KR102594607B1 - Sample sampling device - Google Patents

Abstract

The present invention is a technology related to a sample sampling device that automatically extracts and supplies a predetermined amount of sample to analyze the components of various powdery or granular raw materials, and is installed so that one end is connected to the outlet through which the raw materials fall. , an induction tube in the shape of a hollow tube with an empty interior; A core tube that is inserted into the induction tube, has the shape of a hollow tube with an empty interior, is provided with one or more downwardly opening discharge chutes near the rear end, and can be moved forward and backward along the induction tube by a predetermined actuator. ; A rotating body disposed inside the core tube and having threads formed on its outer surface to rotate at a fixed position; A moving body that is coupled to the rotating body and receives rotational force to move in a straight line; It is characterized in that it includes; at least one metering receiver connected to one end of the moving body and exposed to the outside of the front end of the core tube to receive a portion of the raw material falling from the outlet.

Description

Sample sampling device {Sample sampling device}

The present invention is a technology related to a sample sampling device that automatically extracts and supplies a predetermined amount of sample to analyze the components of various powdery or granular raw materials.

Various raw materials used as industrial materials are often in the form of powder or particles, and component analysis of these raw materials is often necessary during the manufacturing process. In other words, since the raw materials input into the manufacturing process line are often imported from various countries, the quality of the same raw materials often varies from lot to lot, so at least sampling analysis of the raw materials is required to produce products of excellent quality. do.

Currently, the component analysis of raw materials being carried out in industrial sites involves workers periodically putting the raw materials into a predetermined container and then putting them into a component analyzer for component analysis. However, the fine powder or particle-like raw materials scatter and are not used by the operator. There were problems that were fatal to the health of people, and there were also problems that various errors occurred because it was done by manpower.

Meanwhile, in order to periodically and accurately analyze these raw materials, it is necessary to clean the sampling device every time a sample is extracted.

Republic of Korea Patent No. 10-1061883

Therefore, the present invention seeks to provide a sample sampling device that can automatically extract raw materials that can cause fatal harm to humans at an appropriate cycle and supply the appropriate amount required for analysis to the analysis device.

In addition, the present invention seeks to provide a sample sampling device that is easy to clean so as to increase the reliability of component analysis of raw materials.

The sample sampling device of the present application as presented is a sample sampling device for component analysis of raw materials in the form of powder or particles, and is installed with one end connected to the outlet through which the raw materials fall, and has the shape of a hollow tube with an empty interior. Induction tube of; A core tube that is inserted into the induction tube, has the shape of a hollow tube with an empty interior, is provided with one or more downwardly opening discharge chutes near the rear end, and can be moved forward and backward along the induction tube by a predetermined actuator. ; A rotating body disposed inside the core tube and having threads formed on its outer surface to rotate at a fixed position; A moving body that is coupled to the rotating body and receives rotational force to move in a straight line; It is characterized in that it includes; at least one metering receiver connected to one end of the moving body and exposed to the outside of the front end of the core tube to receive a portion of the raw material falling from the outlet.

Preferably, a straight guide is coupled to the inner surface of the core tube to guide the linear movement of the mobile body, and a guide groove is formed on the outer surface of the mobile body to fit into the guide.

Preferably, the upper portion of the front end portion of the core tube is partially cut to form a concave receiving groove in which the raw material can be accommodated.

Preferably, the metering receiver includes: a first connecting piece connected to one end of the moving body; a second connection piece facing the first connection piece and spaced apart from the first connection piece; A connecting rod that restrains the first connection piece and the second connection piece.

Preferably, the first connecting piece and the second connecting piece are plate-shaped bodies of a predetermined thickness and follow the inner diameter shape of the core tube, and the edges of the first connecting piece and the second connecting piece are made of synthetic resin.

Preferably, the first connecting piece and the second connecting piece are characterized in that they are formed by combining a hard material portion and a connecting material portion having a larger outer diameter than the hard material portion.

Preferably, the core pipe is provided with one or more cleaning air supply ports for internal cleaning, and a position sensor is provided to limit the stroke distance of the moving object.

The sample sampling device according to the present invention has the effect of enabling the production of high-quality products by periodically extracting a predetermined amount of raw materials on behalf of workers in a hazardous work environment and enabling component analysis.

In addition, workers can be replaced, and since cleaning is performed after sample extraction, there is an effect of increasing the reliability of component analysis by preventing mixing with previous raw materials during subsequent sample extraction.

1 is an exemplary diagram showing the use of a sample sampling device according to the present invention.
Figure 2 is a configuration diagram showing the main parts of the sample sampling device of the present invention.
Figure 3 is an exemplary diagram of an induction tube.
Figure 4 is a plan view of the core pipe.
Figure 5 is a side view of the core pipe.
Figure 6 is an example diagram of a guide.
Figure 7 is a schematic perspective view of the rotating body, moving body, and metering receiver installed inside the core pipe.
Figure 8 is a perspective view showing a state in which the moving body is separated from the rotating body.
Figure 9 is another example showing a state in which a moving object and a metering receiver are combined.
Figure 10 is an operational example showing a process in which a predetermined amount of sample is collected in a metering receiver and then discharged through a discharge chute.

Hereinafter, a more detailed description will be given of the sample sampling device according to the present invention, with reference to the attached drawings. However, the presented drawings and detailed description thereof illustrate an example of a possible implementation according to the technical idea of the present invention, and the scope of technical protection of the present invention is not limited thereto.

Figure 1 is an exemplary diagram of the use of a sample sampling device according to the present invention, Figure 2 is a configuration diagram showing the main parts of the sample sampling device of the present invention, Figure 3 is an exemplary diagram of an induction tube, and Figure 4 is a diagram of a core tube. It is a top view, Figure 5 is a side view of the core tube, Figure 6 is an example view of a guide, Figure 7 shows a schematic perspective view of the rotating body, moving body, and metering receiver installed inside the core pipe, and Figure 8 is a rotating body It is a perspective view showing the state in which the moving body is separated from, and Figure 9 is another example showing the state in which the moving body and the metering receiver are combined, and Figure 10 shows a sample that is discharged through the discharge chute after a predetermined amount of sample is collected in the metering bowl. This is an operational example showing the process.

As shown, the sample sampling device of the present invention includes a guide tube 100, a core tube 200, a rotating body 300, a moving body 400, and a metering receiver 500 as major components. In addition, the sample sampling device of this institution is used to periodically extract samples and supply them to the analysis device for component analysis of powdered or granular raw materials used for various industrial purposes.

Powdered or granular raw materials are supplied to the manufacturing line through the discharge port 10, and one end of the guide pipe 100 is connected to one side of the discharge port 10. The induction pipe 100 has the shape of a hollow tube with an empty interior, and both ends are open, and one end of the induction pipe 100 is installed to communicate with the inside of the outlet 10.

The core tube 200 is installed to be inserted into the guide tube 100, and the core tube 200 is preferably longer than the length of the guide tube 100. The core tube 200 also has the shape of a hollow tube with an empty interior. Both ends are open, and one or more discharge chutes 210 opening downward are provided near the rear end of the core pipe 200. And the core tube 200 and the guide tube 100 are connected by a predetermined actuator 20, so that the core tube 200 moves forward and backward along the guide tube 100 with respect to the fixed guide tube 100.

The actuator 20 for the forward and backward motion of the core tube 200 can use something like an air cylinder. After one side of the cylinder 21 is fixed to the guide tube 100, the end of the piston 22 is moved to the core. It is configured to be connected to the rear end of the pipe 200 so that the core pipe 200 can move forward and backward along the guide pipe 100. However, since it is an example of an actuator of an air cylinder, any one that can perform an equivalent function can be used.

A rotating body 300 is installed inside the core pipe 200, and preferably the rotating body 300 is arranged coaxially with the core pipe 200. Screw threads are formed entirely on the outer surface of the rotating body 300, and the rotating body 300 rotates forward and backward in a fixed position. The rear end of the rotating body 300 is disposed to protrude from the rear end of the core tube 200 to receive the rotational force of a predetermined drive motor so that it can rotate in the forward or reverse direction.

And a moving body 400 coupled to the rotating body 300 is provided, and a screw portion corresponding to the screw thread formed on the outer surface of the rotating body 300 is formed at the center of the moving body 400 to attach the moving body 400 to the rotating body 300. ) is screwed together, and as the rotating body 300 rotates in a fixed position, the moving body 400 moves in a straight line.

In order to guide the moving body 400, which receives the rotational force of the rotating body 300, to move in a straight line, it is preferable that a straight guide 220 be coupled to the inner surface of the core tube 200, and the moving body 400 A guide groove 410 that is inserted into the guide 220 is formed on the outer surface of .

More specifically, the guide 220 provided on the inner surface of the core tube 200 is suitably a long solid rod having a predetermined outer diameter, and the connection blocks 221 protruding at predetermined intervals are coupled to the outer surface of the solid rod. The guide 220 is fixedly connected to the core pipe 200 using the connection block 221. For this purpose, the core pipe 200 has a block hole 230 through which the connection block 221 can be inserted. After forming the connection blocks 221 into the block holes 230, they are fixedly installed through welding.

Meanwhile, one or more metering receivers 500 are coupled to one end of the moving body 400, and the metering receiver 500 is exposed to the outside of the front end of the core tube 200 and collects a portion of the raw material falling from the discharge port 10. Receive a predetermined amount of sample for component analysis.

That is, the metering receiver 500 is integrated with the moving body 400 and moves forward and backward together, and the metering receiver 500 can be divided into a plurality of pieces by a dividing plate (not shown).

On the other hand, more preferably, the upper part of the front portion of the core tube 200 is partially cut to form a concave receiving groove 240 that can accommodate the raw material, and the receiving groove 240 is provided with a metering receiver ( The raw materials that fall while 500) is positioned are accumulated in the receiving groove 240.

A more specific configuration of the metering receiver 500 will be described. The metering receiver 500 may be composed of a first connecting piece 510, a second connecting piece 520, and a connecting rod 530.

The first connecting piece 510 and the second connecting piece 520 have the same shape, and the first connecting piece 510 and the second connecting piece 520 are constrained and connected by the connecting rod 530. In addition, the first connection piece 510 and the second connection piece 520 are preferably plate-shaped bodies forming a circle equal to the inner diameter of the core tube 200. In addition, the first connection piece 510 is connected to one end of the moving body 400, so that the metering receiver 500 moves forward and backward together with the moving body 400.

The second connecting piece 520 is arranged to face the first connecting piece 510 at a predetermined distance from each other and is coupled to the connecting rod 530. The first connecting piece 510, the second connecting piece 520, and the connecting rod are The empty space between (530) becomes the volume from which the sample is collected.

The raw material that falls while the metering receiver 500 is placed in the receiving groove 240 formed at the front end of the core tube 200 is distributed in an appropriate amount depending on the shape of the metering tray 500 and the shape of the receiving groove 240. Raw materials are received.

In addition, the edges of the first connection piece 510 and the second connection piece 520 are preferably made of synthetic resin. Accordingly, the first connection piece 510 and the second connection piece 520 may be made of a metal material, and a synthetic resin material may be added to the edge. Preferably, the first connection piece 510 and the second connection piece 520 are also provided with a guide groove 503 similar to the guide groove 410 formed on the moving body 400, so that they can be moved without interference while being inserted into the guide 220. Let's do it.

Meanwhile, in another form, the first connection piece 510 and the second connection piece 520 are made of hard material 501 with a size smaller than the inner diameter of the core tube 200, and the moving body 400 and the first connection piece 510 are formed. ) can be combined, and a connecting material portion 502 having a larger outer diameter than the hard material portion 501 can be added to make it integrally coupled. The outer diameter of the soft material portion 502 is sized to be in contact with the inner diameter of the core tube 200 to stably transfer the raw material contained in the metering receiver 500 so that it can be supplied through the discharge chute 210. .

In addition, the core pipe 200 may be provided with one or more cleaning air supply ports 250 for internal cleaning, and when high-pressure air is supplied through the cleaning air supply port 250, the inner diameter surface of the core pipe 200 Raw materials remaining or remaining on the surface of the metering receiver 500 can be easily removed.

In addition, a position detection sensor (not shown) may be provided to limit the stroke distance of the mobile body 400, which moves in a straight line in conjunction with the rotation of the rotating body 300, and detects the maximum forward position and maximum retreat position of the mobile body. make it possible

Next, an example of using the sample sampling device according to the present invention will be described.

Assume that raw materials are falling through the discharge port and being supplied to the manufacturing line.

At a set time, the drive motor operates to rotate the rotating body, and as a result, the moving body moves to the maximum forward position. When the moving object moves to the maximum forward position, the metering receiver is located in the receiving groove at the front end of the core pipe.

Then, the actuator operates to advance the core tube itself so that the end of the core tube enters the inside of the discharge port, and as a result, some of the falling raw materials accumulate in the metering receiver.

Subsequently, as the rotor rotates in the reverse direction, the moving body and the metering receiver retreat, and the raw materials accumulated in the metering tray also move together, and when they reach the discharge chute, the raw materials automatically fall downward through the discharge chute.

For the next sampling operation, high-pressure air is sprayed into the core pipe through the cleaning air supply port so that any remaining raw materials can be thoroughly removed.

As described above, the sample sampling device according to the present invention automatically extracts an appropriate amount of raw materials requiring component analysis and supplies them to the analysis device, thereby ensuring component analysis on a regular basis and at the same time ensuring the reliability of component analysis. There is an advantage.

The present invention is a technology that can be usefully used as an automatic sample sampling device for component analysis of various powdery or granular raw materials.

100: Induction tube
200: Core pipe
210: discharge chute 220: guide
221: connection block 230: block hole
240: Receiving groove 250: Cleaning air supply port
300: rotating body 400: moving body
410: Guide groove 500: Metering receiver
510: 1st connection 520: 2nd connection
530: Connecting rod 501: Hard material part
502: Soft material section
10: outlet 20: actuator
21: cylinder 22: piston

Claims (7)

A sample sampling device for component analysis of powder or granular raw materials,
an induction tube in the shape of a hollow tube, the inside of which is installed so that one end is connected to the outlet through which the raw material falls;
A core tube that is inserted into the induction tube, has the shape of a hollow tube with an empty interior, is provided with one or more downwardly opening discharge chutes near the rear end, and can be moved forward and backward along the induction tube by a predetermined actuator. ;
A rotating body disposed inside the core tube and having threads formed on its outer surface to rotate at a fixed position;
A moving body that is coupled to the rotating body and receives rotational force to move in a straight line;
It includes one or more metering receivers connected to one end of the moving body and exposed to the outside of the front end of the core tube to receive a portion of the raw material falling from the outlet,
A straight guide is coupled to the inner surface of the core tube to guide the linear movement of the moving body, and a guide groove is formed on the outer surface of the moving body to be inserted into the guide,
The guide includes a plurality of connection blocks protruding at predetermined intervals from the outer surface of the solid rod, and a block hole into which the connection block can be inserted is formed in the core tube, so that the connection block is inserted into the block hole and then welded. A sample sampling device characterized in that. delete According to claim 1,
A sample sampling device characterized in that the upper portion of the front end portion of the core tube is partially cut to form a concave receiving groove in which the raw material can be accommodated. According to claim 1 or 3,
The metering receiver is,
a first connection piece connected to one end of the mobile body;
a second connection piece facing the first connection piece and spaced apart from the first connection piece;
A sample sampling device comprising a connecting rod that restrains the first connection piece and the second connection piece. According to claim 4,
The first connecting piece and the second connecting piece are plate-shaped bodies of a predetermined thickness and follow the inner diameter shape of the core tube,
A sample sampling device, characterized in that edges of the first connecting piece and the second connecting piece are made of synthetic resin material. According to claim 4,
The first connection and the second connection,
A sample sampling device comprising a combination of a hard material portion and a connecting material portion having a larger outer diameter than the hard material portion. According to claim 4,
A sample sampling device characterized in that the core tube is provided with one or more cleaning air supply ports for internal cleaning, and a position detection sensor is provided to limit the stroke distance of the moving object.

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