KR102106960B1 - Filtering device for sample and filtering method using the same - Google Patents

Abstract

The present invention relates to a sample filtration device and a filtration method using the same, and more specifically, to convert a specific substance into a sediment form in a single device, it can be filtered and collected, and vacuum pressure can be used in the filtration and collection process. The present invention relates to a sample filtration device capable of simultaneously filtering a plurality of samples or simultaneously collecting precipitates from a plurality of filtration members and a filtration method using the same. To this end, the sample portion for receiving the sample containing the precipitate, the sample portion is connected, a filtration unit provided with a filtration member, a recovery unit for recovering the sample filtered through the filtration unit, and remaining in the filtration member Provided is a sample filtering device including a collection part for collecting precipitates and a vacuum part provided to selectively form a vacuum pressure in the collection part or the collection part.

Description

Filtering device for sample and filtering method using the same}

The present invention relates to a sample filtration device and a filtration method using the same, and more specifically, to convert a specific substance into a sediment form in a single device, it can be filtered and collected, and vacuum pressure can be used in the filtration and collection process. The present invention relates to a sample filtration device capable of simultaneously filtering a plurality of samples or simultaneously collecting precipitates from a plurality of filtration members and a filtration method using the same.

In general, a filtration method is mainly used to separate a specific substance dissolved in a solution. This filtration method can also be used to concentrate certain substances.

In the case of using a conventional filtration device, a specific substance dissolved in a solution is changed into a solid precipitate, and this precipitate is filtered using filter paper, and the remaining solution after the precipitate is filtered can be discarded or recovered for other purposes. Do.

In addition, the precipitate remaining on the filter paper is dissolved in a special solution such as an acidic solution to obtain a solution in which a specific substance is concentrated.

However, in the case of using a conventional filtration device, a device for filtering a specific substance and a device for collecting filtered sediment had to be provided respectively, and an operator has to perform work using each of these devices, so the procedure for filtration and concentration There was a problem that it was troublesome.

In particular, when a large number of samples or a large number of samples need to be processed, such a cumbersome procedure decreases the sample processing efficiency, and thus it is necessary to improve it for operator convenience and to improve sample processing efficiency.

The technical problem to be solved in the present invention is to provide a sample filtration device capable of converting a specific substance into a sediment form in a single device, filtering and collecting it, and a filtration method using the same.

In addition, to provide a sample filtration device configured to use a vacuum pressure in the filtration process and collection process of the precipitate and a filtration method using the same.

In addition, it is to provide a sample filtration device capable of simultaneously filtering a plurality of samples or collecting precipitates from a plurality of filtration members and a filtration method using the same.

The sample filtration device according to the present invention for solving the above technical problem is a sample portion for receiving a sample containing a sediment, the sample portion is connected, the filter portion provided with a filtration member, and filtered through the filter portion It includes a recovery unit for collecting the sample, a collection unit for collecting the precipitate remaining on the filtration member, and a vacuum unit provided to selectively form a vacuum pressure in the recovery unit or the collection unit.

In addition, the filtration method using the sample filtration device according to the present invention comprises the steps of connecting a sample portion containing a sample to a filtration unit, recovering a sample filtered through the filtration unit to a recovery unit, and sediment remaining in the filtration member of the filtration unit It includes the steps of collecting.

The sample filtration device of the present invention having the above-described configuration and the filtration method using the same can convert a specific substance into a sediment form in a single device, and this can be filtered and collected, thus simplifying the configuration of the filtration device, and performing the operator This has the effect of simplifying the work to be done and increasing convenience.

In addition, the vacuum pressure is used in the filtration process and collection process of the sediment, but a valve member is provided to selectively connect a single pump member, so that the filtration and collection process can be smoothly performed and two single pump members are used. Since it can be used for work in common, the configuration of the device is simplified, thereby reducing the manufacturing cost.

In addition, since it is possible to simultaneously filter a large number of samples or to collect precipitates from multiple filtration members at the same time, it is possible to quickly filter large volumes of samples or collect precipitates.

1 is a front view showing a sample filtration apparatus according to the present invention.
2 is a rear view showing a sample filtering device according to the present invention.
3 is a cross-sectional view showing a collection unit of a sample filtration device according to the present invention.
Figure 4 is a schematic diagram showing the flow of the filtration and collection process of the sample using the sample filtration device according to the present invention.
5 is a flowchart showing a filtration method using a sample filtration device according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. The present invention can be implemented in many different forms and is not limited to the embodiments described herein. In the drawings, parts not related to the description are omitted in order to clearly describe the present invention, and the same reference numerals are attached to the same or similar elements throughout the specification.

In this specification, terms such as “include” or “have” are intended to indicate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and one or more other features. It should be understood that the presence or addition possibilities of fields or numbers, steps, actions, components, parts or combinations thereof are not excluded in advance. In addition, when a part such as a layer, film, region, plate, etc. is said to be "above" another part, this includes not only the case "directly above" the other part but also another part in the middle. Conversely, when a portion of a layer, film, region, plate, or the like is said to be “under” another portion, this includes not only the case “underneath” another portion, but also another portion in the middle.

1 is a front view showing a sample filtration device according to the present invention, FIG. 2 is a rear view showing a sample filtration device according to the present invention, and FIG. 3 is a cross-sectional view showing a collection part of a sample filtration device according to the present invention , Figure 4 is a schematic diagram showing the flow of the filtration and collection process of the sample using the sample filtration device according to the present invention, Figure 5 is a flow chart showing a filtration method using a sample filtration device according to the present invention.

1 to 3, the sample filtration device according to the present invention is basically provided with a sample unit 100 and a filter unit 200 for filtering samples. In the sample unit 100, a sample in a liquid state in which a specific substance to be filtered is dissolved is accommodated. However, in order to filter a specific substance, a specific substance dissolved is changed into a precipitate, and thereafter, the filter unit 200 ) To filter the precipitate. The filtration unit 200 is provided with a filtration member 210 for filtration of precipitates.

The sediment contained in the sample in the liquid state is filtered by the filter unit 200, and the sample filtered through the filter unit 200 is recovered through the recovery unit 300. The sample recovered through the recovery unit 300 may be disposed of in accordance with its purpose, or recovered for use for other purposes.

As such, sediment remains in the filtration member 210 provided in the filtration unit 200, and collection of the sediment is possible through the collection unit 400. The collection of sediment is a method of directly collecting the sediment in a solid state, or by dissolving the sediment in a solid state with a special solution such as an acidic solution to obtain a solution in which a specific substance is concentrated. As in the latter, a container 10 containing a special solution can be used, as shown in Fig. 1, to dissolve the solid-state precipitate.

That is, since the collection unit 300 and the collection unit 400 are all provided in a single device for filtering and collecting samples through the filtering unit 200, the configuration of the filtering device is simplified, and through this, an operator must perform This has the effect of simplifying the work and increasing convenience.

In addition, a vacuum unit 500 is provided to facilitate the filtration and collection process of the sample, and the vacuum unit 500 is composed of a single vacuum unit 500 and collects and collects a sample through the recovery unit 300 It is provided so that a vacuum pressure can be selectively formed in the sediment collection process through the part 400.

To this end, the vacuum unit 500 is provided with a valve member 510 and a pump member 520, and since a single pump member 520 can be commonly used for two tasks, the configuration of the device is simplified to reduce manufacturing cost. It has an effect. The valve member 510 and the pump member 520 will be described later.

At this time, as shown in FIG. 3, the filter unit 200 is formed with a common mounting surface 220 to which the recovery unit 300 or the collection unit 400 is connected. That is, when the sample filtration process is in progress, the recovery unit 300 is connected to the common mounting surface 220 so that the filtered sample is recovered, and when the sediment collection process is performed, the collection unit 400 is provided on the common mounting surface 220. It is connected and sediment is collected. Referring to FIG. 1, the recovery unit 300 is connected to the common mounting surface 220 of the filtration unit 200 located on the second and fourth from the left, and on the first, third and fifth from the left. The collection unit 400 is connected to the common mounting surface 220 of the filtration unit 200 located.

When the common mounting surface 220 is formed in the filter unit 200 as described above, the filter unit 200 can be used in common regardless of the sample filtration process or the sediment collection process. By selectively connecting the and the collection part 400, it is possible to filter the sample and collect the precipitate in a single device.

The recovery unit 300 is connected to some of the plurality of filtration units 200 of FIG. 1, and the collection unit 400 is connected to the other portion, but all of the recovery units are collected according to a required process during filtration or collection of the sample ( It is also possible to connect 300), or to connect the entire collection unit 400.

As illustrated in FIG. 1, the recovery unit 300 includes a recovery tube 310 to which a sample to be recovered is mounted and mounted on the common mounting surface 220 described above, and a sample recovered through the recovery tube 310. A collection container 320 accommodated is provided.

That is, the sample accommodated in the sample portion 100 is filtered through the filtration unit 200, the precipitate is filtered, the remaining sample is moved to the recovery tube 320 after moving along the recovery tube 310. At this time, the recovery unit 300 is provided with a first vacuum tube 330 for connecting the recovery container 320 and the vacuum unit 500, the first vacuum tube 330 as the vacuum unit 500 operates Through this, a vacuum pressure is formed inside the recovery container 320, and through this, the sample moving along the recovery tube 310 can be smoothly moved. After moving along the recovery tube 310, it is necessary to be configured so that the sample flowing into the recovery container 320 does not flow out again through the first vacuum tube 330, and for this purpose, the first vacuum tube 330 is recovered It is disposed at a position higher than the end of the tube 310. With this configuration, after moving along the recovery tube 310, the sample flowing into the recovery tube 320 moves downward by gravity, so that the sample flows out through the first vacuum tube 330 at a relatively high position. Can be effectively prevented.

The recovery tube 300 may be configured such that the recovered tube 310 is directly connected to recover the filtered sample, but as illustrated in FIGS. 1 and 2, the first and second recovery tubes 310a and 2 are separated. It is also possible to configure the filtered sample to be recovered by connecting the recovery tube 310b to the recovery tube 310.

When the flow path through which the filtered sample is recovered is configured in such a way that the flow paths separated into a plurality of channels are interconnected, the same configuration as the first connection portion 311 can be additionally installed in the middle of the flow path through which the sample is recovered.

As illustrated in FIG. 4, the first connection part 311 is provided to filter a plurality of samples 100 at the same time, and for this purpose, a plurality of inlet ports are provided. The second recovery tube 310b is connected to the inlet port so that the sample to be recovered can be introduced into the first connector 311, and the sample simultaneously introduced through the plurality of inlet ports is first through the outlet port. The connection part 311 is discharged to the outside, and a recovery tube 310 is connected to the outflow port, so that the filtered sample is introduced into the collection container 320.

When using the first connecting portion 311 provided with a plurality of inflow ports as described above, since a plurality of samples can be filtered simultaneously, it is possible to quickly filter a large amount of samples.

When the above-described second recovery tube 310b and the inlet port provided in the first connection part 311 are connected, the flow path is automatically opened, and when it is separated, the flow path can be automatically closed. There is an effect of increasing the convenience of.

As illustrated in FIGS. 1 to 3, the collection part 400 includes a collection tube 410 mounted on the above-mentioned common mounting surface 220 and a collection tube such that vacuum pressure is formed inside the collection tube 410. A vacuum flow path 420 communicating with the 410 and the vacuum unit 500 is provided.

That is, the collection unit 400 collects the filtered precipitate on the filtration member 210, and is provided with a container 10 containing a special solution to dissolve the precipitate in the solid state. The special solution accommodated in the container 10 dissolves the precipitate while passing through the filtration unit 200, and the special solution in which the precipitate is dissolved moves to the collection tube 410. At this time, as described above, the collection part 400 is provided with a vacuum flow path 420 communicating the collection tube 410 and the vacuum part 500 so that a vacuum pressure is formed inside the collection tube 410, and the vacuum part. As 500 is operated, vacuum pressure is formed inside the collection tube 410 through the vacuum flow path 420, and a special solution moving to the collection tube 410 can be smoothly moved. At this time, it is necessary to be configured so that the special solution moving to the collection tube 410 does not flow through the vacuum passage 420, and for this purpose, as shown in FIG. 3, the vacuum passage 420 is the collection tube 410 It is placed in a position higher than the top.

2, the vacuum flow path 420 is connected to the vacuum unit 500 through the second vacuum tube 430, and a flow path in which a plurality of flow paths in which vacuum pressure is formed is separated from each other is connected to each other. If configured as, it is possible to additionally install components such as an opening / closing member 421, a second connecting portion 431, and a filter member 432 in the middle of the flow path.

As shown in FIG. 4, a first connection tube 420a is connected to the vacuum flow path 420, and an opening / closing member 421 is connected to the first connection tube 420a. The opening / closing member 421 is provided to selectively connect the vacuum passage 420 and the vacuum part 500, and when the sample filtration process is performed, the opening / closing member 421 is closed and the vacuum passage 420 inside. When the vacuum pressure is not formed and the sediment collection process is in progress, the inside of the opening / closing member 421 is opened to be configured to form a vacuum pressure inside the vacuum flow path 420.

The opening / closing member 421 can be used in any configuration as long as it can open and close the flow path, such as a valve or a quick coupler.

In addition, a second connection tube 420b is connected to the opening / closing member 421, and the second connection tube 420b is connected to the second connection part 431. The second connection part 431 is provided with a plurality of first vacuum ports such that a vacuum pressure is simultaneously formed inside the plurality of collection tubes 410. The second connection part 431 is provided with a second vacuum port, and the second vacuum port is sequentially connected to the third connection tube 430a, the fourth connection tube 430b, and the second vacuum tube 430. , The second vacuum tube 430 is connected to the vacuum unit 500. That is, the vacuum pressure formed as the vacuum unit 500 operates is sequentially through the second vacuum tube 430, the fourth connection tube 430b, the third connection tube 430a, and the second connection unit 431. It is transferred to form a vacuum pressure inside the collection tube 410.

As described above, when the second connection part 431 provided with the plurality of first vacuum ports is used, a vacuum pressure can be simultaneously formed inside the plurality of collection tubes 410, so that the collection process of the precipitate can be rapidly progressed.

The aforementioned first vacuum port or the second vacuum port automatically opens the flow path when the second connection tube 420b and the third connection tube 430a are connected, and the second connection tube 420b and the third connection tube ( 430a) can be configured to automatically close the flow path when separated, and this configuration has the effect of increasing operator convenience.

The vacuum unit 500 is provided with a single pump member 520 to form a vacuum pressure, and using the single pump member 520, it is possible to form a vacuum pressure during the filtration and sediment collection process of the sample. A valve member 510 in which a plurality of flow paths are formed is provided. That is, a first vacuum tube 330 used in the process of filtration of the sample is connected to one flow path inside the valve member 510, and a second vacuum tube 430 used in the process of collecting sediment is connected to the other flow path.

As such, since the valve member 510 is provided to selectively connect the single pump member 520, the filtration and collection process can be smoothly performed, and the single pump member 520 can be commonly used for two tasks. Since the configuration of the device can be simplified, there is an effect of reducing the manufacturing cost.

The filtration method using a sample filtration device according to the present invention is a step (S1) of connecting the sample part 100 containing the sample to the filter part 200, as shown in FIG. 5, and this filter part 200 It includes the step (S2) of recovering the filtered sample through the recovery unit (300) and collecting the precipitate remaining on the filtering member (210) of the filtering unit (S3).

At this time, the step (S2) of recovering the filtered sample while passing through the filtration unit 200 to the recovery unit 300 is connected to one end of the recovery tube 310 to the common mounting surface 220 of the filtration unit 200 , Connecting the other end to the recovery vessel 320 and forming a vacuum pressure in the recovery vessel 320 to recover the sample. That is, when the sample filtration process is in progress, the collection tube 310 is connected to the common mounting surface 220 formed in the filtering unit 200 so that the filtered sample is recovered.

In addition, in the step (S3) of collecting the precipitate remaining on the filtration member 210 of the filtration unit 200, when the sample recovery is completed, the recovery tube 310 is separated from the common mounting surface 220, and the common mounting surface ( The step of connecting the collection tube 410 to 220), and collecting a precipitate by forming a vacuum pressure inside the collection tube (410). That is, when the sediment collection process is in progress, the sediment is collected by connecting the collection tube 410 to the common mounting surface 220 formed in the filtration unit 200.

When the common mounting surface 220 is formed in the filter unit 200 as described above, the filter unit 200 can be used in common regardless of the sample filtration process or the sediment collection process. By selectively connecting the and the collection tube 410, it is possible to filter the sample and collect the precipitate in a single device.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art to understand the spirit of the present invention may add elements within the scope of the same spirit. However, other embodiments may be easily proposed by changing, deleting, adding, or the like, but it will also be considered to be within the scope of the present invention.

10: special solution container 100: sample portion
200: filtration unit 210: filtration member
220: common mounting surface 300: recovery unit
310: recovery tube 310a: first recovery tube
310b: second recovery tube 311: first connection
320: collection container 330: first vacuum tube
400: collection unit 410: collection tube
420: vacuum flow path 420a: first connection tube
420b: second connecting tube 421: opening and closing member
430: second vacuum tube 430a: third connection tube
430b: 4th connecting tube 431: 2nd connecting part
432: filter member 500: vacuum
510: valve member 520: pump member
ℓ: sediment collection flow p: vacuum pressure flow during collection

Claims (8)

A sample part accommodating the sample containing the precipitate;
A filter part connected to the sample part and provided with a filtration member;
A recovery unit through which the filtered sample is recovered while passing through the filtering unit;
A collection unit for collecting the precipitate remaining in the filtration member; And
A vacuum unit provided to form a vacuum pressure in the recovery unit or the collection unit;
It includes,
In the vacuum section, a plurality of flow paths are formed inside, and a valve member selectively communicating with the recovery section or the collection section and a single pump member connected to the valve member to form a vacuum pressure are provided. Sample filtration device. According to claim 1,
A sample filtration device characterized in that a common mounting surface to which the collection unit or the collection unit is connected is formed in the filtration unit. According to claim 2, The recovery unit,
A recovery tube mounted on the common mounting surface and on which a sample to be recovered moves;
A collection container in which a sample collected through the collection tube is accommodated; And
A first vacuum tube connecting the recovery tube and the vacuum part;
A sample filtering device comprising a. According to claim 3, The collection unit,
A collection tube mounted on the common mounting surface;
A vacuum flow path communicating the collection tube and the vacuum unit so that a vacuum pressure is formed inside the collection tube;
A sample filtering device comprising a. According to claim 4,
The valve member is a sample filtration device, characterized in that in communication with the first vacuum tube or the vacuum flow path. Connecting the sample part containing the sample to the filter part;
Recovering the filtered sample through the filtering unit to a recovery unit; And
Collecting sediment remaining in the filtration member of the filtration unit in the collection unit;
Including,
The step of recovering the filtered sample and the step of collecting the precipitate are formed with a plurality of flow paths therein, and a valve member selectively connected to the recovery part or the collection part, and connected to the valve member to form a vacuum pressure. Is achieved by using a single pump member,
The steps are sample filtration method characterized in that it is made using a single sample filtration device. The method of claim 6,
The step of recovering the filtered sample through the filtration unit to the recovery unit,
Connecting one end of the recovery tube to the filtration unit, and connecting the other end to the recovery vessel; And
Forming a vacuum pressure in the recovery container to recover a sample;
Sample filtration method comprising a. The method of claim 7,
The step of collecting the precipitate remaining on the filtration member of the filtration unit,
Separating the collection tube from the filter unit when the sample recovery is completed, and connecting the collection tube to the filter unit; And
Collecting a precipitate by forming a vacuum pressure inside the collection tube;
Sample filtration method comprising a.

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