CN219540322U

CN219540322U - Heating device for activating molecular sieve

Info

Publication number: CN219540322U
Application number: CN202320211651.XU
Authority: CN
Inventors: 黄新华; 卢园园; 黄玉琴
Original assignee: Zhengzhou Aluminum City New Material Technology Co ltd
Current assignee: Zhengzhou Aluminum City New Material Technology Co ltd
Priority date: 2023-02-14
Filing date: 2023-02-14
Publication date: 2023-08-18
Anticipated expiration: 2033-02-14

Abstract

The utility model discloses a heating device for activating a molecular sieve, which belongs to the technical field of molecular sieve activation and comprises a frame body, wherein a heating furnace is fixedly arranged at the upper end of the frame body, a feed inlet is arranged on the side wall of the heating furnace, a first motor with an output shaft extending downwards is fixedly arranged at the upper end of the heating furnace, a heating assembly is arranged in the heating furnace, a discharge hole is arranged at the lower end of the heating furnace, and a guide pipe is communicated with the discharge hole; the support body includes first supporter and second supporter, and the upper end of first supporter rotates and is connected with the cooling cylinder, and the right-hand member of pipe extends to the inside of cooling cylinder, and the pipe rotates with the cooling cylinder to be connected, fixedly on the second supporter is equipped with the second motor, is connected with the cross axle on the output shaft of second motor, the left end and the right-hand member fixed connection of cooling cylinder of cross axle. The molecular sieve is heated more uniformly, and the dehumidification speed is increased; the cooling speed of the molecular sieve is accelerated, the molecular sieve is cooled more quickly, the packaging can be carried out earlier, and the working efficiency is improved.

Description

Heating device for activating molecular sieve

Technical Field

The utility model belongs to the technical field of molecular sieve activation, and particularly relates to a heating device for molecular sieve activation.

Background

The molecular sieve must be dehydrated and activated at high temperature before use, so that the molecular sieve can effectively play a role, and the used or adsorbed and saturated molecular sieve can be repeatedly used after reactivation. In the molecular sieve activation process, the existing heating device is used for drying the molecular sieve in a static state in a heating furnace, so that the effect is not good enough, the molecular sieve is heated unevenly and cannot be dried sufficiently, and further the dehumidification efficiency and effect on the molecular sieve are not excellent. In addition, after the molecular sieve is activated at high temperature, the molecular sieve can not be directly packaged, and can be packaged after cooling, and the existing molecular sieve is naturally cooled by placing the molecular sieve outside a heating furnace for a period of time, so that the cooling speed is low, and the working efficiency is low.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provide a heating device for activating a molecular sieve, which solves the problems in the prior art.

The purpose of the utility model is realized in the following way: the heating device for activating the molecular sieve comprises a frame body, wherein a heating furnace is fixedly arranged at the upper end of the frame body, a feed inlet is formed in the side wall of the heating furnace, a first motor with a downward extending output shaft is fixedly arranged at the upper end of the heating furnace, a heating component is arranged in the heating furnace, a discharge hole is formed in the lower end of the heating furnace, and a guide pipe is communicated with the discharge hole; the frame body comprises a first supporting body and a second supporting body, the upper end of the first supporting body is rotationally connected with a heat dissipation cylinder, the right end of the guide pipe extends to the inside of the heat dissipation cylinder, the guide pipe is rotationally connected with the heat dissipation cylinder, the second supporting body is fixedly provided with a second motor, the output shaft of the second motor is connected with a transverse shaft, and the left end of the transverse shaft is fixedly connected with the right end of the heat dissipation cylinder.

Further, the output shaft of first motor is connected with the vertical axis through the shaft coupling, the vertical axis extends to the inside of heating furnace, and the left side wall of vertical axis is from last to a plurality of first puddlers of fixedly connected with down, and the right side wall of vertical axis is from last a plurality of second puddlers of fixedly connected with down, just first puddler and second puddler set up each other alternately.

Further, the heating assembly comprises a heating wire fixedly connected to the first stirring rod and the second stirring rod.

Further, the heating furnace comprises a vertical cylinder body and a bottom cylinder body, and a grid baffle is arranged at the joint of the vertical cylinder body and the bottom cylinder body in a sliding manner.

Further, a sliding groove is formed in the middle of the peripheral outer wall of the heat dissipation cylinder, a sliding hoop is fixedly arranged at the upper end of the first support body, and the sliding hoop is in sliding fit with the sliding groove; a plurality of support rods which are outwards extended in a diffusion mode are fixedly arranged on the peripheral outer wall of the radiating cylinder.

Further, the upper end of the second supporting body is fixedly provided with a transverse plate, the second motor is fixedly installed on the upper surface of the transverse plate through a motor base, and an output shaft of the second motor is connected with the right end of the transverse shaft through a coupler.

Further, the upper end of the feeding pipe is detachably connected with a cover body.

The utility model has the beneficial effects that: through set up first motor and at the inside heating element that sets up of heating furnace in the upper end of heating furnace, first motor rotates and drives heating element and rotate, is not being static stoving to the molecular sieve, but is through letting the molecular sieve mix inside the heating furnace and move the stoving, makes the molecular sieve be heated more evenly for dehumidification speed improves drying efficiency. Through the setting of a heat dissipation section of thick bamboo, the molecular sieve activation is carried to the heat dissipation section of thick bamboo inside after drying, utilizes the second motor to drive the heat dissipation section of thick bamboo and rotates for the cooling rate of molecular sieve, the molecular sieve cooling is faster, can earlier carry out the bagging-off, improves work efficiency.

Drawings

FIG. 1 is a schematic diagram of the front view of the present utility model;

FIG. 2 is a schematic view of the internal structure of the heating furnace of the present utility model;

FIG. 3 is a schematic view of a heat dissipating cartridge according to the present utility model;

fig. 4 is a schematic cross-sectional view of a heat dissipating cartridge of the present utility model.

In the figure: 1. the heating furnace comprises a frame body 2, a heating furnace 3, a first motor 4, a guide pipe 5, a first support body 6, a second support body 7, a heat dissipation cylinder 8, a second motor 9, a transverse shaft 10, a vertical shaft 11, a first stirring rod 12, a second stirring rod 13, a heating wire 14, a bottom cylinder 15, a grid baffle 16, a sliding hoop 17, a supporting rod 18 and a feeding pipe.

Description of the embodiments

The present utility model will be described in further detail with reference to the accompanying drawings, and it should be noted that all the azimuth words, such as up, down, front, back, left, right, etc., appearing in the present utility model are azimuth words made by taking fig. 1 as a reference drawing, and all the azimuth words do not limit the present utility model, but are used for more clear description and explanation of the present utility model.

Examples

As shown in fig. 1-4, this embodiment discloses a heating device for activating a molecular sieve, which comprises a frame body 1, wherein a heating furnace 2 is fixedly arranged at the upper end of the frame body 1, a feed inlet is arranged on the side wall of the heating furnace 2, a first motor 3 with an output shaft extending downwards is fixedly arranged at the upper end of the heating furnace 2, a heating component is arranged inside the heating furnace 2, a discharge hole is arranged at the lower end of the heating furnace 2, and a guide pipe 4 is arranged on the discharge hole in a communicating manner. The support body 1 includes first supporter 5 and second supporter 6, and the upper end of first supporter 5 rotates and is connected with a heat dissipation section of thick bamboo 7, and the right-hand member of pipe 4 extends to the inside of a heat dissipation section of thick bamboo 7, and pipe 4 and heat dissipation section of thick bamboo 7 rotate to be connected, and the fixed second motor 8 that is equipped with on the second supporter 6, be connected with cross axle 9 on the output shaft of second motor 8, the left end and the right-hand member fixed connection of a heat dissipation section of thick bamboo 7 of cross axle 9.

This embodiment is through setting up first motor 3 in the upper end of heating furnace 2 and setting up heating element in heating furnace 2 inside, and first motor 3 rotates and drives heating element and rotate, is not being static stoving of molecular sieve, but is through letting the molecular sieve be heated more evenly at the inside mixed stoving of heating furnace 2 for dehumidification speed improves drying efficiency. Through the setting of a heat dissipation section of thick bamboo 7, the molecular sieve activation is carried inside a heat dissipation section of thick bamboo 7 after drying, utilizes second motor 8 to drive a heat dissipation section of thick bamboo 7 rotation for the cooling rate of molecular sieve, the molecular sieve cooling is faster, can earlier carry out the bagging-off, improves work efficiency.

Examples

For the replacement effect, the output shaft of the first motor 3 is connected with a vertical shaft 10 through a coupling, the vertical shaft 10 extends to the inside of the heating furnace 2, the left side wall of the vertical shaft 10 is fixedly connected with a plurality of first stirring rods 11 from top to bottom, the right side wall of the vertical shaft 10 is fixedly connected with a plurality of second stirring rods 12 from top to bottom, and the first stirring rods 11 and the second stirring rods 12 are alternately arranged. When the molecular sieve heating furnace is used, the molecular sieve is added into the heating furnace 2 through the feed inlet, the vertical shaft 10 is driven to rotate after the first motor 3 is electrified, the vertical shaft 10 drives the first stirring rod 11 and the second stirring rod 12 to rotate in the heating furnace 2 so as to mix and stir the molecular sieve, and the dehumidification is accelerated.

For the effect of the replacement, the heating assembly comprises heating wires 13 fixedly connected to the first stirring rod 11 and the second stirring rod 12. In the process of rotating the vertical shaft 10, the heating wire 13 synchronously rotates along with the first stirring rod 11 and the second stirring rod 12, so that the molecular sieve in the heating furnace 2 is heated more uniformly.

For the replacement effect, the heating furnace 2 comprises a vertical cylinder and a bottom cylinder 14, and a grid baffle 15 is slidably arranged at the joint of the vertical cylinder and the bottom cylinder 14. When the molecular sieve is used, before the molecular sieve is placed into the heating furnace 2, the vertical cylinder body in the heating furnace 2 is firstly separated from the bottom cylinder body 14 through the grid baffle 15, and then the molecular sieve is placed into the heating furnace 2 from the feed inlet. After the molecular sieve is activated and dried, the grid baffle 15 is slowly pulled out of the heating furnace 2, the molecular sieve falls into the bottom cylinder 14 from the upper part of the grid baffle 15, and then flows into the heat dissipation cylinder 7 after passing through the conduit 4.

For the replacement effect, a sliding groove is formed in the middle position of the peripheral outer wall of the heat dissipation barrel 7, a sliding hoop 16 is fixedly arranged at the upper end of the first support body 5, and the sliding hoop 16 is in sliding fit with the sliding groove. A plurality of support rods 17 which are extended outwards in a diffusion way are fixedly arranged on the peripheral outer wall of the heat dissipation cylinder 7. The upper end of the second supporting body 6 is fixedly provided with a transverse plate, the second motor 8 is fixedly arranged on the upper surface of the transverse plate through a motor base, and an output shaft of the second motor 8 is connected with the right end of the transverse shaft 9 through a coupler. When the molecular sieve is used, after entering the interior of the heat dissipation cylinder 7, the second motor 8 is electrified to drive the transverse shaft 9 to rotate, the transverse shaft 9 drives the heat dissipation cylinder 7 to rotate, the heat dissipation cylinder 7 enables the molecular sieve to roll in the interior of the heat dissipation cylinder 7, the molecular sieve transfers heat to the heat dissipation cylinder 7, the heat dissipation cylinder 7 transfers heat to the plurality of support rods 17, the heat is rapidly dissipated through the plurality of support rods 17, and the cooling speed of the molecular sieve is accelerated.

For the replacement effect, the arc-shaped feeding pipe 18 is communicated with the feeding hole, and the upper end of the feeding pipe 18 is detachably connected with a cover body.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the concept thereof, can be replaced or changed equally within the scope of the present utility model.

Claims

1. The utility model provides a heating device for molecular sieve activation, includes support body (1), the upper end of support body (1) is fixed with heating furnace (2), its characterized in that: the heating furnace is characterized in that a feed inlet is formed in the side wall of the heating furnace (2), a first motor (3) with a downward extending output shaft is fixedly arranged at the upper end of the heating furnace (2), a heating assembly is arranged inside the heating furnace (2), a discharge outlet is formed in the lower end of the heating furnace (2), and a guide pipe (4) is communicated with the discharge outlet; the frame body (1) comprises a first supporting body (5) and a second supporting body (6), the upper end of the first supporting body (5) is rotationally connected with a radiating cylinder (7), the right end of the guide pipe (4) extends to the inside of the radiating cylinder (7), the guide pipe (4) is rotationally connected with the radiating cylinder (7), a second motor (8) is fixedly arranged on the second supporting body (6), a transverse shaft (9) is connected to an output shaft of the second motor (8), and the left end of the transverse shaft (9) is fixedly connected with the right end of the radiating cylinder (7).

2. The heating device for activating a molecular sieve according to claim 1, wherein: the output shaft of first motor (3) is connected with vertical shaft (10) through the shaft coupling, vertical shaft (10) extend to the inside of heating furnace (2), the left side wall of vertical shaft (10) is from last a plurality of first puddlers (11) of fixedly connected with down, the right side wall of vertical shaft (10) is from last a plurality of second puddlers (12) of fixedly connected with down, just first puddler (11) and second puddler (12) set up each other alternately.

3. The heating device for activating a molecular sieve according to claim 2, wherein: the heating component comprises a heating wire (13) fixedly connected to the first stirring rod (11) and the second stirring rod (12).

4. The heating device for activating a molecular sieve according to claim 1, wherein: the heating furnace (2) comprises a vertical cylinder body and a bottom cylinder body (14), and a grid baffle plate (15) is slidably arranged at the joint of the vertical cylinder body and the bottom cylinder body (14).

5. The heating device for activating a molecular sieve according to claim 1, wherein: a sliding groove is formed in the middle of the peripheral outer wall of the radiating cylinder (7), a sliding hoop (16) is fixedly arranged at the upper end of the first supporting body (5), and the sliding hoop (16) is in sliding fit with the sliding groove; a plurality of supporting rods (17) which are outwards diffused and extended are fixedly arranged on the peripheral outer wall of the radiating cylinder (7).

6. The heating device for activating a molecular sieve according to claim 1, wherein: the upper end of the second supporting body (6) is fixedly provided with a transverse plate, the second motor (8) is fixedly arranged on the upper surface of the transverse plate through a motor base, and an output shaft of the second motor (8) is connected with the right end of the transverse shaft (9) through a coupler.

7. The heating device for activating a molecular sieve according to claim 1, wherein: the feeding port is communicated with an arc-shaped feeding pipe (18), and the upper end of the feeding pipe (18) is detachably connected with a cover body.