KR20180075264A - Specimen synthesis apparatus and system having the same - Google Patents

Abstract

The present invention relates to a material synthesis, and more specifically, to a material synthesis apparatus which synthesizes nanoparticles and others through heating, stirring and the like; and a material synthesis system including the material synthesis apparatus. The purpose of the present invention is to provide a material synthesis apparatus which can greatly improve uniformity and identity of the target product produced by automating a process of producing a target product by synthesizing a sample; and a material synthesis system including the material synthesis apparatus. The present invention discloses the material synthesis apparatus (100) comprising: a container seating unit (140) on which a sample container (410) having an opened upper side and containing a liquid sample is seated; a temperature control unit (120) which is installed in the container seating unit (140) to control the temperature of the sample contained in the sample container (410); an adaptor member (420) which is sealed and coupled to an upper portion of the sample container (410); one or more mixing material supply units (600) which supplies a mixing material to be mixed with the sample contained in the sample container (410) through an inflow path (422) formed in the adaptor member (420); and a stirring member rotation driving unit (150) which rotationally drives a stirring member (110) installed in the sample container (410) to stir the sample and the mixing material by the rotation.

Description

TECHNICAL FIELD The present invention relates to a material synthesis apparatus and a material synthesis system including the material synthesis apparatus.

More particularly, the present invention relates to a substance synthesizing apparatus for synthesizing nanoparticles or the like through heating, stirring, etc., and a substance synthesizing system comprising the same.

There is a need for techniques for preparing intermediate products for final or final products by synthesizing samples, such as nanoparticles, for industrial or research purposes.

Generally, as in the case of university laboratories and laboratories, there is no mass produced substance when a large amount of substance is not required. The operator (experimenter) has to prepare the final product or intermediate product by hand- , Heating and cooling processes to produce final or intermediate products.

Particularly, in the case of commercially available materials, there is a problem that it is not easy to obtain materials necessary for university laboratories, laboratories, and the like by distributing materials having a prescribed physical property, composition and mixing ratio.

Therefore, when a sample for the purpose of experimentation in a university laboratory, a laboratory, or the like is required, it is synthesized by hand by a worker (experimenter) of a university laboratory or a laboratory.

However, since the uniformity and the identity are determined depending on the skill of the operator and the experimental condition of the individual process, the intermediate product or the final product obtained by individually performing the single or plural processes required for the sample synthesis is determined repeatedly There is a problem that the uniformity and the identity of the target product can not be guaranteed.

Especially, the uniformity and the identity of the target product greatly vary depending on the skill level of the operator in university laboratories and laboratories, and the reliability of the experiment using the target product is deteriorated.

It is an object of the present invention to provide a material synthesizing apparatus and a material synthesizing system including the same that can significantly improve uniformity and uniformity of a target product produced by automating a process for synthesizing a sample to produce an objective product.

The present invention has been made in order to achieve the above-mentioned object of the present invention, and it is an object of the present invention to provide an apparatus and a method for measuring a liquid sample, the apparatus comprising: a container seating part 140 on which a sample container 410 with a liquid sample is placed; A temperature regulator 120 installed in the vessel seating part 140 to regulate the temperature of the sample contained in the sample vessel 410; An adapter member 420 hermetically coupled to the upper side of the sample container 410; At least one mixed substance supply part (600) for supplying a mixed substance to be mixed with a sample contained in the sample container (410) through an inflow channel (422) formed in the adapter member (420); And a stirring member rotation driving unit (150) installed in the sample container (410) for rotating the stirring member (110) which stirs the sample and the mixed substance by rotating the stirring member 100).

The temperature regulating unit 120 may include at least one of a heating unit for heating the sample and a cooling unit for cooling the sample.

And a vapor recovery unit 130 installed on the vessel seating unit 140 and recovering the vapor heated in the sample vessel 410 by the temperature control unit 120.

The steam recovery unit 130 includes a tube 132 coupled to the discharge passage 426 formed in the adapter member 420 on the adapter member 420 and a tube 132 coupled to the tube 132, And a cooling unit 134 that cools the steam heated in the sample vessel 410 discharged through the steam generator 426.

The stirring member rotation driving unit 150 includes a rotation motor 151 mounted on the container seating unit 140 and a rotation driving shaft 152 rotated and rotated by the rotation motor 151 The stirring member 110 includes a rotating rod 111 detachably coupled to the rotating driving shaft 152 through a shaft coupling hole 424 formed in the adapter member 420, And may include one or more blades 112 formed on the rotating rod 111 to stir the sample during rotation of the rotating rod 111.

The agitating member rotation driving unit 150 may include a stirring member driving unit 150 installed in the container seating unit 140 to rotate the container seating unit 140, And a magnetic force generating unit for rotating the stirring member 110 contained in the sample container 410 by changing the magnetic flux around the sample container 410 mounted on the sample container 410.

The material synthesizing apparatus 100 is installed on the upper part of the vessel seating part 140 and the adapter member 420 is inserted into the sample vessel 410 during a synthesis process of synthesizing samples contained in the sample vessel 410. [ After the completion of the synthesis of the material in the sample container 410, the adapter member 420 is inserted into the sample container 410 to discharge the sample container 410 to the outside or replace the sample container 410 with a new sample container 410. [ And an adapter moving part for separating and separating from the container 420.

The adapter moving unit may move the adapter member 420 by at least one of linear movement and rotational movement.

The substance synthesis apparatus 100 according to the present invention includes a synthesis control unit that automatically controls the operation of the substance synthesis apparatus 100 according to a preset synthesis recipe, The temperature of each step, the cooling time, the cooling time, the temperature of the reaction, the type of material, the amount or concentration of the mixed material, the order of supplying the mixed materials, , The number of cooling times, and the time required for each step.

The synthesis control unit may receive the synthetic recipe from a storage medium storing the synthetic recipe data.

And a storage medium mounting module that allows the storage controller to access data stored in the storage medium when the storage medium is coupled to the storage medium.

The present invention also relates to a substance synthesizing apparatus 100 having the above-described configuration; A sample container loading unit 200 for loading the sample container 410 into the material synthesizer 100; And a sample container unloading unit (300) for unloading the sample container (410) synthesized in the material synthesizing apparatus (100).

The material synthesizing apparatus and the material synthesis system including the same according to the present invention have an advantage of improving the uniformity of a target product by automating a process of synthesizing sample samples to produce a desired product.

Specifically, the substance synthesizing apparatus and the substance synthesizing system including the same according to the present invention include an agitating section, a heating section, and a cooling section for performing stirring, heating and cooling, respectively, on a sample accommodated in a sample container, Accordingly, it is possible to control the operation of the agitating part, the heating part and the cooling part, so that a target product of uniform quality can be always produced regardless of the skill of the operator.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a layout showing a material synthesis system according to one embodiment of the present invention.
2 is a cross-sectional view in Y direction showing a material synthesizing apparatus in the material synthesis system of FIG.
3 is a plan view showing the material synthesizing apparatus of FIG. 2;
Fig. 4 is a cross-sectional view in the X direction showing the material synthesizing apparatus of Fig. 2; Fig.
Fig. 5 is an exploded view showing a part of the constitution of the material synthesis apparatus of Fig. 2; Fig.
Fig. 6 is a plan view showing a part of the composition of the material synthesis apparatus of Fig. 2; Fig.

The substance synthesizing apparatus and the substance synthesizing system including the same according to the present invention will be described with reference to the accompanying drawings.

The present invention relates to a substance synthesizing apparatus for producing a synthesized substance including nanoparticles, which is realized as a substance synthesizing system including a substance synthesizing apparatus itself or a substance synthesizing apparatus described later, and various modifications and changes This is possible.

The material synthesis system according to the present invention includes a material synthesis apparatus 100, as shown in FIGS. 1 to 6.

The material synthesis system may be configured to automatically synthesize materials, for example, automatic loading and unloading of the sample container 410, and a stopper (not shown) in the sample container 410, For example, for automatic attachment and detachment.

1, the substance synthesizing system includes a substance synthesizing apparatus 100, a sample container loading unit 200 for loading the sample container 410 in the substance synthesizing apparatus 100, And a sample container unloading unit 300 for unloading the sample container 410 that has been synthesized in the material synthesizing apparatus 100.

The sample container loading unit 200 may be configured to load the sample container 410 into the substance synthesizing apparatus 100 and may have various configurations.

For example, the sample container loading unit 200 may have a turret structure in which a plurality of sample containers 410 are disposed along the circumferential direction, and each sample container 410 is rotated so as to be positioned at the withdrawal position.

The sample unloading unit 300 may be configured to unload the sample container 410 that has been synthesized in the material synthesizing apparatus 100, and may have various configurations.

The sample container unloading unit 300 may have a different configuration from the sample container loading unit 200, such as a separate or integrated configuration.

Although not shown, the transfer of the sample container 100 between the sample container loading section 200, the sample container unloading section 300 and the material synthesizing apparatus 100 can be performed by a pick- Various configurations are possible.

The material synthesis apparatus 100 may be configured to produce a desired end product by synthesizing a sample by performing at least one of stirring, heating and cooling the sample contained in the sample container 410.

For example, the material synthesis apparatus 100 may synthesize a sample containing a raw material to produce target particles. Here, the target particles may be nanoparticles such as silica (Silica) nanoparticles, Q-dot, magnetic particles and the like, but the present invention is not limited thereto.

Hereinafter, the substance synthesizing apparatus 100 according to the present invention will be described in more detail with reference to FIGS. 2 to 6. FIG.

As shown in FIGS. 2 and 4, the material synthesizing apparatus 100 includes a container seating part 140 on which an upper side is open and on which a sample container 410 containing a liquid sample is placed; A temperature adjusting unit 120 installed in the container mounting part 140 to adjust the temperature of the sample contained in the sample container 410; An adapter member (420) hermetically coupled to the upper side of the sample container (410); At least one mixed substance supply part (600) for supplying a mixed substance to be mixed with a sample contained in the sample container (410) through an inflow channel (422) formed in the adapter member (420); And a stirring member rotation driving unit 150 installed inside the sample container 410 to rotate the stirring member 110 which stirs the sample and the mixed substance by rotating.

Here, the sample container 410 may have a variety of configurations in which a sample containing a raw material for producing a target product is accommodated to provide a sample synthesis reaction space.

For example, the sample container 410 is made of transparent glass or the like, and the upper side thereof may be opened.

The opening of the sample container 410 may be detachably coupled with a stopper, and may be detachably coupled to an adapter member 420 described later.

The manner in which the stopper and the adapter member 420 are coupled to the sample container 410 can be determined by a method of inserting the stopper and the adapter member 420 by a groove and a protrusion formed on the outer circumferential surface of the sample container 410, A screw connection method in which the sample 410 is inserted, and an insertion method in which the upper end of the sample 410 is partially inserted.

The sample container 410 may have a variety of configurations in which a space for accommodating the sample is formed.

The sample container 410 is made of a transparent material so that an operator can confirm the sample synthesis process, and is preferably made of a heat-resistant material to prevent damage during heating.

The container seating part 140 can be variously configured as a configuration in which a sample container 410 on which an upper side is opened and a liquid sample is loaded is seated.

Particularly, in consideration of the fact that the container placing part 140 is provided with a temperature adjusting part 120 for adjusting the temperature of the sample contained in the sample container 410, such as heating, cooling, etc., along with the placement of the sample container 410, Lt; RTI ID = 0.0 > 120 < / RTI >

The container seating part 140 may be formed with a receiving part 122 recessed in a corresponding shape so that the sample container 410 can be inserted into the container seating part 140 from above.

The sample container 410 can be inserted or separated from the receiving portion 142 through the up and down movement.

Preferably, the accommodating portion 142 is formed to insert only the sample container 410 except for the adapter member 420.

Meanwhile, the container seating unit 140 may be provided with a housing (not shown) which is provided with a temperature control unit 120 and isolates the container from the outside in order to increase heating or cooling efficiency.

The temperature regulating unit 120 is provided in the container seating unit 140 to regulate the temperature of the sample contained in the sample container 410 and may have various configurations according to the temperature control method

For example, the temperature regulating unit 120 may include at least one of a heating unit for heating the sample and a cooling unit for cooling the sample.

Specifically, the temperature regulating unit 120 may be constituted by a heater as a heating unit or a cooling device as a cooling unit.

The temperature regulator 120 may be a thermoelectric module that selectively performs heating and cooling according to the application of electric power.

Meanwhile, the temperature regulating unit 120 may be installed adjacent to the inner circumferential surface of the accommodating portion 142 to externally apply heat to the sample container 410 inserted into the accommodating portion 142 for efficient heat exchange.

When the sample container 410 is inserted into the receiving part 142, the heater part 124 corresponds to the outer surface of the sample container 410, Can be heated.

Meanwhile, the material synthesis apparatus 100 includes a vapor recovery unit 130 disposed above the vessel seating unit 140 and recovering the vapor heated in the sample vessel 410 by the temperature control unit 120 .

The vapor recovery unit 130 may be configured in various ways as a structure for recovering the vapor heated in the sample vessel 410 by the temperature control unit 120 installed on the vessel seating unit 140.

The steam recovery unit 130 includes a tube 132 coupled to the discharge passage 426 formed in the adapter member 420 and an outlet passage 426 coupled to the tube 132, And a cooling unit 134 for cooling the steam (water vapor, etc.) heated in the sample container 410 discharged through the evaporator (not shown).

The tube 132 may be formed of a combination of at least one of a straight line and a curved line, and may be formed of various materials such as rubber, plastic, or glass.

The tube 132 may be formed as a single tube or may be branched in some regions depending on the method of recovering the vapor.

For example, the tube 132 may be vertically formed so that the vapor is cooled and liquefied, thereby allowing the vapor to be recovered back into the sample vessel 410.

In addition, the tube 132 may be provided with a recovery channel (not shown) such that the steam is cooled and liquefied, thereby being recovered into the sample container 410, or discarded to the outside or recovered to a separate recovery container or the like.

That is, the sample cooled and liquefied by the cooling unit 130 is recovered to the sample vessel 410 again through the tube 132, or is collected in the branch tube, which can be formed in a part of the region of the tube 132, .

The tube 132 is coupled with the discharge passage 426 formed in the adapter member 420 to provide a path through which the vapor evaporated in the sample container 410 is moved.

The tube 132 may be installed vertically or be inclined to the ground.

The cooling member 134 may be configured to have a variety of configurations in which the cooling member 134 is installed outside the tube 132 and cooled to a preset temperature so that the vapor moved to the inside of the tube 132 is liquefied.

For example, the cooling member 134 may comprise a thermoelectric module to cool the evaporation material to a predetermined temperature.

As another example, it is needless to say that the cooling member 134 may be composed of cooling water or cooling air that flows outside the tube 132, not the thermoelectric module.

The mixed material supply unit 600 may be configured to supply a mixed material to be mixed with a sample contained in the sample container 410 through at least one inlet channel 422 formed in the adapter member 420, Do.

The mixed material supply unit 600 may be configured in various forms such as a container containing a mixed material depending on the physical properties and the type of the mixed material while being coupled to the second support frame 530 to be described later.

The mixed material supply unit 600 includes a supply conduit 610 coupled to the inlet flow path 422 and a supply conduit 610 for supplying one of the at least one mixed material to the inside of the sample container 410 through the inlet flow path 422. [ And may be connected to an adapter member 420 described later by a selection valve (not shown) installed in the conduit 610.

It is preferable that the inflow channel 422 is maintained in a shutoff state by the selection valve when the sample is not introduced into the sample vessel 410.

Meanwhile, the sample container 410 is configured as an empty container when it is seated in the container seating part 140, and is configured to supply one of the mixed material supply parts 600 and to supply the other with the mixed material .

The stirring member rotation driving unit 150 is configured to rotate the stirring member 110 installed inside the sample container 410 and stir the sample and the mixed material by rotating the stirring member 110. Various configurations It is possible.

2 to 5, the stirring member rotation driving unit 150 includes a rotation motor 151 mounted on the container seating unit 140 and rotated by the rotation motor 151, And a rotary drive shaft 152 that is driven and rotated.

The rotary motor 151 is provided on the upper side of the container seating part 140, and may be an electric motor, a hydraulic motor, or the like, provided that the rotary motor 151 is rotatably driven.

The rotary drive shaft 152 is provided on the container seating portion 140 and rotatably driven by the rotary motor 151 and the rotary motor 151 to be coupled to the stirring member 110 So that the stirring member 110 is rotated.

Particularly, the length of the rotary drive shaft 152 is determined according to the position of the rotary motor 151, and a coupling portion including a magnet or the like may be provided at an end coupled with the stirring member 110 according to a coupling method.

The coupling unit may have various configurations according to the coupling method in which the stirring member 110 is coupled, and may be coupled with the end of the stirring member 110 by the installation of the magnet.

The stirring member 110 includes a rotary rod 111 detachably coupled to the rotary drive shaft 152 via an axial coupling hole 424 formed in the adapter member 420, And may include one or more blades 112 formed to stir the sample upon rotation of the rotating rod 111.

The rotating rod 111 is formed to have a sufficient length considering that the sample container 410 is elongated in the lengthwise direction and has an end portion formed with a metal member coupled to the magnet or the magnet so as to be coupled with the end portion of the rotation driving shaft 152, As shown in FIG.

The stirring member rotation driving unit 150 may be installed in the container seating unit 140. The stirring member rotation driving unit 150 may include a magnetic stirring member that is rotated by external magnetic force, And a magnetic force generating unit for rotating the stirring member 110 contained in the sample container 410 by changing the magnetic flux around the sample container 410 mounted on the container seating unit 140.

The adapter member 420 is configured to be hermetically coupled to the upper side of the sample container 410, and various configurations are possible.

The adapter member 420 is configured to be coupled to an opening formed on the upper side of the sample container 410 to form a reaction space separated from the inside of the sample container 410.

The method of coupling the adapter member 420 to the sample container 410 includes an insertion method (an undercut method) using grooves and projections formed on the outer peripheral surface of the sample container 410, A screw coupling method 429 screwed to the sample 410, and an insertion method in which the upper end of the sample 410 is partially inserted.

5 and 6, the adapter member 420 includes an inflow channel 422 for supplying a mixed material from the outside to the interior of the sample container 410, For discharging the steam to the steam recovery part 130, a discharge flow path 426 communicating with the sample vessel 410 and the steam recovery part 130, a stirring member 110 and a rotary drive shaft 152 Axis coupling holes 424 and the like may be formed.

The inflow channel 422 may be configured to communicate with a mixed material supply unit 600 for introducing a mixed material from the outside to the sample container 410 and communicate with the inside of the sample container 410.

The discharge passage 426 may have a variety of configurations in which the sample container 410 and the vapor recovery unit 130 are arranged such that the vapor heated in the sample container 410 moves to the vapor recovery unit 130.

The shaft coupling hole 424 is a through hole formed for axial coupling with the stirring member 110 and the rotary driving shaft 152, and can be variously configured according to the shaft coupling method.

The shaft coupling hole 424 for installing the stirring member 110 is preferably formed at a position corresponding to the center of the sample container 410 for even stirring.

Meanwhile, the adapter member 420 is preferably made of a synthetic resin material for ease of processing and light weight in consideration of the formation of the inflow channel 422, the discharge channel 426, the shaft coupling hole 424, It is not.

5 and 6, the adapter member 420 may be a rectangular parallelepiped having a rectangular shape in which the plane shape is longer than the X axis in the Y axis direction to form the discharge passage 426 But is not limited thereto.

Meanwhile, as described above, the stirring member 110 may be configured to stir the sample in the sample container 410 and have various configurations.

For example, as shown in FIG. 5, the stirring member 110 may be a stick having one end in the form of a screw, and a stirring stick for stirring the sample by rotation.

The stick-shaped stirring member 110 may be installed inside the sample container 410 through the adapter member 420.

In the meantime, the adapter member 420, the mixed material supply unit 600, and the stirring member rotation driving unit 150, etc., may be replaced with the sample container 410 according to its structure and installation position. It may be prevented from replacing the container 410.

At least one of the adapter member 420, the mixed material supply unit 600, and the stirring member rotation driving unit 150 may be moved by at least one of linear movement and rotational movement for transporting the sample container 410. [ Can be moved.

To this end, a moving structure for moving at least one of the adapter member 420, the mixed material supply unit 600, and the stirring member rotation driving unit 150 may be added.

1 to 3, the material synthesizing apparatus 100 may be installed on the upper part of the container seating part 140 to synthesize a sample contained in the sample container 410, After the completion of material synthesis in the sample container 410, the sample container 410 is sealed to the upper side of the sample container 410, and the sample container 410 is discharged to the outside or replaced with a new sample container 410. [ And an adapter moving part for separating and separating the member 420 from the sample container 420.

The adapter moving unit can move the adapter member 420 by at least one of linear movement and rotational movement, and various configurations are possible according to the movement mode.

On the other hand, when the adapter is moved by the moving part, the adapter member 420 is in close contact with the first adapter member and functions as a first adapter member (also serving as a cap) in a state of being coupled to the sample container 410, And a second adapter member that is moved by the second adapter member.

The first adapter member and the second adapter member may be formed with an inflow channel 422, a discharge channel 426, a shaft coupling hole 424, and the like. The inflow channel 422, the discharge channel 426, And can be hermetically sealed by a seal member (pressurized state) or the like for communication between the shaft coupling hole 424 and the like and isolation from the outside.

And may be supported and supported by a first support frame 510 for supporting the adapter member 420 in order to transfer and detach the adapter member 420.

Here, the adapter member 420 may be provided to correspond to changes in the size of the sample container 410, the inflow channel 422, the discharge channel 426, the shaft coupling hole 424, And is detachably installed by the first support frame 510.

The mixed material supply unit 600 and the agitator rotation driving unit 150 may be required to move the mixing material supply unit 600 and the agitator rotation driving unit 150 in addition to the adapter member 420, And can be supported and installed by the frame 530.

In addition, as shown in FIG. 3, the rotating member 520 may be rotated and moved to another position by rotating or linearly moving the adapter member 420 or the like.

The adapter moving unit moves the adapter member 420 and the sample container 410 relative to each other in accordance with the coupling method of the adapter member 420 and the sample container 410 for sealing connection with the sample container 410, Can be further driven.

The first support frame 510 may have various configurations in which the sample container 410, particularly, the adapter member 420 is detachably coupled.

The first support frame 510 has a shape corresponding to that of the adapter member 420 and is vertically opened to support the side surface of the adapter member 420.

For example, the first support frame 510 may be configured to support two opposing side surfaces of the side surfaces when the adapter member 420 is formed in a rectangular parallelepiped shape, as shown in FIGS. 2 and 4 And an opening may be formed in the bottom surface of the sample container 410 so that the sample container 410 can be coupled thereto. However, the present invention is not limited thereto.

The first support frame 510 supports the adapter member 420 and enables the sample container 410 to be coupled from below.

Meanwhile, by moving the first support frame 510 linearly or rotationally by the adapter moving part, the sample container 410 can be manually changed or the sample container 410 can be automatically loaded or unloaded when the sample container 410 is automatically loaded or unloaded 410).

As another example, when the sample container support portion 500 is configured to be movable by the adapter moving portion, the adapter member 420 may be integrally moved together with the first support frame 510, May be provided in the sample container 410 in a state separated from the support frame 510 and may be coupled to the first support frame 510 together when the sample is synthesized.

Meanwhile, the substance synthesizer 100 according to the present invention may include a synthesizer controller that automatically controls the operation of the substance synthesizer 100 according to a preset synthetic recipe.

The synthesis control unit may be configured in various manners to automatically control the operation of the substance synthesizing apparatus 100 according to a preset synthetic recipe.

Here, the synthetic recipe may include at least one of a type of the mixed substance to be supplied to the sample container 410, a mixed substance capacity or concentration, a supply order of the mixed substance, a supply point of the mixed substance, a stirring point, Time, number of heating, temperature condition for each step, cooling time, cooling time, number of cooling, and time required for each step.

Here, the synthetic recipe means a series of processes for producing a desired product.

The synthetic recipe may include the contents of the synthesis step or devices necessary for processing or processing.

For example, the synthetic recipe may include at least one of a type of a sample to be supplied to the material synthesizing apparatus, a capacity or concentration of each sample, a supply order of each sample, a supply timing of each sample, a stirring time at each step, The heating time for each step, the temperature for each step, the cooling time for each step, and the time required for each step.

That is, the synthetic recipe exists for each substance to be synthesized, that is, a target product, and a plurality of synthetic recipes may exist for the same target product.

For example, when the target product is gold nanoparticles, the synthetic recipe may include a total of N recipes (N is a natural number of 1 or more) for the gold nanoparticles.

Each synthetic recipe may be different depending on the physical properties such as the size of the gold nanoparticles or the state of the prepared gold nanoparticles (e.g., powder or colloid).

The synthetic recipe may be preset or stored or may be input by the user during sample synthesis and received by the synthesis control unit.

The state information of the material synthesizing apparatus 100 may include a sample synthesis step (stirring, heating, or cooling) performed in the material synthesizing apparatus 100 and a time required for each sample synthesis step, The temperature of the material to be mixed, whether or not the sample is introduced into the material synthesis apparatus 100, and the like.

It goes without saying that the synthesis control unit can receive the state information of the substance synthesizing apparatus 100 and control the operation of the substance synthesizing apparatus 100 based on the state information.

At this time, the material synthesis apparatus 100 may include one or more sensors for measuring information necessary for controlling the synthesis control unit.

For example, the material synthesizing apparatus 100 may include a temperature sensor for measuring the temperature of the material contained in the material synthesizing apparatus 100, a timer for measuring the time required for each sample synthesis step, A power quantity sensing sensor (e.g., current sensor, voltage sensor, etc.), and the like.

The synthesis control unit may receive the sensing information sensed by the sensors and utilize the sensed information for controlling the substance synthesizing apparatus 100.

The synthesis control unit can improve the reproducibility of the target product production and the quality of the final product produced by controlling the substance synthesizer according to the recipe for each target product.

Meanwhile, the synthesis control unit may receive the synthetic recipe from the storage medium storing the synthetic recipe data.

The material synthesizing apparatus 100 may include a storage medium mounting module for detachably connecting the storage medium and allowing the combining control unit to access the data stored in the storage medium when the storage medium is coupled.

Meanwhile, the synthesis control unit controls the operation of the substance synthesizing apparatus 100 to synthesize a sample according to a predetermined recipe, and may be composed of various devices such as a PC, a tablet, and a smart phone.

For example, the synthesis control unit may include: a receiving unit that receives at least one of a synthesis recipe for each target product and state information of the material synthesis apparatus 100; A control unit for controlling the operation of the synthesizing apparatus 100, a storage space for storing a preset synthetic recipe or a synthesized recipe for each desired product by the target product, at least one of the external terminal and the material synthesizing apparatus 100, And a display unit for displaying status information of the received synthetic recipe or substance synthesizing apparatus 100. [0034]

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. Modified forms are also included within the scope of the present invention.

Claims (15)

A container seating part 140 on which an upper side is opened and on which a sample container 410 containing a liquid sample is placed;
A temperature regulator 120 installed in the vessel seating part 140 to regulate the temperature of the sample contained in the sample vessel 410;
An adapter member 420 hermetically coupled to the upper side of the sample container 410;
At least one mixed substance supply part (600) for supplying a mixed substance to be mixed with a sample contained in the sample container (410) through an inflow channel (422) formed in the adapter member (420);
And a stirring member rotation driving unit (150) installed in the sample container (410) for rotating the stirring member (110) which stirs the sample and the mixed substance by rotating the stirring member 100). The method according to claim 1,
Wherein the temperature regulating unit (120) includes at least one of a heating unit for heating the sample and a cooling unit for cooling the sample. The method of claim 2,
And a vapor recovery unit (130) installed on the vessel seating unit (140) and recovering the vapor heated in the sample vessel (410) by the temperature control unit (120) (100). The method of claim 3,
The steam recovery unit (130)
A tube 132 coupled to the discharge passage 426 formed in the adapter member 420 to the adapter member 420 and a tube coupling member coupled to the tube 132 and discharged through the discharge passage 426, And a cooling unit (134) for cooling the steam heated by the heating unit (410). The method according to any one of claims 1 to 4,
The agitating member rotation driving unit 150,
A rotary motor 151 mounted on the container seating part 140,
And a rotary drive shaft 152 rotated and rotated by the rotary motor 151,
The stirring member 110 includes a rotating rod 111 detachably coupled to the rotating drive shaft 152 through a shaft coupling hole 424 formed in the adapter member 420, And at least one blade (112) formed on the rotating rod (111) and stirring the sample upon rotation of the rotating rod (111). The method according to any one of claims 1 to 4,
The stirring member 110 includes a magnetism-responsive member rotated by an external magnetic force change,
The stirring member rotation drive unit 150 may be configured to rotate the stirrer rotation driving unit 150 such that the magnetic flux around the sample container 410 installed in the container seating unit 140 and placed in the container seating unit 140 is changed, And a magnetic force generating unit for rotating and driving the stirring member (110). The method of claim 5,
On the upper portion of the container seating portion 140,
The adapter member 420 is hermetically coupled to the upper side of the sample container 410 in the process of synthesizing the sample contained in the sample container 410. After the completion of the synthesis of the material in the sample container 410, And an adapter moving unit for separating and separating the adapter member from the sample container in order to discharge the sample container to the outside or replace the adapter member with a new sample container. . The method of claim 7,
Wherein the adapter moving unit moves the adapter member (420) by at least one of linear movement and rotational movement. The method according to any one of claims 1 to 4,
And a synthesis control unit for automatically controlling the operation of the substance synthesizing apparatus 100 according to a preset synthetic recipe,
The synthetic recipe may include at least one selected from the group consisting of the type of the mixed substance to be supplied to the sample container, the mixed substance capacity or concentration, the order of supplying the mixed substance, the time of supplying the mixed substance, the time of stirring, the number of times of stirring, The cooling time, the number of cooling times, and the time required for each step. The material synthesis apparatus 100 according to claim 1, The method of claim 9,
The agitating member rotation driving unit 150,
A rotary motor 151 mounted on the container seating part 140,
And a rotary drive shaft 152 rotated and rotated by the rotary motor 151,
The stirring member 110 includes a rotating rod 111 detachably coupled to the rotating drive shaft 152 through a shaft coupling hole 424 formed in the adapter member 420, And at least one blade (112) formed on the rotating rod (111) and stirring the sample upon rotation of the rotating rod (111). The method of claim 10,
The stirring member 110 includes a magnetism-responsive member rotated by an external magnetic force change,
The stirring member rotation drive unit 150 may be configured to rotate the stirrer rotation driving unit 150 such that the magnetic flux around the sample container 410 installed in the container seating unit 140 and placed in the container seating unit 140 is changed, And a magnetic force generating unit for rotating and driving the stirring member (110). The method of claim 9,
The adapter member 420 is hermetically coupled to the upper side of the sample container 410 in a process of synthesizing a sample contained in the sample container 410, After the completion of the material synthesis in the sample container 410, the adapter member 420 is separated from the sample container 420 so as to separate the sample container 410 from the sample container 410 or to replace the sample container 410 with a new sample container 410 And an adapter moving unit. The method of claim 8,
Wherein the synthesis control unit receives the synthetic recipe from a storage medium storing the synthetic recipe data. 14. The method of claim 13,
And a storage medium mounting module for detachably connecting the storage medium and allowing the composite control unit to access data stored in the storage medium when the storage medium is coupled. A material synthesis apparatus (100) according to any one of claims 1 to 4;
A sample container loading unit 200 for loading the sample container 410 into the material synthesizer 100;
And a sample unloading unit (300) for unloading the sample container (410) synthesized in the material synthesizing apparatus (100).

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