KR20170088619A

KR20170088619A - Germanium salt manufacturing apparatus and manufacturing method

Info

Publication number: KR20170088619A
Application number: KR1020160008726A
Authority: KR
Inventors: 어온석; 강호욱
Original assignee: (주)나노피엔씨
Priority date: 2016-01-25
Filing date: 2016-01-25
Publication date: 2017-08-02
Also published as: KR101775423B1

Abstract

A germanium salt production apparatus and a manufacturing method using the same are disclosed.
Among the germanium salt production apparatus and the manufacturing method using the same, the germanium salt production apparatus includes a vacuum chamber supported on a frame; A porous drying furnace rotatably installed in the vacuum chamber and containing salt therein; A drying heater installed in the vacuum chamber to heat and dry the salt contained in the drying furnace; And a plasma generating unit for generating plasma into the vacuum chamber while being installed in the vacuum chamber so that germanium ions are absorbed by the salt as the ions of germanium contained in the vacuum chamber are activated, will be.

Description

[0001] Germanium salt manufacturing apparatus and manufacturing method using the same [0002]

The present invention relates to a germanium salt production apparatus and a manufacturing method using the same.

In particular, the present invention relates to a germanium salt production apparatus capable of simply manufacturing germanium salt in one apparatus and a germanium salt production method produced thereby.

Patent Document 10-2009-0002422 discloses that germanium salt is dissolved in gneutic ore water to make ghanynite salt ore, poured into a heat-resistant vessel, and germanium ore is put into the vessel and heated It is described that germanium salt containing a germanium component is obtained as moisture is evaporated. These germanium salts are known to be one of the functional salts that decontaminate heavy metals and toxic substances.

The above-mentioned patent discloses a method for producing germanium ore, comprising the steps of mixing germanium ore and water with germanium ore in a heat-resistant container to dissolve the germanium salt as water, introducing germanium ore into the germanium ore water in which the salt is dissolved, Maintaining the temperature of the heat-resistant vessel at room temperature for cooling and drying, and then germanium salt is produced.

However, the above-mentioned germanium salt production method has a problem that workability is low because all operations are performed manually, economical efficiency is low due to high manufacturing cost, and thus it is not widely spread.

Prior Art: Published Patent Application No. 10-2009-0002422 (Published on January 9, 2009)

It is an object of the present invention to provide a germanium salt production apparatus capable of mass production of germanium salt at a low production cost.

It is another object of the present invention to provide a germanium salt production method using the germanium salt production apparatus.

A vacuum chamber supported on the frame; A porous drying furnace rotatably installed in the vacuum chamber and containing salt therein; A drying heater installed in the vacuum chamber to heat and dry the salt contained in the drying furnace; And a plasma generating unit for generating plasma into the vacuum chamber while being installed in the vacuum chamber so that germanium ions are absorbed by the salt as the ions of germanium contained in the vacuum chamber are activated, A germanium salt production apparatus is provided.

The vacuum chamber may further include a vacuum pump connected to the inside of the vacuum chamber to evacuate the inside of the vacuum chamber.

Preferably, the vacuum pump further includes a discharge pump connected to the inside of the vacuum chamber, for sucking impurities and wastewater contained in the salt and discharging the impurities and the wastewater to the outside of the vacuum chamber.

Preferably, the drying furnace is supported by the first pulley, and the first pulley is configured to be axially moved along the axial rails installed in the drying furnace in and out of the drying furnace.

Preferably, the axial rail on the outside of the drying furnace is configured to be removable from the axial rail inside the drying furnace, and the axial rail on the outside of the drying furnace is supported on the second pulley, And to move in the lateral direction along the directional rail.

According to another aspect of the present invention, there is provided a germanium salt production method using the germanium salt production apparatus described above, wherein a salt is introduced into a drying furnace, wherein water is removed from the inside of the drying furnace; A residual moisture removing step of sucking residual moisture contained in the salt together with the vacuum chamber while evacuating the inside of the vacuum chamber and discharging it to the outside after the vacuum chamber is closed; A germanium absorption step of causing germanium ions to be absorbed by the salt as the plasma generation unit is activated when the degree of vacuum in the vacuum chamber reaches a set degree of vacuum, thereby accelerating ionization of germanium contained in the vacuum chamber by oscillating the plasma; And a germanium salt extraction step of extracting the germanium salt absorbed from the germanium salt from the drying furnace.

Preferably, the method further comprises a step of spraying juice onto the salt before the step of applying the salt.

Preferably, between the residual water removal step and the germanium absorption step, impurities and wastewater contained in the salt are sucked by the drying heater while simultaneously applying heat to the salt and discharging the impurities and the wastewater to the outside of the vacuum chamber .

Preferably, the method further comprises a salt stirring step of rotating the drying furnace to agitate the salt so that the germanium ions are uniformly absorbed in the salt between the germanium absorption step and the germanium extraction step.

As described above, the germanium salt can be mass-produced automatically by the apparatus for producing germanium salt, thereby remarkably lowering the cost of production, and thus germanium salt, which is a functional salt, can be supplied at low cost.

In addition, germanium salt with consistent quality can be obtained by shaping the work by the mechanical device.

1 is a perspective view of a germanium salt production apparatus according to the present invention;
2 is a transparent perspective view of a germanium salt production apparatus according to the present invention.
3 is a cross-sectional view of a germanium salt production apparatus according to the present invention
4 is a side sectional view of the germanium salt production apparatus according to the present invention
5 is a flowchart of a method for producing germanium salt according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The terms used in the present invention are defined in consideration of the functions of the present invention and may vary depending on the intention or custom of the user or the operator. Therefore, the definitions of these terms are meant to be in accordance with the technical aspects of the present invention As well as the other.

In addition, optional terms in the following embodiments are used to distinguish one element from another element, and the element is not limited by the terms. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of related arts which may unnecessarily obscure the gist of the present invention will be omitted.

1 is a perspective view of a germanium salt production apparatus according to the present invention, Fig. 2 is a transparent perspective view of a germanium salt production apparatus according to the present invention, Fig. 3 is a front sectional view of a germanium salt production apparatus according to the present invention, Sectional side view of a germanium salt production apparatus according to the present invention.

1 to 4, a germanium salt manufacturing apparatus 100 according to the present invention includes a vacuum chamber 110, a drying furnace 120, a drying heater 130, and a plasma generating unit 140.

The vacuum chamber 110 is supported by the frame 101 and has a cylindrical shape for evacuating the inside of the vacuum chamber 110. The vacuum chamber 110 is hermetically closed at one side and opened at the other side, .

The drying furnace 120 is disposed inside the vacuum chamber 110 for receiving salt (a salt for forming germanium salt).

The drying furnace 120 needs to be heated in the process of reforming common salt into germanium salt and has a porous cylinder shape to be in a state of being in communication with the vacuum chamber 110 because germanium ions must be absorbed in the salt.

The drying furnace 120 is rotatably supported by the first pulley 150. That is, a shaft 121 formed on both sides of the drying furnace 120 is rotatably supported on the first pulley 150, and one of the two shafts is connected to a drive motor 122 installed in the vacuum chamber 110, And indirectly connected directly or via the power transmitting member 123 to rotate by the power of the driving motor 122. [

The first pulley 150 is configured to move along the axial rails 170 installed in the axial direction of the drying furnace 120 to the inside and the outside of the drying furnace 120. Therefore, ease of operation can be ensured when the drying furnace 120 is taken out or drawn from the vacuum chamber 110.

The axial rails 172 located outside the drying furnace 120 are configured to be removable from the axial rails 171 inside the drying furnace 120 and the axial rails 172 outside the drying furnace And is configured to be moved laterally along a transverse rail 180 mounted on the frame 101 while being supported on the second pulley 160. [ Accordingly, the drying furnace 120 is allowed to move in the axial direction by the first pulley 150 and in the lateral direction by the second pulley 160.

The drying heater 130 is for heating the salt in the drying furnace 120 and may be installed inside the vacuum chamber 110. In order to evenly dry the salt in the drying furnace 120, It is preferable that a plurality of radially arranged portions are provided.

The plasma generating unit 140 generates plasma to the inside of the vacuum chamber 110 to activate ions of germanium G accommodated in the vacuum chamber 110. The plasma generating unit 140 is disposed on both sides of the vacuum chamber 110, Can be installed.

For reference, when the solid is heated, it becomes liquid. When it is heated, the gas and the gas are heated. The separation of electrons from atoms or molecules into electrons and cations (atoms and molecules that lose electrons) is common in everyday life, but this state is quite unstable, so electrons recombine again. However, if the temperature is high enough, ions that have positively charged electrons coexist without recombination. This is plasma.

This plasma is a special type of gas with electrical energy that accelerates the chemical reaction and accelerates the ions.

Accordingly, when germanium in a solid state is positioned in front of the plasma generating unit 140, germanium is heated by the plasma and anions are released. In addition, ions are accelerated and accelerated by the plasma, so that a large amount of germanium ions are absorbed do.

Germanium (Ge) is a metal with atomic number of 32, atomic weight of 72, 39, specific gravity of 5,325 (25 ℃) and boiling point of 2,700 ℃, which means that when one of the 32 electrons is touched, one of the four electrons springs out, (Ion exchange function), and strongly radiates far-infrared rays to stimulate the production of interferon that acts as an anti-cancer agent for human body, facilitates oxygen supply, and promotes metabolism by promoting metabolism have.

The effect of germanium is provided by various studies through various studies. As for the effect, the effect of oxygen supply (oxygen substitution), anion effect by semiconductor action (controlling current flow of body cells), enhancement of human immunity , Interferon inducing action, endorphin stimulating action, pain relieving action, admiral action and body heavy metal releasing action, natural healing power enhancing action, and dehydrogenation action have been revealed through many studies. Therefore, if germanium is absorbed into salt, it will be possible to receive the aforementioned benefits when consuming salt.

Meanwhile, the apparatus of the present invention may further include a vacuum pump 191 that is connected to the inside of the vacuum chamber 110 and that evacuates the inside of the vacuum chamber 110. The vacuum pump 191 may be installed in the frame 101.

The apparatus of the present invention may further include a discharge pump 192 connected to the inside of the vacuum chamber 110 to suck impurities and wastewater contained in the salt and discharge the discharged impurities and the wastewater to the outside of the vacuum chamber 110 .

5 is a flowchart of a method for producing germanium salt according to the present invention.

A germanium salt production method using the germanium salt production apparatus will be described with reference to FIG.

In the salt injecting step (S20)

The salt injecting step S20 is a step of injecting salt (sun salt) from which moisture has been removed into the drying furnace 120. The salt is injected into the vacuum chamber 110 using the first pulley 150 and the second pulley 160 The drying furnace 120 is filled with the salt in the drying furnace 120. Then, At this time, it is preferable that the filling amount of the salt is filled with 80% of the content by the drying.

If the amount is less than 80%, the amount of salt for making germanium salt is low and the productivity is low. When the amount of germanium is 80% or more, the germanium ions are not absorbed uniformly due to the low fluidity of the salt.

The residual moisture removing step (S30)

The residual moisture removing step S30 is a step of removing residual water contained in the salt and the drying furnace 120 filled with the salt is introduced into the vacuum chamber 130 through the first pulley 150 and the second pulley 160 110, and then the opening and closing lid 111 of the vacuum chamber 110 is closed and closed.

Next, the vacuum pump (191) is operated to turn the vacuum chamber (110) into vacuum, and the moisture contained in the salt is sucked together and discharged to the outside.

At this time, it is preferable to set the pressure in the vacuum chamber 110 to 15 Torr and the operation time of the vacuum pump 191 to 1 to 2 hours.

When the pressure in the vacuum chamber 110 is lower than 15 Torr, the water discharge rate is lowered. If the pressure is higher than 15 Torr, the vacuum pump 191 must be applied. Further, when the operation time of the vacuum pump 191 is set to be within 1 hour, the moisture contained in the salt can not be dewatered sufficiently. If the operation time is 2 hours or more, the vacuum pump 191 is unnecessarily operated It is inefficient.

The germanium absorption step (S50)

The germanium absorbing step S50 is a step of absorbing germanium ions in the salt. When the degree of vacuum in the vacuum chamber 110 reaches a predetermined degree of vacuum, the plasma generating unit 140 is operated to oscillate the plasma, ) To promote the ionization of the germanium contained therein so that the germanium ions are absorbed by the salt.

Appropriate pressure and voltage are required to promote germanium ions by plasma. Accordingly, when the vacuum pressure in the vacuum chamber 110 reaches a level suitable for promoting ionization, the plasma generation unit 140 is operated to proceed ionization.

Here, a suitable pressure for promoting ionization is 3 x 10 ^-2 . If it is lower than the above range, the probability of free electrons or ions colliding with each other is lowered, so that the ionization is poor, and if it is higher than this range, the mean free pass of the ion particles becomes shorter, and ionization becomes difficult.

On the other hand, as an incidental step,

A juice spreading step (S10), a step of removing impurities and wastewater (S40), and a salt stirring step (S60).

The juice spraying step S10 is a step for spraying juice onto the salt before the salt injection step S20, for example, to make an apple-flavored salt by spraying a small amount of apple juice.

Next, the impurity and arsenic removal step S40 is performed between the residual moisture removal step S30 and the germanium absorption step S50 by applying heat to the salt by the drying heater 130, The impurities and the wastewater contained in the salt are sucked and discharged to the outside of the vacuum chamber.

Next, the salt stirring step S60 is a step of stirring the salt by rotating the drying furnace 120 so that germanium ions are uniformly absorbed in the salt between the germanium absorption step S50 and the germanium extraction step S70.

In the present invention, it is possible to carry out a large number of processes for changing general silver salt to germanium salt by one germanium salt production apparatus, thereby mass production is possible, manufacturing cost can be lowered, and a stereotyped work can be performed It is possible to maintain a constant quality so that germanium salt can be popularized.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: germanium salt production apparatus 110: vacuum chamber
120: drying furnace 130: drying heater
140: plasma generating unit 150: first pulley
160: second pulley 170: axial rail
180: transverse rail 191: vacuum pump
192: Discharge pump

Claims

A vacuum chamber supported on the frame;
A porous drying furnace rotatably installed in the vacuum chamber and containing salt therein;
A drying heater installed in the vacuum chamber to heat and dry the salt contained in the drying furnace; And
A plasma generating unit that generates plasma in the vacuum chamber while being installed in the vacuum chamber to activate germanium ions accommodated in the vacuum chamber so that germanium ions are absorbed by the salt;
And a germanium salt production device.

The method according to claim 1,
Further comprising a vacuum pump connected to the inside of the vacuum chamber to evacuate the inside of the vacuum chamber.

The method according to claim 1,
And a discharge pump connected to the inside of the vacuum chamber and sucking impurities and wastewater contained in the salt and discharging the impurities and the wastewater to the outside of the vacuum chamber.

The method according to claim 1,
The drying furnace is supported by the first pulley,
Wherein the first pulley is configured to be axially moved along an axial rail installed in an axial direction of the drying furnace inside and outside the drying furnace.

The method of claim 4,
Wherein the axial rail outside the drying furnace is configured to be removable from the axial rail inside the drying furnace and the axial rail external to the drying furnace is supported on the second pulley with a transverse rail mounted on the frame Wherein the germanium salt production apparatus further comprises:

A germanium salt production method using the germanium salt production apparatus according to claim 1,
A salt injecting step of adding a salt-removed salt to the inside of the drying furnace;
A residual moisture removing step of sucking residual moisture contained in the salt together with the vacuum chamber while evacuating the inside of the vacuum chamber and discharging it to the outside after the vacuum chamber is closed;
A germanium absorption step of causing germanium ions to be absorbed by the salt when the degree of vacuum in the vacuum chamber reaches a set degree of vacuum, thereby activating the plasma generation unit to oscillate the plasma to promote ionization of germanium contained in the vacuum chamber; And
And a germanium salt extraction step of extracting the germanium salt from which the germanium has been absorbed from the drying furnace.

The method of claim 6,
Further comprising a juice spraying step of spraying juice onto the salt before the step of applying the salt.

The method of claim 6,
And removing impurities and wastewater from the vacuum chamber by sucking impurities and wastewater contained in the salt while heating the salt by the drying heater between the residual water removal step and the germanium absorption step Germanium salt production method.

The method of claim 6,
Further comprising the step of stirring the salt by rotating the drying furnace so that germanium ions are uniformly absorbed in the salt between the germanium absorption step and the germanium extraction step.