CN222677185U - A three-fluid spray dryer for preparing sodium ions - Google Patents

Abstract

The utility model discloses a three-fluid spray dryer for sodium ion preparation, which comprises a tower body, wherein a cyclone separator is arranged in the tower body, a drying bin is arranged between the top of the cyclone separator and the tower body, a hot air blower is arranged on the right side of the tower body, the output end of the hot air blower is connected with an input pipe, and the other end of the input pipe is inserted into the tower body and is fixedly connected with spiral exhaust. According to the utility model, the sodium ion solution is atomized and sprayed into the drying bin by matching with the spraying mechanism, and the spray liquid is contacted with high-temperature air due to the increase of the area of the spray liquid, so that quick drying is realized, meanwhile, the cyclone separator is started to suck the dried mixture and separate solid particles, the gas is discharged through the discharging mechanism, and the control panel is used for conveniently controlling the operation of equipment, so that the device has the advantages of more uniform contact between hot air and the spray liquid, higher drying efficiency and improvement of the working efficiency of the device.

Description

Three-fluid spray dryer for sodium ion preparation

Technical Field

The utility model relates to the technical field of spray dryers, in particular to a three-fluid spray dryer for sodium ion preparation.

Background

The existing three-fluid spray dryer is used for converting sodium ion solution or suspension into powder or particle form through a three-fluid spray technology, the dryer adopts a spray drying technology, the sodium ion solution or suspension is sprayed into tiny liquid drops, and then the tiny liquid drops are quickly dried in high-temperature high-speed air flow to be converted into powder or particle state, and the tiny liquid drops are usually formed by a sprayer, a drying chamber, a gas heater, a gas filter, a collector and other parts, and the three-fluid spray dryer has wide application in the fields of chemical industry, medicine, food and the like, particularly in the sodium ion preparation process, can realize high-efficiency continuous production, improve the production efficiency and the product quality, realize high-efficiency continuous production, and improve the production efficiency and the product quality.

But at present three fluid spray drier only sets up single air inlet port when the input hot-blast, and rotatory spraying end of cooperation realizes the drying to atomizing liquid, but because the area increase after the atomizing, single air inlet end leads to hot-blast and the liquid contact after the atomizing insufficient, drying efficiency is not good.

Disclosure of utility model

Aiming at the problems in the prior art, the utility model aims to provide a three-fluid spray dryer for preparing sodium ions, which has the advantages of more uniform contact between hot air and atomized liquid and higher drying efficiency.

In order to solve the problems, the utility model adopts the following technical scheme.

The utility model provides a three fluid spray dryer for sodium ion preparation, includes the tower body, the internally mounted of tower body has cyclone, be dry storehouse between cyclone's top and the tower body, the air heater is installed on the right side of tower body, the output of air heater is connected with the input tube, the other end of input tube is pegged graft to the inside of tower body and fixedly connected with spiral blast pipe, discharge mechanism is installed in the left side of tower body, discharge mechanism's input and cyclone's left side exhaust port fixed connection, spray mechanism is installed in the left side of tower body, spray mechanism cooperates with the internal connection of tower body, control panel is installed in the front of tower body.

As further description of the technical scheme, the spraying mechanism comprises a liquid storage tank, a booster pump and a three-fluid rotary spraying head, wherein one side of the liquid storage tank is fixedly connected with the tower body, the booster pump is fixedly connected to the top of the liquid storage tank, the input end of the booster pump is fixedly communicated with the liquid storage tank through a pipeline, the output end of the booster pump is rotationally connected with the three-fluid rotary spraying head through a pipeline, and the three-fluid rotary spraying head is positioned in the drying bin.

As a further description of the technical scheme, the three-fluid rotary spray head is provided with three spray nozzles at the bottom, and the output ends of the three spray nozzles incline towards the clockwise direction.

As further description of the technical scheme, the discharging mechanism comprises an induced draft fan, a connecting pipe and a dust filter, one side of the induced draft fan is fixedly connected with the tower body, the input end of the induced draft fan is fixedly connected with the output end of the dust filter through the connecting pipe, and the right side of the dust filter is fixedly connected with the left side exhaust port of the cyclone separator.

As a further description of the technical scheme, a pressure sensor is fixedly arranged inside the connecting pipe.

As a further description of the technical scheme, the spiral exhaust pipe is provided with evenly distributed air injection holes.

Compared with the prior art, the utility model has the advantages that:

According to the scheme, the air spraying holes in the outer side of the spiral exhaust pipe are matched with the cyclone separator to separate dry solids, so that the device has the advantages of being even in contact between hot air and atomized liquid, high in drying efficiency and high in working efficiency.

Drawings

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

FIG. 2 is a schematic cross-sectional elevation view of the present utility model;

FIG. 3 is a schematic view of a partial top view cross-section of the present utility model;

Fig. 4 is a partial bottom view of the present utility model.

The reference numerals in the figures illustrate:

1. A tower body; 2, cyclone separator, 3, drying bin, 4, air heater, 5, input pipe, 6, spiral exhaust pipe, 61, air jet hole, 7, exhaust mechanism, 71, induced draft fan, 72, connecting pipe, 721, pressure sensor, 73, dust filter, 8, spray mechanism, 81, liquid storage tank, 82, booster pump, 83, three-fluid rotary spray head, 831, spray nozzle, 9, control panel.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Referring to fig. 1-4, in the utility model, a three-fluid spray dryer for sodium ion preparation comprises a tower body 1, wherein a cyclone separator 2 is arranged in the tower body 1, a drying bin 3 is arranged between the top of the cyclone separator 2 and the tower body 1, a hot air blower 4 is arranged on the right side of the tower body 1, an output end of the hot air blower 4 is connected with an input pipe 5, the other end of the input pipe 5 is inserted into the tower body 1 and fixedly connected with a spiral exhaust pipe 6, a discharge mechanism 7 is arranged on the left side of the tower body 1, the input end of the discharge mechanism 7 is fixedly connected with a left exhaust port of the cyclone separator 2, a spray mechanism 8 is arranged on the left side of the tower body 1, the spray mechanism 8 is matched with the inner connection of the tower body 1, and a control panel 9 is arranged on the front surface of the tower body 1.

According to the utility model, the tower body 1 is used as a main body of the device, the spraying mechanism 8 and the air heater 4 are started to run synchronously, the air heater 4 is used for uniformly introducing high-temperature air into the drying bin 3 through the input pipe 5 and the spiral exhaust pipe 6, and simultaneously the spraying mechanism 8 is used for spraying sodium ion solution into the drying bin 3 in an atomized manner, as the area of atomized liquid is increased to be in contact with the high-temperature air, quick drying is realized, the cyclone separator 2 is started to suck the dried mixture and separate solid particles, and the air is discharged through the discharge mechanism 7, and the control panel 9 is used for conveniently controlling the operation of equipment, so that the device has the advantages of more uniform contact between hot air and the atomized liquid, higher drying efficiency and improvement of the working efficiency of the device, and the problems that in the prior art, only a single air inlet port is arranged when the hot air is input, the atomized liquid is dried through the cooperation of a rotating spraying end, but the hot air and the atomized liquid are insufficiently contacted due to the single air inlet end, and the drying efficiency is poor are solved.

Referring to fig. 2 and 4, the spraying mechanism 8 includes a liquid storage tank 81, a booster pump 82 and a three-fluid rotary spraying head 83, wherein one side of the liquid storage tank 81 is fixedly connected with the tower body 1, the booster pump 82 is fixedly connected to the top of the liquid storage tank 81, an input end of the booster pump 82 is fixedly communicated with the liquid storage tank 81 through a pipeline, an output end of the booster pump 82 is rotatably connected with the three-fluid rotary spraying head 83 through a pipeline, and the three-fluid rotary spraying head 83 is located in the drying bin 3.

In the utility model, the liquid storage tank 81 is used for storing sodium ion liquid, the booster pump 82 is started to pump and boost the liquid and output the liquid to the three-fluid rotary spray head 83, so that rotary atomization and spray out are realized, atomization is more uniform, contact with hot air is more uniform, and drying efficiency is higher.

Referring to fig. 2 and 4, three spray nozzles 831 are mounted at the bottom of the three-fluid rotary spray head 83, and the output ends of the three spray nozzles 831 are inclined in a clockwise direction.

In the utility model, three spray nozzles 831 and the output ends of the three spray nozzles 831 are inclined clockwise, so that the rotation of the three-fluid rotary spray head 83 is realized in the process of re-spraying.

Referring to fig. 1 and 2, the discharging mechanism 7 includes a draught fan 71, a connecting pipe 72 and a dust filter 73, one side of the draught fan 71 is fixedly connected with the tower 1, an input end of the draught fan 71 is fixedly connected with an output end of the dust filter 73 through the connecting pipe 72, and a right side of the dust filter 73 is fixedly connected with a left side exhaust port of the cyclone separator 2.

In the utility model, the induced draft fan 71 is started to pump the dust filter 73 into negative pressure through the connecting pipe 72, so that the separated air is pumped into the dust filter 73, a small amount of dust in the air is filtered and then discharged, and the air pollution is avoided.

Referring to fig. 2, a pressure sensor 721 is fixedly installed inside the connection pipe 72.

In the utility model, the pressure sensor 721 detects the pumping pressure in the connecting pipe 72, so that the blocking condition in the dust filter 73 can be monitored in real time, and the judgment and maintenance are convenient.

Referring to fig. 2 and 3, the spiral exhaust pipe 6 is provided with evenly distributed gas injection holes 61.

In the utility model, the whole exhaust of the spiral exhaust pipe 6 is radially sprayed through the air injection holes 61, so that the contact between the intake air and the water mist is more uniform.

The above description is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto. Any person skilled in the art, within the technical scope of the present disclosure, may apply to the present utility model, and the technical solution and the improvement thereof are all covered by the protection scope of the present utility model.

Claims (6)

1. The utility model provides a three-fluid spray dryer for sodium ion preparation, includes tower body (1), its characterized in that, internally mounted of tower body (1) has cyclone (2), be drying bin (3) between the top of cyclone (2) and tower body (1), air heater (4) are installed on the right side of tower body (1), the output of air heater (4) is connected with input tube (5), the other end of input tube (5) is pegged graft to the inside of tower body (1) and fixedly connected with spiral blast pipe (6), discharge mechanism (7) are installed in the left side of tower body (1), discharge mechanism's (7) input and cyclone's (2) left side exhaust port fixed connection, spray mechanism (8) are installed in the left side of tower body (1), spray mechanism (8) and the internal connection cooperation of tower body (1), control panel (9) are installed in the front of tower body (1).

2. The three-fluid spray dryer for sodium ion preparation, as claimed in claim 1, wherein the spraying mechanism (8) comprises a liquid storage tank (81), a booster pump (82) and a three-fluid rotary spraying head (83), one side of the liquid storage tank (81) is fixedly connected with the tower body (1), the booster pump (82) is fixedly connected to the top of the liquid storage tank (81), the input end of the booster pump (82) is fixedly communicated with the liquid storage tank (81) through a pipeline, the output end of the booster pump (82) is rotatably connected with the three-fluid rotary spraying head (83) through a pipeline, and the three-fluid rotary spraying head (83) is positioned in the drying bin (3).

3. A three-fluid spray dryer for sodium ion production as claimed in claim 2, wherein three spray nozzles (831) are mounted on the bottom of the three-fluid rotary spray head (83), and the output ends of the three spray nozzles (831) are inclined in a clockwise direction.

4. The three-fluid spray dryer for sodium ion preparation according to claim 1, wherein the discharging mechanism (7) comprises an induced draft fan (71), a connecting pipe (72) and a dust filter (73), one side of the induced draft fan (71) is fixedly connected with the tower body (1), the input end of the induced draft fan (71) is fixedly connected with the output end of the dust filter (73) through the connecting pipe (72), and the right side of the dust filter (73) is fixedly connected with the left exhaust port of the cyclone separator (2).

5. A three-fluid spray dryer for sodium ion production according to claim 4, wherein a pressure sensor (721) is fixedly installed inside the connection pipe (72).

6. The three-fluid spray dryer for sodium ion preparation as claimed in claim 1, wherein the spiral exhaust pipe (6) is provided with evenly distributed air injection holes (61).