CN219474340U - Carbon molecular sieve cooling arrangement - Google Patents

Abstract

The utility model discloses carbon molecular sieve cooling equipment, and relates to the technical field of molecular sieves. It comprises a cooling tank; the upper end of the cooling tank is provided with a feeding device; the lower end of the cooling tank is fixedly connected with a discharge block; in the cooling tank, the upper end of the material outlet block is fixedly connected with a sleeve; a sliding rod is connected in a sliding way in the sleeve; a plurality of adjusting devices are arranged on the outer side of the sleeve; the uppermost adjusting device comprises an umbrella rib, an umbrella cover and an umbrella slide tube; the umbrella slide tube is sleeved on the outer side of the sleeve in a sliding way; the outside of the sleeve is fixedly connected with the umbrella cover. The beneficial effects of the utility model are as follows: when the cooling device is used, the cooling device is convenient to adjust and better to cool, and is convenient to adapt to different temperature adjustment.

Description

Carbon molecular sieve cooling arrangement

Technical Field

The utility model relates to the technical field of molecular sieves, in particular to carbon molecular sieve cooling equipment.

Background

The carbon molecular sieve is a novel adsorbent developed in seventies of 20 th century, is an excellent nonpolar carbon material, is used for separating air and enriching nitrogen, and has the advantages of low investment cost, high nitrogen production speed, low nitrogen cost and the like compared with the traditional cryogenic high-pressure nitrogen production process by adopting a normal-temperature low-pressure nitrogen production process. And the carbon molecular sieve is often cooled down by cooling equipment, when the temperature of the cooled carbon molecular sieve is detected to be too high or too low, the traditional cooling equipment is inconvenient to adjust and adapt to use, the cooling effect does not reach the standard, and better cooling is inconvenient to adjust and use.

Disclosure of Invention

The utility model aims to solve the technical problems and provides carbon molecular sieve cooling equipment aiming at the technical defects. When the cooling device is used, the cooling device is convenient to adjust and better to cool, and is convenient to adapt to different temperature adjustment.

The technical scheme adopted by the utility model is as follows: providing a carbon molecular sieve cooling device comprising a cooling tank; the upper end of the cooling tank is provided with a feeding device; the lower end of the cooling tank is fixedly connected with a discharge block; in the cooling tank, the upper end of the material outlet block is fixedly connected with a sleeve; a sliding rod is connected in a sliding way in the sleeve; a plurality of adjusting devices are arranged on the outer side of the sleeve; the uppermost adjusting device comprises an umbrella rib, an umbrella cover and an umbrella slide tube; the umbrella slide tube is sleeved on the outer side of the sleeve in a sliding way; the outer side of the sleeve is fixedly connected with the umbrella cover; the inner side of the upper end of the umbrella rib is rotationally connected with the sleeve; the inner side of the lower end of the umbrella rib is rotationally connected with the umbrella slide tube; the outer side of the umbrella rib is fixedly connected with the umbrella cover; a chute is opened at the position of the umbrella slide tube outside the sleeve; a sliding block is vertically and slidably connected in the sliding groove and fixedly connected with the umbrella sliding tube; the sliding block is connected with the sliding rod in a sliding way; the plurality of adjusting devices have the same structure; inverted conical pipes are fixedly connected between adjacent adjusting devices; the two ends of the outer side of the cooling tank are communicated with ventilation pipes at the inverted conical pipe; the lower end of the sliding rod is provided with a driving device.

Further optimizing the technical scheme, the feeding device of the carbon molecular sieve cooling equipment comprises a funnel-shaped material shell; the middle part of the outer side of the material shell is fixedly connected with the opening at the upper end of the cooling tank; in the cooling tank, the lower end of the material shell is rotationally connected with a feeding block; the feeding block is provided with a funnel-shaped feeding port, and the feeding port and the feeding block are arranged on different axes; a motor is arranged on the material shell through a mounting frame; the output end of the lower end of the motor is fixedly connected with a driving shaft; the lower end of the driving shaft is fixedly connected with the upper end of the feeding block, and the driving shaft and the feeding block are on the same axis.

Further optimizing the technical scheme, the driving device of the carbon molecular sieve cooling equipment comprises a threaded block arranged through a bracket; the lower end of the sliding rod penetrates through the upper end of the discharge block, and the sliding rod is in sliding connection with the discharge port; the lower end of the sliding rod is rotationally connected with a bolt through a rotating shaft; the bolt is connected with the thread block in a threaded way.

Further optimizing the technical scheme, one side of a discharging block of the carbon molecular sieve cooling equipment is communicated with a discharging pipe; a control valve is arranged on the outer side of the discharging pipe; the upper end of the control valve and the discharging pipe are provided with temperature detection modules.

Further optimizing the technical scheme, one side of a ventilation pipe of the carbon molecular sieve cooling equipment is an air inlet pipe, and one side of the ventilation pipe is an air outlet pipe; the ventilation tube may be in communication with an external refrigerator appliance.

Further optimizing this technical scheme, carbon molecular sieve cooling arrangement's ejection of compact piece lower extreme fixedly connected with landing leg.

Further optimizing the technical scheme, the cooling tank of the carbon molecular sieve cooling equipment is provided with the filter screen on the ventilation pipes; the ventilation pipes are all positioned below the material shell and the inverted conical pipe.

Compared with the traditional cooling equipment, the utility model has the beneficial effects that:

1. the material shell, the material inlet, the cooling tank, the driving shaft and the motor are matched, the material is uniformly fed into the cooling tank, and then the material is matched with the shape of the umbrella cover, so that the cooling operation is more convenient;

2. the umbrella cover, the inverted conical tube, the material outlet block and the ventilation tube are matched, ventilation and heat exchange are carried out while movement is carried out, the contact area is large, and the heat exchange effect is better;

3. the temperature detection module, the bolts, the thread blocks, the slide bars, the sleeves, the sliding blocks, the sliding grooves, the umbrella sliding pipes and the umbrella ribs are convenient to adjust the angle, the temperature is changed better, the cooling is used, and the temperature can be adjusted when the outside air temperature is changed;

4. the position of the ventilation pipe is positioned at a position which is not touched by falling inertia of the carbon molecular sieve, so that the carbon molecular sieve is more convenient to cool; the ventilation tube may be in communication with an external refrigerator device with a higher cooling efficiency when in communication with the external refrigerator device.

Drawings

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

FIG. 2 is a schematic diagram of the internal structure of the cooling tank according to the present utility model;

FIG. 3 is a schematic view of the structure of the feed block of the present utility model;

FIG. 4 is a schematic view of the structure of the discharging pipe of the present utility model;

FIG. 5 is a schematic view of the structure of the rib and canopy of the present utility model;

in the figure, 1, a cooling tank; 2. a discharge block; 3. a sleeve; 4. a slide bar; 5. umbrella ribs; 6. an umbrella cover; 7. an umbrella slide tube; 8. a chute; 9. a slide block; 10. an inverted conical tube; 11. a ventilation pipe; 12. a material shell; 13. a feed block; 14. a feed inlet; 15. a motor; 16. a drive shaft; 17. a screw block; 18. a bolt; 19. a discharge pipe; 20. a control valve; 21. a temperature detection module; 22. a support leg; 23. and (5) a filter screen.

Detailed Description

The utility model will be described in further detail with reference to the drawings and the detailed description.

As shown in fig. 1-5, a carbon molecular sieve cooling apparatus includes a cooling tank 1; the upper end of the cooling tank 1 is provided with a feeding device; the lower end of the cooling tank 1 is connected with a discharging block 2; in the cooling tank 1, the upper end of the material outlet block 2 is fixedly connected with a sleeve 3; a slide bar 4 is connected in a sliding way in the sleeve 3; a plurality of adjusting devices are arranged on the outer side of the sleeve 3; the uppermost adjusting device comprises an umbrella rib 5, an umbrella cover 6 and an umbrella slide tube 7; the umbrella slide tube 7 is sleeved on the outer side of the sleeve 3 in a sliding way; the outer side of the sleeve 3 is fixedly connected with the umbrella cover 6; the inner side of the upper end of the umbrella rib 5 is rotationally connected with the sleeve 3; the inner side of the lower end of the umbrella rib 5 is rotationally connected with an umbrella slide tube 7; the outer side of the umbrella rib 5 is fixedly connected with the umbrella cover 6; a chute 8 is arranged at the position of the umbrella slide tube 7 outside the sleeve 3; a sliding block 9 is vertically and slidably connected in the sliding groove 8, and the sliding block 9 is fixedly connected with the umbrella sliding tube 7; the sliding block 9 is in sliding connection with the sliding rod 4; the plurality of adjusting devices have the same structure; an inverted conical tube 10 is fixedly connected between every two adjacent adjusting devices; the two ends of the outer side of the cooling tank 1 are communicated with ventilation pipes 11 at the inverted conical pipe 10; the lower end of the sliding rod 4 is provided with a driving device; the feeding device comprises a funnel-shaped material shell 12; the middle part of the outer side of the material shell 12 is fixedly connected with the opening at the upper end of the cooling tank 1; in the cooling tank 1, the lower end of the material shell 12 is rotatably connected with a feeding block 13; the feeding block 13 is provided with a funnel-shaped feeding port 14, and the feeding port 14 and the feeding block 13 are arranged on different axes; a motor 15 is arranged on the material shell 12 through a mounting frame; the output end of the lower end of the motor 15 is fixedly connected with a driving shaft 16; the lower end of the driving shaft 16 is fixedly connected with the upper end of the feeding block 13, and the driving shaft 16 and the feeding block 13 are on the same axis; the driving device comprises a threaded block 17 mounted by a bracket; the lower end of the slide bar 4 penetrates through the upper end of the discharge block 2, and the slide bar 4 is in sliding connection with the discharge port; the lower end of the slide bar 4 is rotatably connected with a bolt 18 through a rotating shaft; the bolt 18 is in threaded connection with the threaded block 17; one side of the material outlet block 2 is communicated with a material outlet pipe 19; a control valve 20 is arranged on the outer side of the discharging pipe 19; the upper end of the control valve 20, the discharging pipe 19 is provided with a temperature detection module 21; one side of the ventilation pipe 11 is an air inlet pipe, and one side of the ventilation pipe is an air outlet pipe; the ventilation pipe 11 may be in communication with an external refrigerator device; the lower end of the material outlet block 2 is fixedly connected with a supporting leg 22; the filter screen 23 is arranged on the ventilating pipes 11 at the cooling tank 1; the ventilation pipes 11 are positioned below the material shell 12 and the inverted conical pipe 10.

The umbrella rib 5, the umbrella cover 6, the umbrella slide tube 7 and the sleeve 3 form an umbrella structure, and the sleeve 3 has the function of an umbrella handle; the grooves formed at the upper ends of the feeding block 13 and the discharging block 2 are all in the shape shown in figure 3, so as not to influence the cooling;

when the cooling device is used, a carbon molecular sieve to be cooled is placed in a material shell 12, the carbon molecular sieve reaches a feeding block 13 communicated with the carbon molecular sieve, the carbon molecular sieve reaches the cooling tank 1 through a feeding port 14 in the structure of the feeding block 13, the feeding block 13 is connected with a motor 15 through a driving shaft 16, the motor 15 is started, the motor 15 drives the feeding block 13 to rotate, and the feeding block 13 drives the feeding port 14 to rotate, so that the carbon molecular sieve falling into the cooling tank 1 from the feeding port 14 uniformly falls into the cooling tank 1 in a rotating manner, is uniformly fed into the cooling tank 1, and is matched with the shape of an umbrella face 6, so that the cooling device is more convenient to cool and use;

when the carbon molecular sieve reaches the umbrella surface 6, the carbon molecular sieve can slide onto the inverted conical tube 10 correspondingly matched with the umbrella surface 6 and the inverted conical tube 10 according to the inclined surface arrangement of the umbrella surface 6 and then slide onto the umbrella surface 6, and the carbon molecular sieve circulates until reaching the material outlet block 2, and the temperature exchange is carried out in the carbon molecular sieve through the ventilation tube 11 while the carbon molecular sieve circulates, so that the temperature of the carbon molecular sieve is reduced, the cooling effect is achieved, the carbon molecular sieve moves in the cooling tank 1, and ventilation and heat exchange are carried out while the carbon molecular sieve moves, so that the contact area is large, and the heat exchange effect is better;

when the temperature detection module 21 detects that the temperature of the cooled discharged carbon molecular sieve is too high or too low, the bolt 18 is rotated on the threaded block 17 to move up and down, the bolt 18 drives the slide rod 4 rotationally connected with the bolt 18 to move up and down, the slide rod 4 slides up and down in the sleeve 3, the slide rod 4 drives the slide block 9 fixedly connected with the slide rod 4 to move up and down, the slide block 9 slides up and down in the slide groove 8, the slide block 9 drives the umbrella slide tube 7 fixedly connected with the slide block 7 to move up and down, the umbrella slide tube 7 drives the umbrella rib 5 to move up and down, the umbrella face 6 is unfolded when moving up, the inclination angle of the umbrella face 6 is reduced, the inclination angle of the umbrella face 6 is increased when moving down, when the cooled carbon molecular sieve is detected to be too high, the process of moving the umbrella face 6 is slower, the ventilation cooling time is longer, and the cooled temperature is reduced; when the cooled carbon molecular sieve is detected to be too low in temperature, the carbon molecular sieve moves downwards, the carbon molecular sieve with larger inclination angle of the umbrella cover 6 moves faster, ventilation and cooling time is shorter, the cooled carbon molecular sieve is heated, better cooling use is convenient to adjust, and the carbon molecular sieve can also be adjusted when the outside air temperature changes;

the position of the ventilation pipe 11 is positioned at a position which is not touched by falling inertia of the carbon molecular sieve, so that the carbon molecular sieve can be cooled more conveniently; one side of the ventilation pipe 11 is an air inlet pipe, and one side of the ventilation pipe is an air outlet pipe; the ventilation pipe 11 may communicate with an external refrigerator device, and the cooling efficiency is higher when communicating with the external refrigerator device.

It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.

Claims (7)

1. A carbon molecular sieve cooling apparatus, characterized in that: comprises a cooling tank (1); the upper end of the cooling tank (1) is provided with a feeding device; the lower end of the cooling tank (1) is connected with a discharging block (2); in the cooling tank (1), the upper end of the material outlet block (2) is connected with a sleeve (3); a sliding rod (4) is connected in a sliding way in the sleeve (3); a plurality of adjusting devices are arranged on the outer side of the sleeve (3);

the uppermost adjusting device comprises an umbrella rib (5), an umbrella cover (6) and an umbrella slide tube (7); the umbrella slide tube (7) is sleeved on the outer side of the sleeve (3) in a sliding way; the outer side of the sleeve (3) is fixedly connected with the umbrella cover (6); the inner side of the upper end of the umbrella rib (5) is rotationally connected with the sleeve (3); the inner side of the lower end of the umbrella rib (5) is rotationally connected with an umbrella slide tube (7); the outer side of the umbrella rib (5) is fixedly connected with the umbrella cover (6); a chute (8) is arranged at the position of the umbrella slide tube (7) outside the sleeve (3); a sliding block (9) is vertically and slidably connected in the sliding groove (8), and the sliding block (9) is fixedly connected with the umbrella sliding tube (7); the sliding block (9) is in sliding connection with the sliding rod (4); the plurality of adjusting devices have the same structure;

an inverted conical tube (10) is fixedly connected between every two adjacent adjusting devices; the two ends of the outer side of the cooling tank (1) are communicated with ventilation pipes (11) at the inverted conical pipe (10); the lower end of the sliding rod (4) is provided with a driving device.

2. The carbon molecular sieve cooling apparatus of claim 1, wherein: the feeding device comprises a funnel-shaped material shell (12); the middle part of the outer side of the material shell (12) is fixedly connected with the opening at the upper end of the cooling tank (1); in the cooling tank (1), the lower end of the material shell (12) is rotationally connected with a feeding block (13); the feeding block (13) is provided with a funnel-shaped feeding hole (14), and the feeding hole (14) and the feeding block (13) are arranged on different axes; a motor (15) is arranged on the material shell (12) through a mounting rack;

the output end of the lower end of the motor (15) is fixedly connected with a driving shaft (16); the lower end of the driving shaft (16) is fixedly connected with the upper end of the feeding block (13), and the driving shaft (16) and the feeding block (13) are on the same axis.

3. The carbon molecular sieve cooling apparatus of claim 1, wherein: the driving device comprises a threaded block (17) mounted by a bracket; the lower end of the sliding rod (4) penetrates through the upper end of the discharging block (2), and the sliding rod (4) is in sliding connection with the discharging hole; the lower end of the sliding rod (4) is rotationally connected with a bolt (18) through a rotating shaft; the bolt (18) is in threaded connection with the threaded block (17).

4. The carbon molecular sieve cooling apparatus of claim 1, wherein: one side of the material outlet block (2) is communicated with a material outlet pipe (19); a control valve (20) is arranged on the outer side of the discharging pipe (19); the upper end of the control valve (20) and the discharging pipe (19) are provided with a temperature detection module (21).

5. The carbon molecular sieve cooling apparatus of claim 1, wherein: one side of the ventilation pipe (11) is an air inlet pipe, and one side of the ventilation pipe is an air outlet pipe; the ventilation pipe (11) can be communicated with an external refrigerator device.

6. The carbon molecular sieve cooling apparatus of claim 1, wherein: the lower end of the material outlet block (2) is fixedly connected with a supporting leg (22).

7. The carbon molecular sieve cooling apparatus of claim 2, wherein: the filter screen (23) is arranged on the ventilating pipes (11) at the cooling tank (1); the ventilation pipes (11) are all positioned below the material shell (12) and the inverted conical pipe (10).