention;

FIG. 5 is a front view of a material dispersing mechanism of a glass fiber reinforced plastic reaction kettle for producing water purification materials according to the present invention;

FIG. 6 is a right side view of the internal structure of the sampling mechanism of the glass fiber reinforced plastic reaction kettle for producing water purification materials in accordance with the present invention;

FIG. 7 is an enlarged view of the structure at the position A of the reaction kettle for producing water purification material of the present invention;

figure 8 is the utility model discloses a water purification material production is with glass steel reation kettle's embodiment 2 on-off mechanism's front view.

The reference numerals are explained below: 1. a reaction kettle; 2. a feed hopper; 3. a stirring mechanism; 301. a support; 302. a stirring motor; 303. a stirring shaft; 304. a stirring arm; 4. a transmission mechanism; 401. a bull gear; 402. a pinion gear; 403. a rotating shaft; 5. a bulk material mechanism; 501. a magazine; 502. a support bar; 503. an arc-shaped net; 504. a turntable; 505. a material poking rod; 6. a sampling mechanism; 601. a sampling box; 602. a material taking cavity; 603. a material pumping pipe; 604. a discharge pipe; 7. an on-off mechanism; 701. a worm; 702. a worm gear; 703. a screw rod; 704. a sleeve; 705. a piston; 706. a threaded rod; 707. a thread block; 708. a drive ring; 709. a push-pull rod.

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.

In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The present invention will be further explained with reference to the accompanying drawings:

example 1

As shown in fig. 1-7, a glass fiber reinforced plastic reation kettle is used in water purification material production, including reation kettle 1, reation kettle 1 top is connected with feeder hopper 2, reation kettle 1 top is provided with rabbling mechanism 3, be provided with drive mechanism 4 on the rabbling mechanism 3, reation kettle 1 is inside to be provided with the bulk cargo mechanism 5 that is used for breaking up the raw materials, bulk cargo mechanism 5 is located the feed opening below of feeder hopper 2, bulk cargo mechanism 5 is driven by drive mechanism 4, reation kettle 1 one side is provided with the sampling mechanism 6 of being convenient for collect the sample, be provided with in the sampling mechanism 6 and be used for making sampling mechanism 6 and reation kettle 1 intercommunication or on-off mechanism 7 who blocks.

Preferably, the stirring mechanism 3 comprises a support 301, a stirring motor 302, a stirring shaft 303 and stirring arms 304, the support 301 is arranged at the top of the reaction kettle 1 through bolts, the top of the support 301 is connected with the stirring motor 302 through bolts, an output shaft of the stirring motor 302 extends into the reaction kettle 1 and is connected with the stirring shaft 303 through a coupling, a plurality of stirring arms 304 are welded on the stirring shaft 303, the transmission mechanism 4 comprises a large gear 401, a small gear 402 and a rotating shaft 403, the large gear 401 is connected to the output shaft of the stirring motor 302 through a key, one side of the large gear 401 close to the feed hopper 2 is engaged with the small gear 402, the rotating shaft 403 is welded at the bottom of the small gear 402, the bottom end of the rotating shaft 403 extends into the reaction kettle 1, the rotating shaft 403 is connected with the top wall of the reaction kettle 1 through a bearing, the bulk material mechanism 5 comprises a material box 501, a supporting rod 502, an arc net 503, a rotating table 504 and a stirring rod 505, the top of the material box 501 is welded with the supporting rod 502, the top of the support rod 502 is welded on the top wall in the reaction kettle 1, one side of the material box 501 close to the stirring shaft 303 is provided with an arc-shaped net 503, the bottom wall in the material box 501 is connected with a rotary table 504 through a bearing, the rotary table 504 is welded with a plurality of material stirring rods 505, the top of the rotary table 504 is connected with the rotary shaft 403 through a key, the sampling mechanism 6 comprises a sampling box 601, a material taking cavity 602, a material taking pipe 603 and a material discharging pipe 604, the sampling box 601 is connected with one side of the reaction kettle 1 through a bolt, at least two material taking cavities 602 are arranged in the sampling box 601, the number of material taking pipes 603 which is the same as the number of the material taking cavities 602 are arranged in the sampling box 601, one end of each material taking pipe 603 is communicated with the interior of the reaction kettle 1, the bottom of each material taking pipe 603 is connected with the material discharging pipe 604, the other end of each material discharging pipe 604 is communicated with the material taking cavity 602, the on-off mechanism 7 is provided with a worm 701, a worm wheel 702, a screw rod 703, a sleeve 704 and a piston 705, one side of the worm 701 close to the material taking cavity 602 is engaged with a worm wheel 702, the worm wheel 702 is internally connected with a screw rod 703 through a key, one end of the screw rod 703, which is far away from the material taking pipe 603, is connected with the side wall of the sampling box 601 through a bearing, one end of the screw rod 703, which is close to the material taking pipe 603, is connected inside a sleeve pipe 704 through a thread, one end of the sleeve pipe 704 extends into the material taking pipe 603 and is fixedly connected with a piston 705, the piston 705 is tightly attached to the inner wall of the material taking pipe 603, the reaction kettle 1 is made of glass fiber reinforced plastic, and the rotary table 504 is a tapered cylinder with a small top and a large bottom.

Example 2

As shown in fig. 8, embodiment 2 differs from embodiment 1 in that: the on-off mechanism 7 comprises a piston 705, a threaded rod 706, a threaded block 707, a driving ring 708 and a push-pull rod 709, the threaded rod 706 is connected to the inside of the sampling box 601 through a bearing, the threaded rod 706 is connected with the threaded block 707 through threads, one side, far away from the material taking cavity 602, of the threaded block 707 is in sliding connection with the inner wall of the sampling box 601, the driving ring 708 is welded on one side, close to the material taking cavity 602, of the threaded block 707, one end of the push-pull rod 709 is arranged inside the driving ring 708, the other end of the push-pull rod 709 extends into the material taking pipe 603 and is fixedly connected with the piston 705, the piston 705 is tightly attached to the inner wall of the material taking pipe 603, and a sliding groove connected with the threaded block 707 is formed in one side, close to the threaded block 707, of the sampling box 601.

The working principle is as follows: when the stirring device is used, the stirring shaft 303 is driven by the stirring motor 302 to rotate, the stirring shaft 303 drives the stirring arm 304 to rotate, the stirring motor 302 drives the large gear 401 to rotate, the large gear 401 drives the small gear 402 to rotate, the small gear 402 drives the rotating shaft 403 to rotate, the rotating shaft 403 drives the rotating table 504 to rotate, the rotating table 504 drives the stirring rod 505 to rotate, raw materials are poured into the reaction kettle 1 from the feeding hopper 2 and fall into the material box 501, the raw materials are scattered by the stirring rod 505, and are made to fly out through the arc-shaped net 503 under the centrifugal force action of the rotating table 504, so that the raw materials are scattered again, solid raw materials can be quickly mixed with liquid raw materials, the solid raw materials are prevented from being quickly deposited at the bottom of the reaction kettle 1, the mixing efficiency is improved, when sampling detection is required, the worm 701 drives the worm gear 702 to rotate, the worm gear 702 drives the screw rod 703 to rotate, the screw rod 703 drives the sleeve 704 to move in the direction far away from the reaction kettle 1, the sleeve 704 drives the piston 705 to move, or the threaded rod 706 drives the threaded block 707 to move downwards, the threaded block 707 drives the driving ring 708 to move downwards, the driving ring 708 enables the push-pull rod 709 to move towards the direction away from the reaction kettle 1, the push-pull rod 709 drives the piston 705 to move, so that raw materials enter the discharge pipe 604 through the material pumping pipe 603, and a sampling bottle is placed in the material pumping cavity 602 for sampling.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a water purification material production is with glass steel reation kettle, includes reation kettle (1), reation kettle (1) top is connected with feeder hopper (2), reation kettle (1) top is provided with rabbling mechanism (3), be provided with drive mechanism (4), its characterized in that on rabbling mechanism (3): reation kettle (1) inside bulk cargo mechanism (5) that are used for breaking up the raw materials that are provided with, bulk cargo mechanism (5) are located the feed opening below of feeder hopper (2), bulk cargo mechanism (5) by drive mechanism (4) drive, reation kettle (1) one side is provided with sampling mechanism (6) of being convenient for collect the sample, be provided with in sampling mechanism (6) and be used for making sampling mechanism (6) with reation kettle (1) intercommunication or break-make mechanism (7) that block.

2. The glass fiber reinforced plastic reaction kettle for producing the water purifying material as claimed in claim 1, wherein: rabbling mechanism (3) are including support (301), agitator motor (302), (mixing) shaft (303), rabbling arm (304), support (301) through the bolt in reation kettle (1) top, there is agitator motor (302) at support (301) top through bolted connection, the output shaft of agitator motor (302) stretches into reation kettle (1) is inside and has through the coupling joint (303), the welding is gone up in (mixing) shaft (303) has a plurality ofly rabbling arm (304).

3. The glass fiber reinforced plastic reaction kettle for producing water purifying materials as claimed in claim 2, wherein: drive mechanism (4) include gear wheel (401), pinion (402), pivot (403), gear wheel (401) through the key-type connection in on the output shaft of agitator motor (302), gear wheel (401) are close to one side meshing of feeder hopper (2) has pinion (402), the welding of pinion (402) bottom has pivot (403), pivot (403) bottom stretches into in reation kettle (1), pivot (403) with reation kettle (1) roof passes through the bearing and connects.

4. The glass fiber reinforced plastic reaction kettle for producing water purifying materials according to claim 3, wherein: bulk cargo mechanism (5) are including magazine (501), bracing piece (502), arc net (503), revolving stage (504), stirring rod (505), the welding of magazine (501) top has bracing piece (502), bracing piece (502) top weld in on reation kettle (1) interior roof, magazine (501) are close to one side of (mixing) shaft (303) is provided with arc net (503), the bottom wall is connected with through the bearing in magazine (501) revolving stage (504), the welding has a plurality ofly on revolving stage (504) stirring rod (505), revolving stage (504) top with pivot (403) pass through the key-type connection.

5. The glass fiber reinforced plastic reaction kettle for producing water purifying materials according to claim 1, wherein: sampling mechanism (6) including sampling case (601), get material chamber (602), material extraction pipe (603), discharging pipe (604), sampling case (601) through bolted connection in reation kettle (1) one side, set up at least two in sampling case (601) get material chamber (602), sampling case (601) inside be provided with get material chamber (602) the same quantity material extraction pipe (603), material extraction pipe (603) one end with reation kettle (1) inside intercommunication, material extraction pipe (603) bottom is connected with discharging pipe (604), the other end of discharging pipe (604) with get material chamber (602) intercommunication.

6. The glass fiber reinforced plastic reaction kettle for producing water purifying materials according to claim 5, wherein: the sampling device is characterized in that the on-off mechanism (7) comprises a worm (701), a worm wheel (702), a lead screw (703), a sleeve (704) and a piston (705), the worm (701) is connected to the inside of the sampling box (601) through a bearing, the worm wheel (702) is meshed on one side, close to the material taking cavity (602), of the worm (701), the lead screw (703) is connected to the inside of the worm wheel (702) through a key, one end, far away from the material taking pipe (603), of the lead screw (703) is connected with the side wall of the sampling box (601) through a bearing, one end, close to the material taking pipe (603), of the lead screw (703) is connected to the inside of the sleeve (704) through threads, one end of the sleeve (704) stretches into the inside of the material taking pipe (603) and is fixedly connected with the piston (705), and the piston (705) is tightly attached to the inner wall of the material taking pipe (603).

7. The glass fiber reinforced plastic reaction kettle for producing water purifying materials according to claim 5, wherein: the on-off mechanism (7) comprises a piston (705), a threaded rod (706), a threaded block (707), a driving ring (708) and a push-pull rod (709), the threaded rod (706) is connected to the inside of the sampling box (601) through a bearing, the threaded rod (706) is connected with the threaded block (707) through threads, one side, away from the material taking cavity (602), of the threaded block (707) is connected with the inner wall of the sampling box (601) in a sliding mode, one side, close to the material taking cavity (602), of the threaded block (707) is welded with the driving ring (708), one end of the push-pull rod (709) is arranged inside the driving ring (708), the other end of the push-pull rod (709) extends into the inside of the material taking pipe (603) and is fixedly connected with the piston (603), and the piston (705) is tightly attached to the inner wall of the material taking pipe (603).

8. The glass fiber reinforced plastic reaction kettle for producing water purifying materials according to claim 1, wherein: the reaction kettle (1) is made of glass fiber reinforced plastic.

9. The glass fiber reinforced plastic reaction kettle for producing water purifying materials as claimed in claim 4, wherein: the rotary table (504) is a conical cylinder with a small upper part and a big lower part.

10. The glass fiber reinforced plastic reaction kettle for producing water purifying materials according to claim 7, wherein: one side of the sampling box (601) close to the thread block (707) is provided with a sliding groove connected with the thread block (707).

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