KR20210123061A - Nanocellulose concentration and condensation system - Google Patents

Abstract

The present invention relates to a nanocellulose concentration and condensation system. The nanocellulose concentration and condensation system of the present invention enables continuous and uniform concentration of a nanocellulose liquid raw material by using a parallel multi-stage ceramic filter equipped with a pump for each branch pipe. In addition, since a waste heat is condensed and then recycled in drying the nanocellulose liquid raw material by spraying, drying efficiency can be increased. The nanocellulose concentration and condensation system comprises: a raw material storage tank (1); a supply unit (2); a filtering unit (3); a waste liquid storage tank (4); a backwashing unit (5); a drying tank (6); and a condensing circulation unit (7).

Description

Nanocellulose concentration and condensation system

The present invention relates to the production of nanocellulose, in detail, using a parallel multi-stage ceramic filter equipped with a pump for each branch pipe so that continuous and uniform concentration of the nanocellulose liquid raw material is achieved, and when drying it by spraying, waste heat It relates to a nanocellulose concentration and condensation system that can increase drying efficiency by condensing and recycling.

Nanocellulose refers to nano-micrometer-sized rod-shaped particles or fibers in which cellulose chains form a bundle and are tightly bound. In general, nanocellulose is a bio-based material having a tensile modulus similar to that of steel or Kevlar, a low density, and a large specific surface area.

Because of these advantages, it can be applied to various fields such as the packaging industry, the paper industry, filtration devices, artificial skin, and cosmetics.

Nanocellulose can also be produced from bacteria such as Acetobacter xylinum, but bacterial culture is expensive and difficult to produce in large quantities due to low volume-to-volume yields. -down processing).

The isolation method for obtaining nano-cellulose from cellulose, which occupies the largest amount of organic matter on earth, can be largely divided into chemical treatment and physical treatment. The chemical treatment method is an acid hydrolysis method to make nano-sized cellulose by removing the amorphous region of cellulose using a strong acid. Physical methods include high-intensity ultrasonic treatment, high-pressure refiner treatment, grinder treatment, and high-pressure homogenizer treatment. In addition, it is possible to isolate nano-cellulose using an enzyme.

After all, since the nanocellulose obtained in this way has a liquid form, in order to utilize it, it must be made into a powder form through drying, and for this purpose, a concentration process and a process using a spray dryer are utilized.

However, during filtering to separate moisture from liquid raw materials, cellulose nanoparticles often clogged and stuck to the filter. Since it showed a low drying yield along with thermal efficiency, a method for improving this was required.

Laid-Open Patent Publication No. 10-2010-0121640 (2010.11.18) Registered Patent Publication No. 10-0540026 (2005.12.23)

The present invention was created to solve the above problems, and an object of the present invention is to enable continuous and uniform concentration of nanocellulose liquid raw materials by using a parallel multi-stage ceramic filter equipped with a pump for each branch pipe. It is to provide a nanocellulose concentration and condensation system that can increase drying efficiency by condensing and recycling waste heat in drying it by spraying.

For the above purpose, the present invention is a raw material storage tank in which the nanocellulose liquid raw material is stored, the lower end is narrowed, the circulation tube is formed, and the return tube is formed at the upper end; a supply unit connected to the circulation pipe to suck and transport the liquid raw material in the raw material storage tank; One end and the other end are connected to the supply part and the return pipe, respectively, and a plurality of ceramic filters that transmit the liquid component to the outside through the pressure of the supplied liquid raw material are formed in series in a plurality of conveying pipes, and the ceramic filters are surrounded a filtering unit having a casing for collecting and discharging the liquid components passing through the water; a waste liquid storage tank connected to the casing to store the collected liquid components; a backwash unit having one end and the other end connected to the waste liquid storage tank and the casing, respectively, and pressurizing the liquid component of the waste liquid storage tank into the casing; The liquid raw material concentrated in the raw material storage tank is sprayed with high-temperature air to dry it, the lower end is narrowed and a discharge pipe is formed, and a supply pipe through which high-temperature air is supplied together with the liquid raw material at the upper end is connected to the supply pipe on the inside a drying tank formed with a spraying unit for spraying hot air together with a liquid raw material; A first cyclone unit connected to the discharge pipe and separating and collecting the nanoparticles by applying centrifugal force to the nanoparticles contained in the air through a swirling flow of air, a condenser for condensing the air passing through the first cyclone unit, and the condenser passing through the condenser a condensing circulation unit having a second cyclone unit for removing foreign substances contained in the air through a swirling flow of air, and a heater and a blower for heating the air passing through the second cyclone unit and supplying it to the supply pipe; It is characterized in that it includes.

At this time, the condenser includes an inlet through which air passing through the first cyclone is introduced on one side and an outlet through which dry air is discharged on the other side, and a cylindrical body inclined downward to the other side is connected to the inlet and outlet. a plurality of condensing pipes having condensing fins formed therein, a trap of a multi-layer sloping plate structure installed inside the outlet and condensing moisture in the air in contact with the surface, and the inlet and lower sides of the outlet A drain unit for discharging the formed condensate, and a cooling water inlet pipe and a cooling water outlet pipe passing through the body and cooling the condensate pipe through the cooling water flow, respectively, are connected to the cooling water inlet pipe and the cooling water outlet pipe to circulate the cooling water It is preferable to further include a chiller and a cooling pump.

In addition, the filtering unit is made in a cylindrical shape, and an inlet connected to the supply pipe on one side and an outlet connected to the transfer pipe on the other side are formed at a relatively lower height than the inlet, and bubbles mixed with the raw material are formed therein. It is preferable to include an air vent having a diaphragm plate having an inclined structure for inducing a rise by colliding with it, and an air vent having a vent valve communicating with the atmosphere upward.

In addition, the raw material is temporarily accommodated, and the inlet and the outlet are formed in the tangential direction of the outer circumferential surface to one side and the other side of the cylindrical body having a narrow bottom and formed with a sludge outlet, respectively, a magnetic body formed along the side wall, and the inlet and outlet to the inside a pre-processing unit having a screen mesh plate installed in a transverse form and pre-processing the raw material accommodated in the raw material storage unit; It is preferable to further include

In addition, the raw material storage tank is installed in a form surrounding the outside and further comprises a heater for heating the internal raw material, a mixer for stirring the received raw material, and a level sensor for measuring the level of the received raw material, and the supply unit supplies the raw material A feeding pump that transports and a booster pump for secondary boosting of the raw material discharged through the feeding pump, are installed between the feeding pump and the booster pump and between the booster pump and the ceramic filtering unit, respectively, and operate when a pressure greater than a set pressure is applied It is preferable to include a relief valve for transferring to the return pipe.

In manufacturing the dried powdered nanocellulose product through the present invention, the ceramic filter is used to minimize the liquid component so that the drying process is performed, and the hot air supplied for drying is condensed and recycled to reduce operating costs and improve drying efficiency. Not only can it be increased, but it is also possible to produce nano-cellulose in powder form with a high yield.

In addition, long-term reliable operation can be achieved by cleaning the nano-filter for hot air recovery and pressure maintenance in the drying process and preventing the internal deposition of nano-cellulose powder.

In addition, it is possible to increase the pressure difference of all filters during the filtering process and automatically backwash the clogged filter to increase the separation efficiency of moisture in the liquid raw material containing nano cellulose, and prevent the hydrophilic nano cellulose particles from sticking to the filter and clogging. can be effectively prevented.

1 is a schematic diagram of the present invention;
2 is a plan view showing the structure of a filtering unit according to the present invention;
3 is a side view showing the structure of a filtering unit according to the present invention;
4 is a conceptual view showing the liquid component transfer direction of the filtering unit according to the present invention;
5 is a conceptual diagram showing the structure of a drying tank and a condensing circulation unit according to the present invention;
6 is a cross-sectional view showing the structure of the condenser according to the present invention;
7 is a schematic diagram showing a detailed configuration of a filtering unit according to the present invention;
8 is a cross-sectional view showing the structure of the pre-processing unit according to the present invention;
9 is a cross-sectional view showing an air vent structure according to the present invention.

Hereinafter, the configuration of the nanocellulose concentration and condensation system of the present invention will be described in detail with reference to the accompanying drawings.

1 is an opening view of the present invention, in which the present invention is a system for greatly improving the concentration and drying efficiency of raw materials in commercializing liquid nanocellulose raw materials in powder form, together with a filtering unit 3 for concentrating raw materials. It includes a drying tank 6 and other accessories for drying the concentrated raw material by spraying it with hot air.

2 is a plan view showing the structure of the filtering unit according to the present invention, and FIG. 3 is a side view showing the structure of the filtering unit according to the present invention. The configuration of the raw material storage tank 1, the supply part 2, the filtering part 3, the waste liquid storage tank 4 and the backwashing part 5 provided to increase the temperature is shown.

The raw material storage tank 1 is a tank in which the liquid nanocellulose raw material to be treated in the present invention is stored. The lower end is narrowed, the circulation tube 11 is connected, and the return tube 12 is connected to the upper side, respectively.

7 is a schematic diagram showing a detailed configuration of a filtering unit according to the present invention, and shows a state in which an additional configuration for improving performance and protecting a device is added.

At this time, it is preferable to heat and stir the received raw material to an appropriate temperature in order to prevent precipitation and agglomeration of the nanocellulose component contained in the liquid raw material and to increase the filtering efficiency.

Accordingly, a heater 13 is installed to surround the raw material storage tank 1 to the outside to heat the internal raw material, and a mixer 14 to stir the received raw material is installed to ensure proper fluidity. It is preferable to continuously stir the raw materials together to achieve a homogeneous distribution of the nanocellulose component, and as will be described later, to measure the amount of raw materials accommodated in the raw material storage tank 1 when the raw materials are concentrated over multiple rounds. A level sensor 15 for measuring the level may be further included.

At this time, it is preferable that the level sensor 15 is an ultrasonic sensor installed downwardly at the upper end of the raw material storage tank in consideration of the viscosity increase characteristics according to the concentration of the raw material.

A supply part 2 connected to the circulation pipe 11 to suck and transport the liquid raw material of the raw material storage tank 1 is configured. This supply unit 2 is a pump that actually transports the raw material and may be configured as a single pump, but since a certain level of pressure is required to filter moisture in the raw material, a feeding pump 21 that primarily boosts the pressure while transferring the raw material and a booster pump 22 for secondary boosting the raw material discharged through the feeding pump 21 .

The raw material transferred through the supply unit 2 is pressurized to the filtering unit 3 for water filtering. The filtering unit 3 has one end and the other end connected to the supply unit 2 and the return pipe 12, respectively, to filter moisture in the raw material, and then the separated moisture is transferred to a waste liquid storage tank 4 to be described later, and The raw material from which moisture is separated and concentrated is re-supplied to the raw material storage tank 1 through the return pipe 12 .

In the present invention, the ceramic filter 32 that passes only moisture without passing through the nanocellulose through the pressure of the supplied liquid raw material filters only the moisture of the raw material through the transfer pipe 31 formed in series with a plurality, the accompanying drawings In a preferred embodiment, three ceramic filters 32 are connected in series to the transfer pipe 31, but the number may be appropriately adjusted.

A casing is surrounded to the outside of the ceramic filter 32 to transfer the permeated moisture, and only the liquid components that have passed through the ceramic filter 32 from the inside to the outside are collected and discharged.

Preferably, as shown in FIG. 3, the three ceramic filters 32 are connected in series so that moisture filtering is performed over the third order, but as shown in FIG. 2, the three ceramic filters 32 described above are again divided into three in parallel. By allowing the filtering to be performed, the reduction in efficiency due to filter occlusion is reduced and the filtering is performed in a short time. At this time, each branch pipe for parallel filtering may be provided with a supply unit to promote continuity of work, such as performing filtering through another branch pipe when maintaining the ceramic filter for one selected branch pipe.

Of course, it is also possible to supply raw materials to all branch pipes connected in parallel through one supply part. It is possible to reduce the occurrence of problems due to clogging of the ceramic filter.

The liquid component passing through the ceramic filter 32 moves along the inside of the casing 33 , and is collected and stored in the waste liquid storage tank 4 connected to the casing.

Since the nanocellulose component blocks the micropores of the ceramic filter 32 over time and increases the pressure, for this purpose, the liquid component of the waste liquid storage tank 4 is reversed through the casing 33 through the ceramic filter 32 Filtering performance can be restored by backwashing the clogged part by supplying pressure to the side.

That is, one end and the other end are connected to the waste liquid storage tank 4 and the casing 33, respectively, and the pump is a backwashing unit 5 that pressurizes and transfers the liquid component of the waste liquid storage tank 4 into the casing 33. to additionally install

4 is a conceptual view showing the liquid component transfer direction of the filtering unit according to the present invention. FIG. 4 (a) is the flow of the liquid in the process of filtering the raw material, and FIG. 4 (b) is the backwashing of the ceramic filter 32. The flow of the liquid in the process is shown respectively.

That is, the nanocellulose raw material stored in the raw material storage tank 1 is continuously dehydrated through the filtering unit 3, but the performance of the ceramic filter is maintained through backwashing according to the degradation of the filtering unit 3, As shown in Fig. 4(a), as the supply unit 2 operates, only moisture in the raw material passes through the ceramic filter 32 and is transferred to the waste liquid storage tank 4, and the concentrated raw material is returned to the raw material storage tank 1 .

Thereafter, when the pressure inside the ceramic filter 32 rises according to the clogging of the ceramic filter 32, the operation of the supply unit 2 is stopped and the backwash unit 5 is operated, and as shown in FIG. 4(b), the waste liquid The water contained in the storage tank 4 is pressurized to the outside of the ceramic filter 32 through the inside of the casing 33 and transmitted to the inside, so that the ceramic filter 32 blocked from the inside through the nanocellulose component is washed.

Similarly, as the filtering unit 3 is provided in parallel as shown in FIG. 2 , the casing 33 and the waste liquid storage tank 4 are connected through a branch pipe, and the liquid component is supplied to all branch pipes through one backwashing unit. It is preferable to provide a backwashing unit for each branch pipe rather than a method, so that the clogged ceramic filter can be washed evenly.

At this time, a control valve 37 is installed in a pipe connecting the casing 33 and the waste liquid storage tank 4 , and a discharge valve 37 is installed in a portion connecting the backwashing unit 5 and the casing 33 , respectively. Therefore, it is self-evident that backflow can be prevented by properly opening and closing them in the filtering process and backwashing process.

In the case of the ceramic filter 32, between the feeding pump 21 and the booster pump 22, the booster pump 22 and the ceramic filter ( 32), a relief valve (R) is installed between each of which is automatically opened when a pressure greater than a set value is applied and reduces the pressure to a set value or less by transferring the supplied raw material to the return pipe (12).

That is, when the nanocellulose raw material accommodated in the raw material storage tank 1 is transferred to the filtering unit 3 through the supply unit 2, the relief valve R, which is a safety valve, is 10 bar to prevent damage to the inside of the ceramic filter 32. It is set to open at the correct level, and the raw material according to the pressure over is transferred to the raw material storage tank (1).

In addition, since the ceramic filter 32 may be damaged even by the pressure of the backwashing unit 5 during backwashing, a relief valve R is also provided on the output side of the backwashing unit 5 to pressurize the pressure higher than the set pressure. However, the relief valve (R) installed in the backwash unit (5) is configured to return the liquid to the waste liquid storage tank (4) when opened.

At this time, a pressure gauge 34 is installed in the transfer pipe 31 to measure the degree of blockage of the ceramic filter 32 from the outside, and a flow meter ( 35) so that the amount of stored water and the amount required for backwashing can be known.

5 is a conceptual diagram showing the structure of a drying tank and a condensing circulation unit according to the present invention. As described above, the nanocellulose component and water contained in the raw material are removed in a significant proportion through the filtering unit 3, and the nanocellulose component is concentrated. In the agglomerated state, it is dried through hot air and commercialized in powder form, but shows a configuration that can increase drying efficiency by recirculating hot air.

The drying tank 6 is a tank for drying the liquid raw material concentrated in the raw material storage tank 1 with high-temperature air and drying it to make a powder product. It is configured to effectively collect and discharge the product, and it is connected to the supply pipe 61 in which high-temperature air is supplied together with the liquid raw material at the top and the supply pipe 61 inwardly to spray the high-temperature air together with the liquid raw material. A spraying unit 63 is provided.

It is preferable to use a spray of a rotary spray method for even drying of the raw material, and the basic drying principle of this spray method is known through the applicant's Registered Patent No. 10-1929928 (2018.12.11), and in the present invention, In order to prevent the gist of the invention from being obscured, specific details about the drying principle and the spraying unit 63 will be omitted.

In the conventional case, waste heat is often thrown away as the air remaining after drying is discharged to the atmosphere in such a spray-type dryer. In order to recycle the remaining heat, a high-level filtering means is required. In the present invention, the condensing circulation unit 7 is configured to effectively recycle heat and save energy without requiring a high-level filtering means among methods to solve this problem.

The condensed circulation unit 7 is connected to the discharge pipe 62 and is discharged through the first cyclone unit 71 that separates and collects by applying centrifugal force to the nanoparticles contained in the air through the swirling flow of air. will recover

The air that has passed through the first cyclone unit 71 passes through the condenser 72, moisture is removed, and becomes dry, and foreign substances contained in the air are removed through the swirling flow of the air that has passed through the condenser 72. Foreign matter is removed through the second cyclone unit 73 that do.

The first cyclone part 71 and the second cyclone part 73 have no separate movable part or power part compared to other centrifugal force-using devices that mechanically apply centrifugal force to particles by installing rotary blades in a filter or structure. It is possible to separate nanoparticles and foreign substances smoothly.

6 is a cross-sectional view showing the structure of the condenser according to the present invention.

In the condenser 72 of the present invention, an inlet 721 through which the air that has passed through the first cyclone unit 71 is introduced to one side and an outlet 722 through which dry air is discharged to the other side are formed on the other side of the condenser 72. A plurality of condensing pipes 723 having a photo cylindrical body, crossing the inside of the body and connecting the inlet 721 and the outlet 722 to form an air passage but having a condensing pin 7231 inside ) is provided.

That is, air passes through the condensing pipe 723 and the cooling water flows outside the condensing pipe 723 and inside the body, so that heat exchange between the air and the cooling water is made, and the condensing pipe 723 passes through Condensing the air to remove moisture, but as the cross section of the condensing fins 7231 are installed inside the condensing pipe 723, the contact area of the air passing through is widened and the condensation efficiency is maximized.

At this time, a trap 724 having a multi-layer swash plate structure for condensing moisture in the air in contact with the surface is installed inside the outlet 722 to finally remove moisture in the discharged air. In particular, the trap 724 is inclined upward toward the outlet 722 so that the air moves upward and is discharged, but water droplets condensed on the surface fall to the lower side and collect.

In particular, as mentioned above, as the body of the condenser 72 is inclined downward to the other side as a whole, the collected water is easily collected to the lower side of the outlet part 722 side, and the inlet part 721 and the outlet part 722 lower side. The condensed water is discharged to the outside through the formed drain part 725 .

In addition, a cooling water inlet pipe 726 and a cooling water outlet pipe 727 are formed in the body to cool the condensing pipe 723 through the cooling water flow outside the internal condensing pipe 723, and the cooling water inlet pipe 726 ) and a water cooling structure of the condenser 72 such as a chiller 75 and a cooling pump 76 for circulating cooling water connected to the cooling water outlet pipe 727 are provided.

At this time, it is preferable to measure the temperature and humidity state in the temperature and humidity sensor 77 in the air pipe and to mount the dew point sensor 78 in the condenser 72 part to control the cooling pump 76 so as to maintain an appropriate dew point temperature. That is, the degree of moisture generation is calculated through the temperature-humidity sensor 77 and the dew point sensor 78, but when the detected moisture generation is small, the amount of cooling water is adjusted with the cooling pump 76 so that a large amount of moisture can be discharged.

8 is a cross-sectional view showing the structure of the pre-processing unit according to the present invention, in the present invention, the pre-processing unit 8 is configured to perform a secondary filtering operation of foreign substances among the raw materials in the raw material storage tank 1, The included solid foreign matter has difficulty in separating well and may cause problems when it flows into the filtering unit. By supplying to 3), the safety and lifespan of the filtering part are extended.

This pretreatment unit 8 basically removes foreign substances through three filtering means, such as a cyclone structure, a ferromagnetic screen collector, and a screen mesh, and specifically, the raw material is temporarily accommodated, and the lower end is narrowed and the sludge outlet 83 ), the inlet 81 and the outlet 82 are formed in the tangential direction of the outer circumferential surface to one side and the other side of the cylindrical body, respectively, and the body is formed in a cyclone structure in which a vortex is generated between the inlet 81 and the outlet 82. .

In addition, by forming a strong magnetic body 85 along the sidewall of the main body, it is possible to effectively remove the metal component in the raw material together with the centrifugal force due to the vortex, and the screen mesh plate 84 installed in a form that crosses the inlet and the outlet inside. Installed to physically filter out foreign substances from the raw materials in which the flow occurred. The separated foreign substances are collected downward by specific gravity and discharged through the sludge outlet 83 .

The configuration indicated by A in the accompanying drawings may be a separate temporary storage tank, but preferably it may be a raw material storage tank 1, and when the pre-processing unit 8 is provided in front of the raw material storage tank 1, a centrifugal separator is usually You will receive the raw material that has passed (C).

9 is a cross-sectional view showing an air vent structure according to the present invention.

As mentioned above, a mixer 14 is provided in the raw material storage tank 1 and as the received raw material is stirred, air is mixed into the raw material, and when it is supplied to the filtering unit 3 through the supply unit 2, the As the bubble repeats compression and expansion, it gives an impact to the ceramic filter 32 to cause damage, interferes with maintaining a constant pressure, and may impair the filtering efficiency. It is preferable to install an air vent (36).

The air vent 36 is a tank structure having a cylindrical shape, and has an inlet connected to the supply pipe 61 on one side and an outlet connected to the transfer pipe 31 on the other side and formed at a relatively lower height than the inlet. do. This is a structure in which the lower raw material that does not contain air bubbles can be discharged preferentially as the air bubbles mixed in the raw material have a tendency to rise. A vent valve 364 for discharging air while communicating with the atmosphere upwards is formed with the last plate 363 .

That is, the diaphragm plate 363 is provided at a position where the raw material introduced from the inlet can come into contact with it and has an upward inclination toward the outlet, so that the liquid component of the contacted raw material is lowered, and the bubble component is separated after collision and guided upward, The separated air bubbles are discharged to the atmosphere through the vent valve 364, and the raw material is supplied to the filtering unit in a state in which air components are excluded as much as possible.

As mentioned above, the concentration of the raw material according to the present invention reflects the level of the received concentrate (raw material) by installing the level sensor 15 on the upper part of the raw material storage tank 1 to perform the first to third backwashing. . That is, the level sensor 15 using ultrasound measures the height of the received raw material, and when the set height is sensed, water is supplied through the backwashing unit 5 .

In addition, it is obvious that the control unit 9 connected to the aforementioned electrical and electronic components is provided for controlling the system according to the present invention. In particular, in controlling the aforementioned various pumps, that is, the cooling pump 76 including the supply unit 2 and the backwash unit 5, the control unit 9 is configured to slowly increase the flow rate instead of rapidly operating it. It is desirable to control In particular, abrupt operation of the pumps of the supply unit 2 and the backwash unit 5 may cause damage to the ceramic filter 32 and shorten the lifespan, so it is necessary to control the pump to prevent this.

The rights of the present invention are not limited to the above-described embodiments, but are defined by the claims, and those of ordinary skill in the art can make various modifications and adaptations within the scope of the claims. it is self-evident

1: Raw material storage tank 11: Circulation tube 12: Return tube
13: heater 14: mixer
15: level sensor
2: supply unit 21: feeding pump 22: booster pump
3: filtering unit 31: transfer pipe 32: ceramic filter
33: casing 34: pressure gauge
35: flow meter 36: air vent
361: entrance 362: exit
363: diaphragm plate 364: vent valve
37: control valve 38: discharge valve
4: Waste liquid storage tank
5: Backwashing unit
6: drying tank 61: supply pipe 62: discharge pipe
63: injection unit
7: condensing circulation unit 71: first cyclone unit 72: condenser
721: inlet 722: outlet
723: condensing tube 724: trap
725: drain unit 726: cooling water inlet pipe
727: coolant outlet pipe 73: second cyclone unit
74: blower 75: chiller
76: cooling pump 77: temperature and humidity sensor
78: dew point sensor 79: heater
8: preprocessor 81: inlet 82: outlet
83: sludge outlet 84: screen mesh plate
85: magnetic material
9: Control unit R: Relief valve C: Centrifuge

Claims (5)

a raw material storage tank 1 in which the nanocellulose liquid raw material is stored, the lower end is narrowed, the circulation tube 11 is formed, and the return tube 12 is formed at the upper end;
a supply part (2) connected to the circulation pipe (11) for sucking and transferring the liquid raw material of the raw material storage tank (1);
One end and the other end are connected to the supply part 2 and the return pipe 12, respectively, and a plurality of ceramic filters 32 for passing the liquid component to the outside through the pressure of the supplied liquid raw material are formed in series. a filtering unit (3) having a transfer pipe (31) and a casing (33) for collecting and discharging liquid components that have passed around the ceramic filter (32);
a waste liquid storage tank (4) connected to the casing (33) to store the collected liquid components;
a backwash unit (5) having one end and the other end connected to the waste liquid storage tank (4) and the casing (33), respectively, and transferring the liquid components of the waste liquid storage tank (4) to the inside of the casing (33) under pressure;
The liquid raw material concentrated in the raw material storage tank 1 is sprayed and dried with high-temperature air, the lower end is narrowed and the discharge pipe 62 is formed, and the high-temperature air is supplied with the liquid raw material at the upper end of the supply pipe 61 and a drying tank 6 connected to the supply pipe 61 inside and provided with an injection unit 63 for injecting high-temperature air together with a liquid raw material;
The first cyclone unit 71 connected to the discharge pipe 62 and separated and collected by applying centrifugal force to the nanoparticles contained in the air through the swirling flow of air, and the air passing through the first cyclone unit 71 A condenser 72 for condensing , a second cyclone unit 73 that removes foreign substances contained in the air through a swirling flow of air that has passed through the condenser 72, and the second cyclone unit 73 passes through a condensing circulation unit (7) having a heater (79) and a blower (74) for heating one air and supplying it to the supply pipe (61); Nanocellulose concentration and condensation system comprising a.
According to claim 1,
The condenser 72 is
A cylindrical body having an inlet 721 through which air that has passed through the first cyclone unit 71 is introduced on one side and an outlet 722 through which dry air is discharged to the other side is formed and inclined downward to the other side; The inlet 721 and the outlet 722 are connected to form an air passage, but a plurality of condensing pipes 723 having condensing pins 7231 formed therein, are installed inside the outlet 722 and are in contact with the surface A trap 724 having a multi-layer sloping plate structure for condensing moisture in the air, a drain 725 for discharging condensed water formed below the inlet 721 and outlet 722, respectively, and cooling water passing through the body and a cooling water inlet pipe 726 and a cooling water outlet pipe 727 for cooling the condensing pipe 723 through the flow,
Nanocellulose concentration and condensation system, characterized in that it further comprises a chiller (75) and a cooling pump (76) connected to the cooling water inlet pipe (726) and the cooling water outlet pipe (727) to circulate the cooling water.
According to claim 1,
The filtering unit 3,
It has a cylindrical shape, and an inlet 361 connected to the supply pipe on one side and an outlet 362 connected to the transfer pipe 31 on the other side and formed at a relatively lower height than the inlet are formed inside, Nanocellulose concentration and condensation, characterized in that it comprises an air vent 36 formed with a diaphragm plate 363 having an inclined structure to induce a rise by colliding the mixed bubbles, and a vent valve 364 communicating with the atmosphere upward. system.
According to claim 1,
The raw material is temporarily accommodated, and the inlet 81 and the outlet 82 are formed in the tangential direction of the outer circumferential surface to one side and the other side of the cylindrical body having a narrow lower end and a sludge outlet 83, respectively, and a magnetic body 85 formed along the side wall ) and a screen mesh plate 84 installed in a form crossing the inlet and the outlet inside, and a pre-processing unit 8 for pre-processing the raw material accommodated in the raw material storage unit; Nanocellulose concentration and condensation system, characterized in that it further comprises.
According to claim 1,
The raw material storage tank (1),
It is installed in a form surrounding the outside and further comprises a heater 13 for heating the internal raw material, a mixer 14 for stirring the received raw material, and a level sensor 15 for measuring the level of the received raw material,
The supply unit 2 includes a feeding pump 21 for transferring raw materials, a boosting pump 22 for secondary boosting of the raw material discharged through the feeding pump 21, the feeding pump 21 and the boosting pump 22 ) and between the booster pump 22 and the ceramic filtering unit 3 and operates when a pressure greater than a set pressure is applied to transfer the raw material to the return pipe 12, characterized in that it comprises a relief valve (R). Nanocellulose Concentration and Condensation System.

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