KR101659233B1 - Apparatus of producing specimen - Google Patents

Abstract

According to the present invention, a specimen manufacturing apparatus, comprises: a heating block which has a plurality of heating grooves to melt a specimen loaded on one side; a cooling block which adheres to the heating block or is moved to be separated from the heating block, having a plurality of cooling grooves in positions corresponding to the heating grooves of the heating block to manufacture the specimen by receiving and cooling the specimen melted in the heating grooves; an inserter which inserts the specimen into the heating grooves, and is moved to a space between the heating and cooling blocks to receive the specimen drawn out of the cooling grooves of the cooling block; and a reversion motor which integrally rotates the heating and cooling blocks to vertically be reversed.

Description

{APPARATUS OF PRODUCING SPECIMEN}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a specimen manufacturing apparatus, and more particularly, to a specimen manufacturing apparatus for producing a specimen by melting and cooling a specimen.

In order to accurately analyze the components of the metal sample, it is necessary to melt the sample once, disperse the components more uniformly, and then cool the sample to prepare the specimen. The preparation of such specimens can make the qualitative and quantitative analysis of the components more smooth.

Therefore, a solid sample is put in a heating furnace, heated and melted, cooled in a specific type of frame that can be analyzed, and the thus-prepared sample is analyzed using an analyzer.

If there is a problem in the manufacturing process of the specimen, the deviation of the specimen measurement data becomes large. Therefore, it is important to manufacture a more uniform specimen.

FIG. 1 shows a conventional process of manufacturing a sample. 1, a sample container 20 is inserted into a mold 10 composed of a lower mold 11 and an upper mold 12, and a jig 30 is used for the sample container 20 The sample 1 is put into the mold 10 and the mold 10 is closed and heated to melt the sample 1 with the molten sample 2. When the melting is completed, the sample 1 is cooled to prepare the sample 3. Thereafter, the sample container 20 is taken out of the mold 10, and the sample container 20 is turned over and hammered with a hammer or the like to separate the sample piece 3 from the sample container 20.

In this case, it takes a long time for the molten specimen 2 to be cooled by the specimen 3, and when the specimen 3 is separated from the specimen bottle 20 by the hammer, the specimen bottle 20 and the specimen 3 may be broken have.

In addition, since the manufacturing time is excessively consumed in the manufacturing process as described above, it is difficult to obtain the analysis data at a desired time, and data such as the data of the workpiece is different depending on the manufacturing skill of the user.

A method of producing a mold type sample for the quantitative analysis of alloy iron (Korean Patent Laid-Open No. 10-2003-0026385 (2003.04.03)) and a sample extraction device for component analysis (Korean Utility Model No. 20-1999-0026240 (1999.07. 15)) ", a method and an apparatus for producing a specimen are known.

The method for producing the mold-type sample for the quantitative analysis of alloy iron is characterized in that, in the production of an alloyed iron sample in the form of a mold, the alloy is melted at a high temperature using a high-frequency induction melting furnace and centrifugally casted to make a mold- .

In addition, the sample extraction device for analyzing a component is a device capable of taking out a sample while lifting and lowering a table provided on a floor surface in an injection space.

However, all of the above-mentioned inventions have a problem that rapid cooling of the specimen is difficult due to cooling in the heating mold, and a time difference occurs between the withdrawal of the finished specimen and the introduction of the new specimen, thereby increasing the processing time.

Therefore, there is a need for a new apparatus capable of producing a uniform test piece within a shortened process time.

Korean Patent Laid-Open No. 10-2003-0026385 (Apr. 2003) Korea public utility model 20-1999-0026240 (July 15, 1999)

SUMMARY OF THE INVENTION The present invention has been made to solve such problems, and an object of the present invention is to provide a specimen manufacturing apparatus capable of improving a process speed while manufacturing a specimen of a constant quality.

According to an aspect of the present invention, there is provided an apparatus for manufacturing a specimen, comprising: a heating block having a plurality of heating grooves for melting and melting a sample on one side; A plurality of cooling grooves formed at positions corresponding to the heating grooves of the heating block so as to be closely contacted with or separated from the heating block and to receive and melt the molten samples in the heating grooves to produce the test pieces Cooling block; An inserter for drawing the sample into the heating groove and entering a space between the heating block and the cooling block to receive a specimen drawn out from the cooling groove of the cooling block; And a reversing motor for rotating the heating block and the cooling block integrally to flip up and down.

Further comprising: a frame supporting the heating block and the cooling block; and a lifting cylinder installed to connect the frame and the cooling block to lift the cooling block, wherein the reversing motor is connected to the frame, So as to vertically invert.

And an ejector pipe protruding from the plane of each of the cooling grooves to protrude the protrusion from the cooling grooves and eject the separated liquid into the cooling grooves.

The ejector cylinder being connected to the ejector pipe to move the ejector pipe up and down, and the ejector cylinder is connected to the ejector pipe, and the ejector pipe is connected to the ejector pipe, And a working space in which a pipe is inserted and can be raised and lowered is formed.

Wherein the ejector pipe is provided with a space through which the separating liquid can flow and an ejector pipe inserted into the ejector pipe to open and close the end of the ejector pipe is provided at an end of the ejector pipe, A first spring installed in the ejector pipe for urging the ejector cover toward the inner side of the ejector pipe, and a second spring provided around the ejector pipe to press the ejector pipe in the opposite direction protruding into the cooling groove, The ejector cover is projected from the ejector pipe to eject the separation liquid to the inner surface of the cooling groove. When the ejector cylinder is extended, the ejector cover is ejected from the ejector pipe, And a pipe protrudes from the cooling groove All.

Wherein the ejector cover is formed in an H shape and one end thereof closes the end of the ejector pipe and the first spring is inserted into the central portion thereof to press the other end inner side surface in the direction of the ejector pipe do.

The inserter includes an inserter base which enters between the heating block and the cooling block and has a concave sample space formed on one surface thereof and a specimen-receiving groove formed on the other surface thereof; a cover motor installed at one side of the inserter base; And a cover rotatably connected to the cover rotating shaft to integrally rotate with the cover rotating shaft so as to open and close the sample space, and an inserter connected to the inserter base for inverting the inserter base up and down Wherein the specimen drawn out of the cooling groove is dropped onto the specimen receiving groove when the cover is opened and the specimen loaded in the specimen space is loaded on the heating groove.

Wherein the inserter motor is mounted on a platform so as to be able to move up and down, the platform is provided with an ascending / descending body connected to the inserter motor, an elevating shaft rotated vertically through the ascending / descending body, And a lifting and lowering motor for rotating the lifting and lowering shaft, and a platform bar for horizontally moving the platform.

A pair of columns supporting the frame and a moving plate for supporting the column, wherein the reversing motor is connected to one of a pair of rotation shafts protruding from both ends of the frame and inserted into the column .

And a moving plate cylinder mounted on the base for horizontally moving the moving plate. The moving plate includes a base for supporting the moving plate, the moving plate being movable on the moving plate.

The apparatus for producing a sample according to the present invention has the following effects.

First, it is possible to manufacture specimens of constant quality regardless of the skill of the operator by automating the manufacturing process of the specimen.

Second, the specimen can be prevented from breakage by minimizing the impact when it is separated from the frame after cooling of the specimen.

Third, sample preparation and sample recovery can be performed at the same time, which shortens sample preparation time.

Fourth, uniform specimen can be manufactured by applying vibration during sample melting.

1 is a view showing a conventional sample preparation process,
FIG. 2 is a front view showing a specimen manufacturing apparatus according to an embodiment of the present invention. FIG.
3 is a side view showing a specimen manufacturing apparatus according to an embodiment of the present invention,
4 is an enlarged cross-sectional view of the cooling block,
5 is a partially enlarged view of the cooling block showing the closed state of the ejector pipe,
6 is a partially enlarged view of the cooling block showing the opened state of the ejector pipe,
7 is a partially enlarged view of the cooling block showing the projecting state of the ejector pipe,
8 is a perspective view showing the inserter,
9 is a view showing a sample loaded on an inserter,
10 is a view showing a state in which a specimen is loaded into a heating groove in the inserter and the specimen drawn out from the cooling groove is loaded.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms as used herein include plural forms as long as the phrases do not expressly express the opposite meaning thereto. Means that a particular feature, region, integer, step, operation, element and / or component is specified, and that other specific features, regions, integers, steps, operations, elements, components, and / And the like.

Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Commonly used predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

Hereinafter, a specimen manufacturing apparatus according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 2 and 3, the present invention includes a heating block 200 having a heating groove 210 for melting a sample, and a cooling groove 330 formed by cooling the molten sample to be cooled, The cooling block 300 is vertically disposed facing each other and the reversing motor 141 is installed so that the heating block 200 and the cooling block 300 are reversed to change the vertical relationship.

The cooling block 300 is installed so as to be able to move up or away from the heating block 200. When the cooling block 300 and the heating block 200 are separated from each other, An inserter 400 is further provided for receiving the completed specimen in the cooling block 300 while supplying the specimen.

Hereinafter, the state where the cooling block 300 is positioned above and the heating block 200 is positioned below is referred to as a basic state for convenience, and the state where the cooling block 300 is positioned on the upper side and the heating block 200 is positioned on the upper side State.

The heating block 200 and the cooling block 300 are supported by a frame 140. An elevating cylinder 340 is fixed to the frame 140 and a rod of the elevating cylinder 340 is fixed to the cooling block 300 So that the cooling block 300 is moved up and down.

The shape of the frame 140 is not particularly limited, but is preferably formed in a rectangular frame shape so that the heating block 200 and the cooling block 300 are disposed in the central space. At this time, the heating block 200 is directly fixed to the frame 140, and the cooling block 300 is connected to the frame 140 via the lifting cylinder 340.

On both sides of the frame 140, a pair of rotation shafts are respectively protruded. The rotation shafts are inserted into the pair of columns 130 to support the frame 140. An inverting motor 141 is connected to one end of the pair of rotating shafts which is fixed to the pillar 130 so as to rotate the frame 140 as a whole to connect the heating block 200 and the cooling block 300).

Also, the column 130 is installed on the moving plate 110, and the moving plate 110 is installed horizontally movably on the base 100. Further, a moving plate cylinder 120 installed in the base 100 may be further installed to vibrate the moving plate 110 in the horizontal direction. The moving plate cylinder 120 vibrates the moving plate 110 so that the melted sample can be mixed more uniformly in the heating block 200 and the cooling block 300.

As shown in FIG. 4, an ejector pipe 310 is inserted into the cooling block 300 so as to be vertically movable. The ejector pipe 310 is formed with an end portion that can protrude from each inner plane of each cooling groove 330, and a hollow is formed therein so that the separated liquid can flow. The ejector cylinder 311 provided in the frame 140 is connected to the ejector pipe 310 and the ejector pipe 310 is moved up and down by the operation of the ejector cylinder 311.

At each end of the ejector pipe 310, there is provided a structure capable of spraying the separated liquid. This configuration is specifically shown in Figs.

5 to 7, an ejector cover 315 is provided at an end of the ejector pipe 310 so that the ejector cover 310 can be lifted and lowered to open and close the ejector pipe 310. In order to maintain the ejector cover 315 in a closed state, More specifically, a second spring 314 is installed to pull the ejector cover 315 inwardly of the ejector pipe 310 to be inserted into the ejector pipe 310 and to close the end thereof. When the separation liquid is supplied into the ejector pipe 310, the second spring 314 is compressed by the pressure of the separation liquid, and the ejector cover 315 protrudes from the end of the ejector pipe 310, Be sprayed

The ejector cover 315 is formed in a shape in which the H letter is rotated by 90 degrees. The second spring 314 is disposed so as to surround the central vertical line and the second spring 314 is disposed at the upper side of the ejector cover 315 So as to press the ejector cover 315 toward the inside of the ejector pipe 310.

The timing at which the sample 3 is ejected from the cooling groove 330 and the timing at which the cooling block 300 contacts the heating block 200 will be described later in more detail desirable.

Further, the ejector pipe 310 itself protrudes from the cooling groove 330, and the specimen 3 solidified in the cooling groove 330 can be drawn out. At this time, the ejector cylinder 311 provides a driving force for ejecting the ejector pipe 310 from the cooling groove 330. A second spring 313 for applying a force for returning the ejector pipe 310 to the inside of the cooling block 300 may be installed so as to surround the outer diameter of the end of the ejector pipe 310.

A hose 320 is connected to the ejector pipe 310 in addition to the ejector cylinder 311. The separated liquid is supplied into the ejector pipe 310 through the hose 320. The hose 320 is connected to the ejector pipe 310 and extends outwardly through the cooling block 300.

As shown in FIGS. 3 and 8 to 10, when the heating block 200 and the cooling block 300 in the basic state are spaced from each other, the inserter 400 can be inserted therebetween.

The inserter 400 is based on an inserter base 450. The inserter base 450 is formed with a sample space 453 in which a sample to be supplied to the heating groove 210 can be loaded, And a specimen holder groove 454 on which the specimen 3 can be mounted is formed on the opposite side.

The sample space 453 is opened and closed by a cover 451. The cover 451 is rotated integrally with the cover rotating shaft 455 to open and close the sample space 453. [ The cover rotating shaft 455 is installed in the inserter base 450, and a cover motor 452 is installed at one end to rotate the rotating shaft. The cover motor 452 is fixed to the inserter base 450 and the cover rotation shaft 455 is preferably spaced apart from the inserter base 450 by a predetermined distance.

It is preferable that an inserter motor 440 for rotating the inserter 400 itself and inverting the inserter 400 is additionally provided. When the specimen is loaded on the specimen space 453, the specimen space 453 moves upward And the sample space 453 must be opened toward the downward direction when the sample is dropped from the sample space 453 into the heating groove 210.

In addition to this, a platform 410 installed horizontally movably on the base 100, an ascending / descending body 430 installed so as to be movable up and down along the platform 410, And an elevating motor 420 installed at an upper end of the elevating shaft 421 to rotate the elevating shaft 421. [

A method of operating the ascending / descending member 430 is not particularly limited. For example, when the ascending / descending motor 420 rotates the ascending / descending shaft 421, The lifting body 430 can be lifted and lowered.

The inserter motor 440 is installed on the ascending / descending member 430 and is mounted on the base 100 to move the platform 410 horizontally along with the ascending / descending member 430 .

Hereinafter, the operating relationship according to the present invention will be described.

The heating block 200 and the cooling block 300 are spaced apart from each other in a basic state and the inserter 400 is positioned such that the sample space 453 is opened upward and the lifting bar cylinder 411 is contracted So that the inserter 400 is positioned at a preparation position spaced apart from the heating block 200 and the cooling block 300.

At this time, the cover motor 452 is rotated to open the sample space 453, and the sample is put into the sample space 453. When the sample is completely inserted, the cover motor 452 is rotated to close the sample space 453, and the inserter motor 440 is rotated so that the sample space 453 faces downward. Then, the elevator cylinder 411 is advanced to move the inserter 400 between the heating block 200 and the cooling block 300.

When the inserter 400 is positioned on the upper part of the heating block 200, the cover motor 452 is rotated to open the sample space 453 and to inject the sample into the heating groove 210. If it is the first operation, only the sample injection is performed, and if it is the second operation, the sample is received at the same time.

When the introduction of the sample into the heating groove 210 is completed, the lifting bar cylinder 411 is retracted to retreat the inserter 400 and the lifting cylinder 340 is operated to move the cooling block 300 to the heating block 200 And is brought into close contact.

Thereafter, the heating block 200 is operated to melt the sample loaded in the heating groove 210. In this process, the moving plate cylinder 120 moves forward and backward to uniformly mix the melted sample.

When melting of the sample is completed, the reversing motor 141 is operated to invert the heating block 200 and the cooling block 300. Accordingly, the molten material stored in the heating groove 210 is transferred to the cooling groove 330. Thereafter, the cooling groove 330 is cooled to solidify the molten specimen, and the specimen is manufactured. The cooling block 300 may be connected to a cooling block 300 through a channel formed inside the cooling block 300 so that the cooling block 300 It may be desirable to cool the entire system.

When the molten specimen stacked in the cooling groove 330 is completely solidified to produce the test piece 3, the reversing motor 141 is operated to return the heating block 200 and the cooling block 300 to the basic state again. Then, the lifting cylinder 340 is operated to separate the cooling block 300 from the heating block 200.

The inserter 400 in which the sample is loaded in the sample space 453 advances to enter between the heating block 200 and the cooling block 300 to load the sample in the heating groove 210.

The ejector cylinder 311 is operated to project the ejector pipe 310 from the cooling groove 330 so that the test piece 3 is moved to the cooling groove 330. In this case, 3 are separated from the cooling grooves 330 and fall down. The falling specimen 3 is loaded on the specimen holder groove 454 formed in the inserter 400 and the specimen 3 loaded on the specimen holder groove 454 can be recovered when the inserter 400 is retracted .

When the test piece 3 is detached, the ejector cylinder 311 is retracted and the ejector pipe 310 is returned to the inside of the cooling groove 330. In this process, the second spring 313 assists the return of the ejector pipe 310.

After the ejector pipe 310 is returned, the separation liquid is supplied through the hose 320. The separating liquid is a material for facilitating the separation between the mold and the casting, and is a material for facilitating the separation of the specimen 3 in the cooling groove 330.

When the separation liquid is supplied into the ejector pipe 310 through the hose 320, the ejector cover 315 protrudes to the end of the ejector pipe 310 by the pressure of the separation liquid. When the ejector cover 315 is protruded, a gap is formed and the separated liquid is sprayed onto the wall surface of the cooling groove 330. Then, the molten specimen is received and solidified to facilitate separation when the specimen is manufactured.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand.

It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be interpreted as being included in the scope of the present invention .

1: Sample 2: Melted sample
3: Piece 10: mold
11: lower mold 12: upper mold
20: sample container 30: jig
100: Base 110: Movable plate
120: moving plate cylinder 130: column
140: Frame 141: Reverse motor
200: heating block 210: heating groove
300: cooling block 310: ejector pipe
311: Ejector cylinder 312: Ejector rod
313: second spring 314: first spring
315: ejector cover 320: hose
330: cooling groove 340: lifting cylinder
350: feed pipe 400: inserter
410: a platform 411: a platform
420: elevating motor 421: elevating shaft
430: ascending / descending member 440: inserter motor
450: Inserter base 451: Cover
452: cover motor 453: sample space
454: Pisces receiver

Claims (10)

A heating block having a plurality of heating grooves for melting and melting a sample on one side;
A plurality of cooling grooves formed at positions corresponding to the heating grooves of the heating block so as to be closely contacted with or separated from the heating block and to receive and melt the molten samples in the heating grooves to produce the test pieces Cooling block;
An inserter for drawing the sample into the heating groove and entering a space between the heating block and the cooling block to receive a specimen drawn out from the cooling groove of the cooling block; And
And a reversing motor which rotates the heating block and the cooling block integrally and inverts them in the vertical direction.
The method according to claim 1,
A frame supporting the heating block and the cooling block, and a lifting cylinder installed to connect the frame and the cooling block to lift the cooling block,
Wherein the inverting motor is connected to the frame, and rotates the frame so as to vertically invert the frame.
The method of claim 2,
And an ejector pipe protruding from a plane of each of the cooling grooves to separate the sample from the cooling groove and draw the separated sample, and to eject the separated liquid into the cooling groove.
The method of claim 3,
An ejector cylinder fixed to the frame, and a hose for supplying a separate liquid to the ejector pipe,
Wherein the ejector cylinder is connected to the ejector pipe to move the ejector pipe up and down,
Wherein the cooling block is formed with an operation space in which the ejector pipe can be inserted and elevated.
The method of claim 4,
The ejector pipe is provided with a space through which the separation liquid can flow,
An ejector cover which is inserted into the ejector pipe and opens and closes the end of the ejector pipe; and an ejector cover provided inside the ejector pipe, the ejector cover being inserted into the ejector pipe And a second spring installed to surround the ejector pipe and pressing the ejector pipe in a direction opposite to the direction in which the ejector pipe projects into the cooling groove,
Wherein the ejector cover protrudes from the ejector pipe to eject the separation liquid to the inner surface of the cooling groove when the separation liquid is supplied to the ejector pipe,
And the ejector pipe protrudes from the cooling groove when the ejector cylinder is extended.
The method of claim 5,
Wherein the ejector cover is formed in an H shape and one end thereof closes the end of the ejector pipe and the first spring is inserted into the central portion thereof to press the other end inner side surface in the direction of the ejector pipe A specimen manufacturing apparatus.
The method of claim 2,
The inserter includes an inserter base which enters between the heating block and the cooling block and has a concave sample space formed on one surface thereof and a specimen-receiving groove formed on the other surface thereof; a cover motor installed at one side of the inserter base; And a cover rotatably connected to the cover rotating shaft to integrally rotate with the cover rotating shaft so as to open and close the sample space, and an inserter connected to the inserter base for inverting the inserter base up and down Comprising a motor,
Wherein when the cover is opened and the sample loaded in the sample space is loaded on the heating groove, the specimen drawn out from the cooling groove falls into the specimen holder groove.
The method of claim 7,
The inserter motor is mounted on a platform,
The elevator shaft includes an elevating body connected to the inserter motor, an elevating shaft rotated vertically through the elevating body, and an elevating motor coupled to an end of the elevating shaft to rotate the elevating shaft,
Further comprising: a platform bar cylinder for horizontally moving the platform.
The method of claim 2,
A pair of columns supporting the frame, and a moving plate for supporting the column,
Wherein the reversing motor is connected to one of a pair of rotation shafts protruding from both ends of the frame and inserted into the column.
The method of claim 9,
Further comprising: a base supporting the moving plate, the moving plate being movable on the base; and a moving plate cylinder installed on the base for horizontally moving the moving plate.

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