KR20200058337A - Sediment particle separator with sample-loss prevention structure - Google Patents

Abstract

Disclosed is a sediment particle separation device having a sample-loss prevention structure. According to the present invention, the particle separation device having a sample-loss prevention structure is for separating particles of a sediment sample by size, and comprises: a strainer securing member which has an inlet formed at an upper end thereof and an outlet formed at a lower end thereof, the outlet being narrower than the inlet, and is installed by penetrating a first plate provided in an upper part of a frame; a standard strainer placed on the upper part of the strainer securing member; and a placement unit which is installed on a second plate provided in an lower part of the frame so as to be situated directly underneath the strainer securing member, and on which a receiving member for receiving sediment matter separated by the standard strainer is placed, wherein particles filtered by passing the sampled sediments through the standard strainer are discharged to the receiving member. According to the present invention, the sediment particle separation device provided herein has a simple structure that did not exist previously, and can be used to easily separate sediment particles while preventing sample loss.

Description

SEDIMENT PARTICLE SEPARATOR WITH SAMPLE-LOSS PREVENTION STRUCTURE}

The present invention relates to an apparatus for separating sediment particles having a structure for preventing sample loss, and more specifically, to a simple structure for passing sediments collected to separate particles of sediment samples by size through a standard body seated on a sieve fixing member. The present invention relates to a sediment particle separating device having a structure for preventing a loss of a sample that prevents the loss of a sediment sample and can be easily filtered by a beaker.

In general, the particle size can be expressed by the scale of the smallest sieve through which the particle can pass, or by the diameter of a sphere having a sedimentation rate equal to the sedimentation rate of the particle, or by the long axis of the particle.

On the other hand, when obtaining the size of a fine particle that cannot directly measure the size of the particle, the particle size can be determined by separating the particles by a certain size and then using the distribution ratio of sediment particles for each size to obtain the particle size. .

Of course, the principle of measuring particle size depends on the particle size. The size of the particles can be largely divided into gravel (particle diameter 2 mm or more), sand (particle diameter 1/16 mm or more), and 뻘 (particle diameter 1/16 mm or less). Sediment particles having a size larger than gravel are measured using a vernier caliper to measure their long axis and short axis, and sand-sized particles are separated into dry sieves and sand and wet sieves.

That is, in order to separate particles of sediment (particularly seabed sediment) having a size equal to or smaller than the size of sand, particles of the particles according to the interval of each sieve are used using a standard sieve in which the eyes of the network are standardized by the recommendations of the International Organization for Standardization. The average particle size of the particles can be calculated by measuring the weight.

In this regard, the Republic of Korea Patent Registration No. 1849627 (announcement date: April 20, 2018) discloses an automatic sieving machine for sediment samples. The mechanism has a predetermined shape and size, and the upper portion is opened, and the inside is empty, and is housed in a state accommodated in the interior space of the body, and horizontally reciprocates horizontally. It consists of a vertical vibrating unit located above the horizontal vibrating unit vertically reciprocating in one state.

Since such an apparatus can vibrate by shaking the sieve containing the sample up, down, left, and right, it was possible to separate sediment samples by particle size.

However, this structure, there is a problem that the sample may be lost out of the body when vibrating, there is a problem that occurs when separating the particles by a certain size and measuring the mass to determine the size of the particle by the distribution ratio of sediment particles.

Republic of Korea Registered Patent Publication No. 1849627 (Notice: 2018.04.20.)

An object of the present invention is to provide a means for easily separating particles of a sediment sample by size without loss.

In addition, the problems to be solved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly understood by those skilled in the art from the following description. Will be understandable.

The object, according to the present invention, for separating the particles of the sediment sample by size, a narrower outlet than the inlet at the top is formed at the lower end and is installed through the first plate provided at the top of the frame through a sieve fixing member; A standard body seated on top of the body fixing member; And a seating portion installed on a second plate provided at a lower portion of the frame so as to be located under the sieve fixing member and seating a receiving member for receiving sediments separated by the standard body, wherein the collected sediments are It is achieved by a sediment particle separation device having a sample loss prevention structure, characterized in that the filtered particles are passed through the standard body to be discharged to the receiving member.

The seating portion may be provided with a sensing member for sensing the receiving member to be seated.

The sensing member may include a weight sensor, a limit switch, or an optical sensor for sensing the weight of the receiving member.

The outlet may be provided with opening and closing means for opening and closing the outlet based on the detection signal of the sensing member.

The opening and closing means, a stopper coupled to the shaft on one side of the outlet; And a first actuator having one end coupled to the outer surface of the sieve fixing member, and the other end coupled to the stopper, the stopper actuating to open and close the outlet, and when the sensing member senses the receiving member, A first actuator may be made to open the outlet by flipping the stopper.

The opening / closing means includes a stopper provided to open and close the discharge port by rotating or sliding in the horizontal direction at an end of the discharge port; And second and third actuators, one end of which is coupled to the outer surface of the sieve fixing member, and the other end of which is coupled to the stopper, such that the stopper moves forward, backward or rotationally to open and close the outlet. When the receiving member is sensed, the second and third actuators may be configured to open the outlet by sliding or rotating the stopper.

The opening / closing means may include a solenoid valve provided in the outlet, and the solenoid valve may be configured to open the outlet when the sensing member senses the receiving member.

The standard body or the body fixing member may be provided with a shielding film for shielding a space between the standard body and the body fixing member.

The second plate or the frame may be further provided with a first positional variable end coupled to one region of the screen to change the position of the screen.

The first position variable end, a vertical support member installed on the second plate or the frame; And one end is coupled to the screen, the other end of the ring-shaped moving body is formed so as to be coupled to the vertical support member, the horizontal support to adjust the height of the screen by fixing the mobile body with a height adjustment screw penetrating the mobile body It may be configured to include a member.

The first position variable end, a vertical support member installed on the second plate or the frame; One end is coupled to the screen, the other end is a horizontal support member coupled to the vertical support member; A pinion gear installed to mesh with the rack gear formed at the lower end of the vertical support member; And a fourth actuator operated to operate the pinion gear to change the height of the vertical support member, and the fourth actuator operates to raise or lower the vertical support member based on the detection signal of the detection member. It can be made to adjust the height.

According to the present invention, as well as providing a sediment particle separating device having a simple structure that has not existed, it is possible to easily separate particles of a sediment sample with this device, and it is possible to provide an effect of preventing the sample from being lost.

In addition, by forming a rib on the inner surface of the sieve fixing member, it is possible to provide an effect that when the standard body is fitted to the sieve fixing member, the position of the standard body is stably maintained horizontally with the bottom surface.

In addition, by forming a screen to prevent the separation space between the sieve fixing member and the standard body, when sediment before separating is poured into the standard body, it is possible to prevent contamination of the sediments already separated and the effect of sediment before separation is the destination. It is possible to provide an effect of preventing the housing member from being lost to the outside without reaching.

In addition, it is possible to provide an effect of preventing the standard body from being flowed by an unintended external force by fixing the screen to either the standard body or the body fixing member.

In addition, when the receiving member is sensed by the sensing member, the outlet of the body fixing member is opened, thereby providing an effect of preventing the sample from being discharged and lost while the receiving member is not seated on the seating portion.

1 is an exploded perspective view showing a sediment particle separation device having a sample loss prevention structure according to a first embodiment of the present invention.
FIG. 2 is a combined perspective view of a sediment particle separation device having a sample loss prevention structure shown in FIG. 1.
3A and 3B are schematic diagrams showing opening and closing means of a sediment particle separation device having a sample loss prevention structure according to a second embodiment of the present invention.
4A and 4B are schematic diagrams showing opening and closing means of a sediment particle separation device having a sample loss prevention structure according to a third embodiment of the present invention.
5 is a schematic view showing the opening and closing means of the sediment particle separation device having a sample loss prevention structure according to a fourth embodiment of the present invention.
6 (a) and 6 (b) are cross-sectional views showing a screen of a sediment particle separation device having a sample loss prevention structure according to a fifth embodiment of the present invention.
7 is a perspective view showing a sediment particle separation device having a structure for preventing sample loss according to a sixth embodiment of the present invention.
8 is a cross-sectional view showing a first position variable variable stage of a sediment particle separation device having a sample loss prevention structure according to a seventh embodiment of the present invention.
9 is a block diagram of a sediment particle separation device having a sample loss prevention structure according to an eighth embodiment of the present invention.
FIG. 10 is a cross-sectional view showing a second first positional variable stage of the sediment particle separation device having a sample loss prevention structure shown in FIG. 9.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

Among the accompanying drawings, FIG. 1 is an exploded perspective view showing a sediment particle separation device having a sample loss prevention structure according to a first embodiment of the present invention, and FIG. 2 is a sediment particle having a sample loss prevention structure shown in FIG. 1 It is a combined perspective view showing the separation device.

First, "particle separation" here is one of the basic methods of separating particles by a certain size, measuring a mass, and then obtaining a particle size of sediment using a distribution ratio of sediment particles for each size.

In addition, "sediment sample", "sediment", "sample", "particles of sediment samples", and "particles" refer to the materials used in the present invention, and may be used interchangeably.

1 to 2, the sediment particle separation device 1 having a sample loss prevention structure according to a first embodiment of the present invention is for separating the particle size of a sediment sample, and the shape of the upper light tubercle That is, the funnel-shaped sieve fixing member 100, a standard body (S) seated on top of the sieve fixing member 100, and a receiving member (B) for receiving a sediment sample separated by the standard body (S) It is configured to include a seating portion 200 that is seated. In an embodiment, the receiving member B may be a beaker, but is not limited thereto. Hereinafter, for convenience of understanding, a description will be given focusing on a beaker which is one end of the receiving member B.

This will be described in more detail.

The standard body S is a network for selecting the size of particles, and is a standardized eye of the network. Currently, as recommended by the International Organization for Standardization, the eyes of the network use almost the same value in each country.

Although the user may use a sieve made according to a desired size according to the purpose or purpose, the present invention will be described as using a standardized body S for convenience of explanation.

The sieve fixing member 100 is for collecting sediment samples separated by fixing the sieve, and a narrower outlet 120 than the inlet 140 of the upper portion is formed at the lower end and provided at the upper portion of the frame 30 It is installed through the first plate (10).

In addition, a handle may be provided on one of the upper ends of the sieve fixing member 100 to facilitate movement of the sieve fixing member 100 by gripping.

In addition, for a stable seating of the standard body (S) on the inner surface of the body fixing member 100, as shown in Figure 1, may be provided with a protruding rib 160, although not shown, cross (十) ) In the form of a skeleton, a standard body (S) may be seated thereon.

In addition, the spout on the outlet 120 side of the sieve fixing member 100 may be formed with a different slope than the spout on the inlet 140 side. In other words, the cross-sectional area of the spout toward the outlet 120 can be rapidly reduced, which is to prevent the sediment sample separated by the standard body S from being discharged to the receiving member B (hereinafter referred to as a 'beaker') in a large amount. .

The material of the sieve fixing member 100 is not particularly limited, but is preferably made of a hydrophobic material because distilled water can be used for particle separation.

In addition, as the material of the stopper 180 to be described later, sediment samples, that is, the repulsive force that pushes the molecules of the soil and the molecules of the material to each other, the soil is applied to the inner surface or the stopper 180 of the body fixing member 100. It is preferably made of a material that does not bury.

This is to reduce the error in particle size analysis by preventing any loss of the sample.

* The seating portion 200 is for seating the beaker (B) for receiving the sediment sample separated by the standard body (S), provided in the lower portion of the frame 30 to be located under the sieve fixing member 100 The second plate 20 is installed.

There is no particular limitation on the shape of the seating portion 200, but a stepped portion is formed slightly surrounding the bottom surface of the beaker B, so that the beaker B does not fall or fall even in a small flow.

In addition, by placing the beaker B on the stepped portion, the beaker B is placed at a position directly below the outlet 120.

The seating portion 200 may be formed integrally with the second plate 20.

The beaker (B) can be used with different sizes depending on the user's purpose and purpose, but is usually 500 mL.

The operation of the sediment particle separation device 1 having the structure for preventing sample loss according to the first embodiment of the present invention configured as described above will be described.

As shown in FIGS. 1 and 2, the first plate 10 and the second plate 20 in two stages are spaced apart by the frame 30.

The sieve fixing member 100 is penetrated through the through hole 15 of the first plate 10 and the beaker B is seated on the seating portion 200 of the second plate 20.

Here, the beaker (B) and the outlet 120 are disposed close to prevent particles of the sediment separating from being splashed out of the beaker (B).

Thereafter, the standard body S of a standard desired by the user is seated on the rib 160 of the sieve fixing member 100. As the ribs 160 are formed, the position of the standard body S can be stably maintained horizontally with the bottom surface when the standard body S is seated on the body fixing member 100.

If the sample of the collected sediment is carefully poured over the standard body (S), the filtered sediment sample can be obtained from the beaker (B).

On the other hand, if necessary, you can also sieve using a brush and distilled water.

Even at this time, an unintended flow may occur due to the external force, but the standard body S is stably seated on the rib 160, so that a sample of sediment due to the flow of the standard body S can be prevented from being lost. do.

As described above, if the particle size of the sediment sample is separated while the apparatus is installed, not only can the sample be separated easily and quickly, but also the loss of the sample can be prevented to reduce the error of the test result.

In addition, it is easy to install and assemble with a simple structure, and is a mechanical device that does not require electrical operation, so there is an advantage that there is no fear of circuit breakage or electrical malfunction.

Among the accompanying drawings, FIGS. 3A and 3B are schematic diagrams showing opening and closing means of a sediment particle separation device having a sample loss prevention structure according to a second embodiment of the present invention.

The sensing member 400 is provided on the bottom surface of the seating part 200, and as illustrated in FIGS. 3A and 3B, the tactics are except that the outlet 120 is opened and closed by the opening and closing means. It is the same as the first embodiment.

The sensing member 400 is for detecting the beaker B, and is provided at any one of the inner surfaces of the seating portion 200 where the beaker B and the seating portion 200 abut. It is preferably provided on the inner bottom surface of the seating portion 200 that the outer bottom surface of the beaker (B) touches.

The sensing member 400 may be made of a weight sensor for sensing the weight of the beaker B, may be made of a limit switch, or may be made of an optical sensor or an infrared sensor.

This is to interlock the opening of the opening / closing means O of the outlet 120 only when the beaker B is seated on the seating portion 200.

Opening and closing means (O) is for opening and closing the outlet 120 based on the detection signal of the sensing member 400, as shown in (a) and (b) of Figure 3, the shaft at one side of the outlet 120 It comprises a stopper 180 and a first actuator (A1) that operates to open and close the stopper 180.

One end of the first actuator A1 is coupled to the outer surface of the body fixing member 100 by the support piece 182, and the other end is coupled to the stopper 180 by the support piece 182. The first actuator A1 is axially coupled by the support piece 182, and when the sensing member 400 detects the beaker B, the stopper 180 is flipped to open the outlet 120.

In addition, each support piece 182 is coupled to the connecting piece 184 formed on the outer surface of the sieve fixing member 100 and the stopper 180, respectively.

The operation of the sediment particle separation device 1 having the structure for preventing sample loss according to the second embodiment of the present invention configured as described above will be described.

As shown in (a) of FIG. 3, when the beaker B is not yet positioned in the seating portion 200, the stopper 180 closes the outlet 120.

When the beaker B is seated and the sensing member 400 detects the beaker B, a signal is sent to the opening / closing means O through the control unit C. (See Figure 9)

Then, as shown in (b) of FIG. 3, the first actuator A1 pulls the support piece 182 connected to the stopper 180 to tilt the stopper 180 to open the outlet 120. .

As described above, when the particle size of the sediment sample is separated while the device is installed, the control unit (C) sends a signal to the opening / closing means (O) only when the detection member 400 detects the beaker (B). By opening), filtered sediment particles may remain inside the sieve fixing member 100 even if the sediment sample collected in a situation where the user is not ready for the beaker B is accidentally poured into the standard sieve S It is possible to prevent the loss of.

In addition, when separation of the collected sediment sample takes a long time, the separation is performed after closing the stopper 180, and when the separation is completed, a beaker B is seated to open the outlet 120 to obtain a separated sediment sample. It becomes possible.

Among the accompanying drawings, FIGS. 4 (a) and 4 (b) are schematic diagrams showing opening and closing means of a sediment particle separation device having a sample loss prevention structure according to a third embodiment of the present invention.

As shown in (a) and (b) of FIG. 4, the same as the second embodiment described above, except that the stopper 180 is provided with a sliding door.

The sensing member 400 is provided on the bottom surface of the seating portion 200.

Opening and closing means (O) is for opening and closing the discharge port 120 based on the detection signal of the detection member 400, sliding horizontally to the end of the discharge port 120, a stopper coupled to open and close the discharge port 120 It comprises a second actuator (A2) that operates to open and close the 180 and the stopper 180.

One end of the second actuator (A2) is coupled to the outer surface of the body fixing member (100) toward the outlet (120) so that the guide portion (186) can linearly move in line with the stopper (180), and the other end is supported It is coupled to the stopper 180 by a piece (182).

Here, the guide portion 186 may be formed of a bracket.

When the sensing member 400 detects the beaker B, as shown in FIG. 4 (b), the second actuator A2 pulls the stopper 180 so that the stopper 180 slides. The 120 can be opened.

As described above, when separating the particle size of the sediment sample in a state in which the device is installed, the stopper 180 has a sliding structure, so that the top of the outlet 120 and the beaker B can be located close to each other, thereby separating the sediment. When the sample is discharged to the beaker (B), it can be prevented from being lost outside the beaker (B).

Among the accompanying drawings, FIG. 5 is a schematic view showing opening and closing means of a sediment particle separation device having a sample loss prevention structure according to a fourth embodiment of the present invention.

As shown in FIG. 5, the same as the second embodiment described above, except that the stopper 180 is opened and closed by the third actuator A3.

The sensing member 400 is provided on the bottom surface of the seating portion 200.

Opening and closing means (O) is for opening and closing the discharge port 120 based on the detection signal of the detection member 400, and rotates in the horizontal direction at the end of the discharge port 120, a stopper coupled to open and close the discharge port 120 It comprises a third actuator (A3) that operates to open and close the 180 and the stopper 180.

The third actuator A3 is installed on one side of the body fixing member 100 and is configured to drive the stopper 180.

Although not shown, a bracket for covering and guiding the third actuator A3 may be provided.

When the sensing member 400 detects the beaker B, as illustrated in FIG. 5, the third actuator A3 rotates the stopper 180 in the horizontal direction to open the outlet 120.

As described above, when separating the particle size of the sediment sample while the device is installed, the stopper 180 has a structure that rotates in the horizontal direction, so that the outlet 120 and the top of the beaker B may be located closer. There is, it is possible to prevent the sediment sample is lost to the outside of the beaker (B) when discharged to the beaker (B), the third actuator (A3) does not need to be installed in the horizontal direction, easy installation and installation space It has the advantage of not having to take up a lot.

On the other hand, although not shown, the opening and closing means (O), may be made of a solenoid valve (magnetic valve), that is provided in the outlet 120, that is, a solenoid valve (solenoid valve). When the sensing member 400 detects the beaker B, the solenoid valve opens the outlet 120.

Among the accompanying drawings, FIGS. 6 (a) and 6 (b) are cross-sectional views showing a screen of a sediment particle separation device having a sample loss prevention structure according to a fifth embodiment of the present invention.

As shown in (a) and (b) of FIG. 6, the same as the above-described embodiments, except that the shielding film 300 is additionally provided.

The shielding film 300 is for shielding the separation space D between the standard body S and the body fixing member 100, and the fastening part 340 fastened to the upper end of the standard body S or the body fixing member 100 ) And the wing part 320 covering the space D.

As shown in Figure 6 (a), the fastening portion 340 is fitted along the upper end of the standard body (S), the wing portion 320 shields the separation space (D) of the body fixing member 100 It can be over the outer surface, as shown in Figure 6 (b), the fastening portion 340 is fitted along the upper end of the sieve fixing member 100, the wing portion 320 is spaced apart (D) By shielding it may be over the inner surface of the standard body (S).

On the other hand, as represented by the dotted line in Fig. 6 (a), when the wing portion 320 of the screen 300 is turned over by an external force, it is changed into a concave shape, which is the sample remaining in the standard body (S) after sediment sample separation. It is to put in another container. That is, in a state in which the blanking film 300 is coupled to the upper end of the standard body S, the wing portion 320 of the blanking film 300 is changed into a concave shape, so that sediment samples remaining in the standard body S can be easily contained in other containers. It becomes possible. The shielding film 300 may be made of a flexible material such as rubber or silicone to achieve this.

As described above, when separating the particle size of the sediment sample in the state where the device is installed, a separating layer 300 is formed by blocking the separation space D between the sieve fixing member 100 and the standard body S, thereby separating the sediment before separation. When it is poured into the standard body (S), it enters the separation space (D) and prevents contamination of the already separated sample, that is, it is possible to prevent the sediment sample from being lost outside without reaching the beaker (B) before separation. do.

In addition, the screen 300 is fastened to either the standard body (S) or the body fixing member 100, thereby preventing the standard body (S) from being flowed by an unintended external force, and primarily the rib (160). By the standard body (S) is seated, it is possible to prevent the flow of the standard body (S) by the secondary cover 300.

Among the attached drawings, FIG. 7 is a perspective view showing a sediment particle separation device having a sample loss prevention structure according to a sixth embodiment of the present invention.

As shown in FIG. 7, it is the same as the fifth embodiment described above, except that the first position variable variable stage M1 for adjusting the position of the screen 300 is provided.

The first position variable end (M1) is coupled to a region of the screen 300 to vary the position of the screen 300, and includes a vertical support member 12 and a horizontal support member 14.

The vertical support member 12, which acts as a skeleton to move the horizontal support member 14 up and down, is installed on the second plate 20 or the frame 30 and is made of a rod shape.

The shape of the cross section of the vertical support member 12 is not particularly limited, and in this embodiment, it will be described as consisting of circles.

The horizontal support member 14 is such that the blanking film 300 is directly above the standard body S, and one end is coupled to one point of the blanking film 300. The coupling may be a coupling force sufficient to withstand the weight of the masking film 300, and it is preferable that the fitting is coupled so as to correspond to a hole formed in the masking film 300 or a protruding protrusion.

At the other end of the horizontal support member 14, a ring-shaped moving body 16 is formed so as to penetrate through the vertical support member 12. The height of the horizontal support member 14 can be adjusted by fixing the moving body 16 with a height adjusting screw 18 penetrating the moving body 16. That is, it is possible to manually change the position of the blanking film 300 coupled to the horizontal support member 14.

The operation of the first positional variable stage M1 of the sediment particle separation device 1 having the structure for preventing sample loss according to the sixth embodiment of the present invention configured as described above will be described.

As shown in FIG. 7, the shielding film 300 is positioned directly above the standard body S.

One end of the horizontal support member 14 is forcibly fitted to one point of the screen 300, and the other end is reciprocated in the longitudinal direction of the vertical support member 12 by the moving body 16.

After the screen 300 is fastened to the top of the standard body (S) or the body fixing member 100, the height adjustment screw 18 is tightened so that the horizontal support member 14 is fixed to the vertical support member 12 without flow. .

If the sample of the collected sediment is carefully poured over the standard body (S), the filtered sediment sample can be obtained from the beaker (B).

As described above, when separating the particle size of the sediment sample while the device is installed, the screen 300 and the first positional variable stage (blocking the separation space D) between the sieve fixing member 100 and the standard body S By configuring M1), when sediment samples before separation are poured into the standard body (S), they enter the separation space (D) and prevent contamination of samples that have already been separated, that is, sediments before separation do not reach the destination and are lost to the outside. Can be prevented.

In addition, the screen 300 is fastened to either the standard body (S) or the body fixing member 100, thereby preventing the standard body (S) from being flowed by an unintended external force, and primarily the rib (160). The standard body (S) is seated by, and secondly, the flow of the standard body (S) is prevented by the shielding film (300), and the masking film (300) is fixed by the first position variable variable stage (M1). ) Can be prevented.

In addition, there is a fear of loss of the cover film 300 by additionally provided with the cover film 300, the loss is prevented by being fixed by the vertical support member 12 and the horizontal support member (14).

In the accompanying drawings, FIG. 8 is a cross-sectional view showing a first positional variable stage of a sediment particle separation device having a sample loss prevention structure according to a seventh embodiment of the present invention.

As shown in FIG. 8, except that the fourth actuator A4 for operating the vertical support member 12 of the first position variable variable M1 up and down for adjusting the position of the screen 300 is provided. It is the same as the sixth embodiment described above.

The first position variable end (M1) is coupled to a region of the screen 300 to vary the position of the screen 300, the vertical support member 12, the horizontal support member 14, and the fourth actuator ( A4).

The horizontal support member 14 is fixed at the upper end of the vertical support member 12, and a rack gear R is installed at the lower end.

A pinion gear P is installed on the upper or lower surface of the first plate 10 so as to mesh with the rack gear R, and a fourth actuator A4 for operating the pinion gear P is provided. do. That is, the height of the vertical support member 12 can be varied by operating the fourth actuator A4.

In addition, a housing 40 surrounding the fourth actuator A4 is provided. This is to prevent an inoperable state due to external force including particles of dust or flying sediments.

In addition, although not shown, a bracket for covering and guiding the rack gear R and the fourth actuator A4 may be provided.

The operation of the first positional variable stage M1 of the sediment particle separation device 1 having the structure for preventing sample loss according to the seventh embodiment of the present invention configured as described above will be described.

When the beaker B is seated and the sensing member 400 detects the beaker B, a signal is sent to the opening / closing means O and the first position variable end M1 through the control unit C. (See Figure 9)

Then, as shown in Figure 8, the fourth actuator (A4) operates the pinion gear (P), the vertical support member 12 is designated position, that is, the shielding film 300 is fixed to the standard body (S) or sieve It is variable to fit on the member 100.

As described above, when the particle size of the sediment sample is separated while the device is installed, the sensing member 400 detects the beaker B, so that the control unit C opens and closes the means O and the first position variable stage M1. By sending a signal to) to open the outlet 120 and the shielding film 300 is installed, it is possible to reduce the user's copper wire and at the same time obtain all of the above-described effects.

In the accompanying drawings, FIG. 9 is a block diagram of a sediment particle separation device having a sample loss prevention structure according to an eighth embodiment of the present invention, and FIG. 10 is a sediment particle separation device having a sample loss prevention structure shown in FIG. 9 It is a sectional view showing the second position variable end of the.

9 and 10, it is the same as the seventh embodiment described above, except that a second position variable end M2 for changing the position of the beaker B is additionally provided.

The second position variable end (M2), as shown in Figure 10, is configured to include a vertical support member 12 and a fifth actuator (A5).

The seating part 200 is fixed to the upper part of the vertical support member 12, and a rack gear R is installed to the lower part.

A pinion gear is installed on the upper or lower surface of the second plate 20 to mesh with the rack gear R, and a fifth actuator A5 for operating the pinion gear P is provided. That is, the height of the vertical support member 12 can be varied by operating the fifth actuator A5. This is to prevent the sample buried in the water droplets from being splashed when the distilled water is used because the outlet 120 is positioned to interfere inside the beaker B.

In addition, a housing 40 surrounding the fifth actuator A5 is provided.

Further, although not shown, a bracket for covering and guiding the rack gear R and the fifth actuator A5 may be provided.

The operation of the second position variable stage M2 of the sediment particle separation device 1 having the structure for preventing sample loss according to the eighth embodiment of the present invention configured as described above will be described.

As shown in FIG. 9, when the beaker B is seated and the sensing member 400 detects the beaker B, the opening / closing means O through the control unit C, the first position variable variable stage M1, And the second position is to send a signal to the variable end (M2).

Then, as described above, the shielding film 300 is shielded from the separation space D by the first position variable end M1, and the stopper 180 is opened by the opening / closing means O to open the outlet 120. , As illustrated by the dashed-dotted line in FIG. 10, the outlet 120 is positioned inside the upper end of the beaker B by the second position variable end M2.

As described above, when the beaker B is raised and the outlet 120 is positioned in the beaker B, loss due to the 튐 of the sample to be discharged is prevented.

As described above, when the particle size of the sediment sample is separated while the device is installed, the sensing member 400 detects the beaker B, so that the control unit C opens and closes the means O and the first and second position variable stages. By sending a signal to (M1, M2) to open the outlet 120, the shielding film 300 is installed, and when the outlet 120 is positioned to interfere inside the beaker B, it reduces the user's experimental flow and reduces the loss of the sample. Not only can it be prevented more reliably, but all the above-described effects can be obtained.

In particular, the sediment particle separation device 1 having a structure for preventing sample loss according to the present invention has the technical characteristics described in the present invention, and of course, may have various shapes, shapes, and standards.

* In the foregoing, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and various modifications and modifications can be made without departing from the spirit and scope of the present invention. It is obvious to those who have knowledge. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should belong to the claims of the present invention.

1: sediment particle separation device having a structure for preventing sample loss
10: first plate 12: vertical support member
14: horizontal support member 15: through hole
16: movable body 18: height adjustment screw
20: second plate 30: frame
40: housing
100: sieve fixing member
120: outlet 140: inlet
160: rib 180: stopper
182: support piece 184: connecting piece
186: guide section
200: seating portion
300: screen
320: wing 340: fastening
400: detection member
A1: 1st actuator A2: 2nd actuator
A3: Third actuator A4: Fourth actuator
A5: 5th actuator B: Receiving member
C: Control unit D: Separation space
M1: 1st variable position M2: 2nd variable position
O: Switching means P: Pinion gear
R: Rack gear S: Standard body

Claims (3)

To separate the particles of the sediment sample by size,
A sieve fixing member having a narrower outlet than the upper inlet and formed through the first plate provided at the upper portion of the frame;
A standard body seated on top of the body fixing member; And
It is installed on a second plate provided on the lower portion of the frame so as to be located under the sieve fixing member includes a seating portion for receiving the receiving member for receiving sediment separated by the standard body,
In the seating portion,
A sensing member for sensing the receiving member to be seated is provided,
In the outlet,
Opening and closing means for opening and closing the outlet on the basis of the detection signal of the detection member is provided,
The opening and closing means,
It consists of a solenoid valve provided in the outlet,
When the sensing member detects the receiving member, the solenoid valve opens the outlet,
The standard body or the sieve fixing member,
A shielding film for shielding the space between the standard body and the body fixing member is installed,
On the second plate or the frame,
A first position variable variable stage is further provided to be coupled to one region of the screen and to change the position of the screen.
The first position variable end,
A vertical support member installed on the second plate or the frame;
One end is coupled to the screen, the other end is a horizontal support member coupled to the vertical support member;
A pinion gear installed to mesh with the rack gear formed at the lower end of the vertical support member; And
And a fourth actuator operated to change the height of the vertical support member by operating the pinion gear,
The fourth actuator is operated based on the detection signal of the sensing member to adjust the height by raising or lowering the vertical support member,
Characterized in that the collected sediments are passed through the standard body so that filtered particles are discharged to the receiving member,
A sediment particle separation device having a structure for preventing sample loss. According to claim 1,
The sensing member,
Characterized in that consisting of a weight sensor, a limit switch, or an optical sensor for sensing the weight of the receiving member,
A sediment particle separation device having a structure for preventing sample loss. According to claim 1,
The first position variable end,
A vertical support member installed on the second plate or the frame; And
One end is coupled to the screen, and the other end is formed with a ring-shaped moving body to be coupled to the vertical support member, a horizontal support member adapted to adjust the height of the screen by fixing the moving body with a height adjustment screw penetrating the moving body Characterized in that comprises a,
A sediment particle separation device having a structure for preventing sample loss.

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