CN221016034U - Electric heating reaction kettle - Google Patents

Abstract

The utility model discloses an electric heating reaction kettle, which comprises an outer shell, wherein a mixing mechanism is arranged in the outer shell, a discharging mechanism is arranged at the bottom of the outer shell, the mixing mechanism comprises an inner shell, the inner shell is arranged in the outer shell, a heating pipe is arranged between the inner shell and the outer shell, a motor is arranged at the top of the outer shell, a shaft rod is arranged at the bottom end of an output shaft of the motor and positioned in the inner shell, a plurality of stirring rods are arranged at the periphery of the shaft rod, two spiral plates are arranged at the outer end of the stirring rods and positioned in the inner shell, and a plurality of through holes are formed through the front part and the rear part of the spiral plates; the electric heating reaction kettle is convenient for scraping the colloid adhered to the inner wall, is favorable for uniform heating reaction of the colloid, is convenient for opening and closing the discharging pipe, accelerates the discharging of the colloid, and prevents blockage.

Description

Electric heating reaction kettle

Technical Field

The utility model relates to the technical field of reaction kettles, in particular to an electric heating reaction kettle.

Background

The electric heating reaction kettle is equipment for heating materials for reaction, is internally provided with an electric heating element for providing the reaction temperature, and is widely used for chemical reaction, pharmaceutical technology, material synthesis and the like;

When the conventional electric heating reaction kettle is used, when the colloid is heated for reaction, the colloid is easy to adhere to the inner wall to cause local overhigh temperature, the adhered colloid is inconvenient to scrape off, uniform heating is inconvenient, the colloid in the part of the discharging pipe cannot be heated for reaction, the colloid in the discharging pipe cannot be turned upwards for mixing, the discharging pipe is easy to block during discharging, the discharging is inconvenient to accelerate, and certain influence is brought to practical use.

Disclosure of utility model

The utility model mainly aims to provide an electric heating reaction kettle which can effectively solve the technical problems in the background technology.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

The utility model provides an electrical heating reation kettle, includes the shell body, the internally mounted of shell body has mixing mechanism, discharge mechanism is installed to the bottom of shell body, mixing mechanism includes the inner shell body, the inside at the shell body is installed to the inner shell body, install the heating pipe between inner shell body and the shell body, the motor is installed at the top of shell body, motor output shaft bottom just is located the internally mounted of inner shell body has the axostylus axostyle, a plurality of puddler is installed to the periphery of axostylus axostyle, the outer end of puddler just is located the internally mounted of inner shell body has two screw plates, runs through a plurality of through-hole has been seted up at the front and back portion of screw plate, the scraper blade is installed to the outside of screw plate and the inner wall that is located the inner shell body.

As a further scheme of the utility model, the diameter of the inner shell is smaller than that of the outer shell, and the two spiral plates are fixedly arranged between the two spiral plates and the corresponding three stirring rods respectively.

As a further scheme of the utility model, the spiral plate is arranged in a bent and inclined mode, and the scraping plates are arranged on the inner wall of the inner shell in a matched mode.

As a further scheme of the utility model, the discharging mechanism comprises a chassis, the chassis is arranged at the bottoms of the inner shell and the outer shell, a discharging pipe is arranged at the bottom penetrating through the chassis, a rotating rod is arranged in the discharging pipe and positioned at the bottom of the shaft lever, a spiral blade is arranged at the periphery of the rotating rod and positioned in the discharging pipe, a valve seat is arranged at the bottom of the discharging pipe, a ball body is movably arranged in the valve seat, a discharging hole is formed at the upper end and the lower end penetrating through the ball body, and a rotary valve is arranged between one side penetrating through the valve seat and the ball body.

As a further scheme of the utility model, the shaft lever and the rotating rod are synchronously rotated, and the ball body is positioned in the valve seat and synchronously rotated with the rotary valve.

As a further scheme of the utility model, the spiral blades are positioned on the inner wall of the discharging pipe and are mutually matched, and the spiral direction of the spiral blades is the same as that of the spiral plate.

The beneficial effects of the utility model are as follows:

According to the utility model, the mixing mechanism is arranged, the motor drives the shaft rod to rotate, so that the stirring rod drives the spiral plate and the scraping plate to rotate on the inner wall of the inner shell, the colloid adhered to the inner wall is scraped, the adhered colloid is prevented from being heated to be too high, and the scraped colloid is stirred and mixed by the stirring rod, so that the colloid is heated uniformly for reaction;

Through setting up discharge mechanism, drive the bull stick rotatory when the axostylus axostyle is rotatory, make spiral leaf and spiral lamina synchronous rotation, upwards overturn the colloid that will flow into the discharging intraductal, through rotating the rotary valve, drive the spheroid rotatory, make discharge gate and discharging pipe switch-on or break away from, the opening and the closure of the discharging pipe of being convenient for through the reversal of spiral leaf for the ejection of compact of colloid prevents to block up.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an electric heating reaction kettle;

FIG. 2 is a schematic diagram of the internal structure of a mixing mechanism in an electric heating reaction kettle;

FIG. 3 is a schematic diagram of the internal structure of a discharging mechanism in an electric heating reaction kettle;

fig. 4 is a front view of the inside of an electrically heated reactor according to the present utility model.

In the figure: 1. an outer housing; 2. a mixing mechanism; 3. a discharging mechanism; 4. an inner housing; 5. heating pipes; 6. a motor; 7. a shaft lever; 8. a stirring rod; 9. a spiral plate; 10. a through hole; 11. a scraper; 12. a chassis; 13. a discharge pipe; 14. a rotating rod; 15. spiral leaves; 16. a valve seat; 17. a sphere; 18. a discharge port; 19. and (5) rotating the valve.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

As shown in fig. 1-4, an electric heating reaction kettle comprises an outer shell 1, a mixing mechanism 2 is installed in the outer shell 1, a discharging mechanism 3 is installed at the bottom of the outer shell 1, the mixing mechanism 2 comprises an inner shell 4, the inner shell 4 is installed in the outer shell 1, a heating pipe 5 is installed between the inner shell 4 and the outer shell 1, a motor 6 is installed at the top of the outer shell 1, a shaft rod 7 is installed at the bottom end of an output shaft of the motor 6 and located in the inner shell 4, a plurality of stirring rods 8 are installed at the periphery of the shaft rod 7, two spiral plates 9 are installed at the outer ends of the stirring rods 8 and located in the inner shell 4, a plurality of through holes 10 are formed through the front portion and the rear portion of the spiral plates 9, a scraping plate 11 is installed on the outer side of the spiral plates 9 and located on the inner wall of the inner shell 4, and the model JS of the heating pipe 5 is-MS.

In this embodiment, the diameter of inner casing 4 is less than the diameter of shell body 1, is fixed mounting setting between two screw plates 9 respectively and the corresponding three puddler 8, drives axostylus axostyle 7 rotatory through motor 6, makes screw plate 9 be located the inside rotation of inner casing 4, stirs the colloid through puddler 8, is convenient for evenly heat.

In this embodiment, spiral plate 9 is crooked slope form setting, and scraper blade 11 is located the inner wall of inner shell 4 and is mutual matching setting, and spiral plate 9 drives scraper blade 11 and is located the inner wall rotation of inner shell 4, scrapes the colloid of inner shell 4 inner wall adhesion in proper order through scraper blade 11, prevents that the colloid temperature of adhesion at the inner wall from being too high, reduces the adhesion.

In this embodiment, discharge mechanism 3 includes chassis 12, chassis 12 installs the bottom of inner casing 4 and shell body 1, install discharging pipe 13 throughout the bottom of chassis 12, the bull stick 14 is installed to the inside of discharging pipe 13 and is located the bottom of axostylus axostyle 7, the periphery of bull stick 14 and be located the internally mounted of discharging pipe 13 have spiral vane 15, disk seat 16 is installed to the bottom of discharging pipe 13, the inside movable mounting of disk seat 16 has spheroid 17, discharge gate 18 has been seted up to the upper and lower end of running through spheroid 17, one side of running through disk seat 16 and be connected with the spheroid 17 and install rotary valve 19, spiral vane 15 and axostylus axostyle 7 synchronous rotation, under the rotatory effect of spiral plate 9 and spiral vane 15, make the colloid upwards overturn, make the colloid downwards through the reversal, and in intaking discharging pipe 13, discharge gate 18 discharges, can make the colloid that flows in discharging pipe 13 carry out cyclic heating, accelerate the ejection of compact of colloid.

In this embodiment, the shaft lever 7 and the rotating rod 14 are synchronously rotated, the ball 17 is located in the valve seat 16 and synchronously rotated with the rotary valve 19, and the rotary valve 19 drives the ball 17 to rotate, so that the discharge port 18 is connected or disconnected with the discharge pipe 13, and the discharge pipe 13 is conveniently opened and closed.

In this embodiment, the spiral blade 15 is located the discharging pipe 13 inner wall and is mutually matched and set up, and spiral direction of spiral blade 15 and spiral plate 9 is the same, through the rotation of spiral blade 15, makes the colloid circulation that flows in the discharging pipe 13 upwards flow and heats in turn, through the reversal of spiral blade 15, is convenient for accelerate the colloid ejection of compact.

When the electric heating reaction kettle is used, firstly, colloid to be processed is added into the inner shell 4 through a feed inlet, a motor 6 is started to drive a shaft lever 7 to rotate, meanwhile, a heating pipe 5 is started to heat the inner shell 4, the shaft lever 7 drives a stirring rod 8 to rotate, a spiral plate 9 drives a scraping plate 11 to be positioned on the inner wall of the inner shell 4 to rotate, the scraped colloid adhered to the inner wall of the inner shell 4 is scraped by the scraping plate 11, the stirring rod 8 is used for stirring and mixing, the colloid is uniformly heated while the colloid adhered to the inner wall is prevented from being heated, part of the colloid flows into a discharge pipe 13, a rotating rod 14 is driven to rotate while the shaft lever 7 rotates, a spiral blade 15 is used for overturning the colloid in the discharge pipe 13 upwards, and when the discharging is carried out, the motor 6 is reversely rotated, the colloid is positioned in the discharge pipe 13 and flows downwards through the spiral blade 15, a rotary valve 19 is rotated, a ball 17 is rotated, a discharge port 18 is aligned with the discharge pipe 13, and the colloid is discharged through the discharge port 18.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. An electric heating reation kettle, its characterized in that: including shell body (1), the internally mounted of shell body (1) has mixed mechanism (2), discharge mechanism (3) are installed to the bottom of shell body (1), mixed mechanism (2) are including interior casing (4), the inside at shell body (1) is installed to interior casing (4), install heating pipe (5) between interior casing (4) and shell body (1), motor (6) are installed at the top of shell body (1), motor (6) output shaft bottom and the internally mounted who is located interior casing (4) have axostylus axostyle (7), a plurality of puddler (8) are installed to the periphery of axostylus axostyle (7), the outer end of puddler (8) and the internally mounted who is located interior casing (4) have two screw plates (9), run through a plurality of through-hole (10) have been seted up at the front and back portion of screw plate (9), the outside of screw plate (9) and the inner wall that is located interior casing (4) install scraper blade (11).

2. An electrically heated reactor as set forth in claim 1 wherein: the diameter of the inner shell (4) is smaller than that of the outer shell (1), and two spiral plates (9) are fixedly arranged between the two spiral plates and the corresponding three stirring rods (8).

3. An electrically heated reactor as set forth in claim 1 wherein: the spiral plate (9) is arranged in a bending and tilting mode, and the scraping plates (11) are arranged on the inner wall of the inner shell (4) in a mutually matched mode.

4. An electrically heated reactor as set forth in claim 1 wherein: the discharging mechanism (3) comprises a chassis (12), wherein the chassis (12) is arranged at the bottoms of the inner shell (4) and the outer shell (1), a discharging pipe (13) is arranged at the bottom of the penetrating chassis (12), a rotating rod (14) is arranged at the bottom of the discharging pipe (13) and positioned at the bottom of a shaft rod (7), a spiral blade (15) is arranged at the periphery of the rotating rod (14) and positioned at the inner part of the discharging pipe (13), a valve seat (16) is arranged at the bottom of the discharging pipe (13), a ball body (17) is movably arranged at the bottom of the valve seat (16), a discharging hole (18) is arranged at the upper end and the lower end of the penetrating ball body (17), and a rotary valve (19) is arranged on one side of the penetrating the valve seat (16) and connected with the ball body (17).

5. An electrically heated reactor as set forth in claim 4 wherein: the shaft lever (7) and the rotating rod (14) are synchronously rotated, and the ball body (17) is positioned in the valve seat (16) and synchronously rotated with the rotary valve (19).

6. An electrically heated reactor as set forth in claim 4 wherein: the spiral blades (15) are arranged on the inner wall of the discharge pipe (13) in a mutually matched mode, and the spiral directions of the spiral blades (15) and the spiral plate (9) are the same.