KR101761343B1 - System that calibrate the device for measuring the sediment - Google Patents

Abstract

A sword correction system for a sub-pseudo measurement device is disclosed. The present invention provides a sword correction system for a sub-pseudo-similar measuring apparatus, comprising: a cylindrical chamber having a receiving space into which a solvent and a suspended syringe are inserted; A measuring device carrier lifting up and down in the receiving space by a winch in a state in which at least one sub-similar measuring device is mounted; A stirring blade installed at a lower end of the containing space to perform a rotating operation so that the solvent and the suspended sol are mixed with each other to form a uniform suspension without bubbles; A circulation operating portion communicating with the accommodating space at an upper end portion of the chamber and the bottom plate side to circulate the sub-pellets with the solvent; And a control unit for controlling the rotation of the stirring vane and the circulation operation unit to control the uniformity of the suspension in the accommodation space, And a control unit for controlling the display unit. According to the present invention, since the sword correction system of the sub-pseudo-similarity measuring apparatus can be installed and operated indoors, the sub-pseudo-similarity measuring apparatus can be quickly corrected without any process such as actual operation of the observation area and sampling of the sample And it is possible to provide a sword correction system of a sub-pseudo-measurement apparatus which can improve the convenience of the operator because no problem is caused by the loss of the sample.

Description

[0001] The present invention relates to a system for calibrating a sub-

The present invention relates to a sword correction system for a sub-pseudo-similar measuring apparatus, and more particularly, to a sword correction system for a sub-pseudo-similar measuring apparatus in which various types of sub- And more particularly, to a sword correction system for a sub-pseudo-measurement device.

Floats are the term collectively referred to as earths that float in water or float in the river or coast and float out from the bottom by water. Information on the particle size, distribution, or volume concentration of these suspended solids is basic information in characterizing the behavior of erosion and sedimentation environments in rivers and coastal areas, and furthermore, The big data obtained can be used as important information for predicting topographic changes in rivers and coastal areas.

In order to measure the sub-similarity in moving in the water, Aquadopp Profiler (Side looking), Aquadopp Profiler (500khz), Vector 3d Acoustic Velocimeter (Fixed Stem Standard), PC-ADP (Pulse-Coherent ADP) System), Sequoia (LISST-100X), etc. have been already commercialized.

However, it is necessary to verify before use or periodically and to calibrate (check correction work) whether these measuring devices accurately provide information on the particle size, distribution or concentration per volume of suspended particles, This is usually done in order to ensure accuracy in the characterization of the behavior of erosion and sedimentation environments in rivers and coastal areas.

The conventional method of correcting the sub-pseudo-similar measuring apparatus is two methods. First, the first method is to measure the information about the sub-similarity (information on the particle size, the distribution, or the concentration per volume) in the river water or seawater of the observation area using a measuring device, In the laboratory, post-treatment (extraction of suspended solids and calculation of information on particle size and distribution based on them), and calibration of the measuring device by mutual comparison with the measured information (adjustment of the parameters of the measuring device according to the information calculated in the laboratory) .

In the second method, a certain amount of suspended solids contained in the solvent (water) is uniformly distributed in the chamber by using a rotating impeller and a pump circulation system mounted in a cylindrical chamber, and then, After the information is measured, the measured information is compared with the information of the solvent introduced into the chamber and the information based on a certain amount of sub-similarity, thereby performing the calibration of the measuring apparatus.

In the first method of the conventional method of correcting the sword, it takes a lot of time to correct the sword because it requires several steps such as sampling, movement, and laboratory experiment. In this process, the sample is lost There is a problem that appropriate measures or actions are difficult to be made.

In the second method, since a certain kind of sub-pseudo-similar measuring device is mounted and fixed to one side of the chamber, it is difficult to apply the same to other kinds of sub-pseudo-measuring devices immediately, There is a problem in that accurate calibration can not be performed due to the fact that a portion of the pseudo-similar portion is not re-suspended upward and is deposited.

Therefore, a structural improvement and improvement are needed to solve the above-mentioned problems inherent in the conventional automatic correction method.

An object of the present invention is to provide a sub-pseudo-similar measuring apparatus, which can basically perform a quick check correction operation of a sub-pseudo measurement apparatus without any sampling process or the like, The present invention also provides a sword correction system for a sub-pseudo measurement apparatus capable of maintaining the state in which the suspended solids included in the solvent in the chamber are uniformly distributed without being deposited on the floor.

The object of the present invention is achieved by a method of manufacturing a semiconductor device, comprising: a cylindrical chamber having a housing space into which a solvent and a floating oil are introduced; A measuring device carrier lifting up and down in the receiving space by a winch in a state in which at least one sub-similar measuring device is mounted; A stirring blade installed at a lower end of the containing space to perform a rotating operation so that the solvent and the suspended sol are mixed with each other to form a uniform suspension without bubbles; A circulation operating portion communicating with the accommodating space at an upper end portion of the chamber and the bottom plate side to circulate the sub-pellets with the solvent; And a control unit for controlling the rotation of the stirring vane and the circulation operation unit so as to control the rotation of the stirring vane and the rotation of the suspension in the accommodation space, And a control unit for adjusting the uniformity of the measurement result.

The circulation operation unit includes a circulation pump provided at an outer side of the chamber and controlled by the control unit; A first circulation pipe provided between the circulation pump and the upper end of the chamber and communicating with the accommodation space; and a second pipeline provided between the circulation pump and the bottom plate and communicating with the accommodation space; And a jet nozzle unit provided between the stirring vane and the bottom plate to prevent the floating oil from being deposited on the bottom plate.

Wherein the injection nozzle unit comprises: an injection pump provided at an outer side of the chamber and controlled by the control unit; A ring-shaped nozzle body provided between the stirring blade and the bottom plate in a state in which one end portion is in communication with the injection pump, the ring-shaped nozzle body having a plurality of spray nozzles directed toward the bottom plate; And an injection pipe provided between the injection pump and the chamber and communicating with the accommodation space.

The chamber may be provided with a plurality of intake valves spaced apart from each other in the longitudinal direction of the chamber so as to allow the suspension to be taken out by the height of the chamber.

Wherein the bottom plate is provided with a rounded machining surface in a concave shape along the inner edge of the bottom plate so as to reduce the accumulation of suspended solids in the inner edge region of the bottom plate, The bottom plate, and the inner circumferential surface of the chamber.

The stirring vane may include a motor provided at an outer side of the chamber to provide a rotational force under the control of the controller. At least one impeller which receives a rotational force of the motor and generates a thrust force at an upper end of the accommodating space; And a turbulence generating grid plate positioned above the impeller to receive the rotational force of the motor and generate turbulence in the suspension according to the rotation to reduce bubbles in the suspension.

Wherein the measuring device carrier is configured such that at least one or more sub-pseudo-similar measuring devices are formed to be vertically elongated, and the upper end portion is connected to the winch and the wire to vertically move up and down; And a plurality of guide rings spaced vertically from one side of the inner circumferential surface of the chamber, the guide rings having a ring shape through which the mounting frame passes and guiding vertical movement of the mounting frame.

The mounting frame is provided with at least one guide protrusion protruding from the outer circumferential surface of the mounting frame and elongated along the longitudinal direction of the mounting frame. The guide ring is provided with guide protrusions A guide groove recessed from the inner circumferential surface can be formed.

Wherein the guide groove is further provided with a pressing means for pressing the guide projection so that the mounting frame can be firmly held in a state of being fitted to the guide ring, And a fixed ball elastically supported by the elastic body in the center direction of the guide ring.

The inner circumferential surface of the guide ring is further provided with a pressing means for pressing the mounting frame so that the mounting frame can be firmly held in a state of being fitted to the guide ring, And a plate spring partly protruding from the guide ring in the center direction of the guide ring.

The inner circumferential surface of the guide ring is further provided with a pressing means for pressing the mounting frame so that the mounting frame can be firmly held in a state of being fitted to the guide ring, And a fixed ball which is elastically supported in the center direction of the guide ring by the elastic body in the accommodated state.

According to the present invention, since the sword correction system of the sub-pseudo-similarity measuring apparatus can be installed and operated indoors, the sub-pseudo-similarity measuring apparatus can be quickly corrected without any process such as actual operation of the observation area and sampling of the sample And it is possible to provide a sword correction system of a sub-pseudo-measurement apparatus which can improve the convenience of the operator because no problem is caused by the loss of the sample.

(Output voltage (V) or reflected acoustic intensity (dB)) calculated by the sub-pseudo-measurement apparatus is used as information about sub-similarity (information such as particle size or distribution or concentration per volume (mg / L) A relational expression that can be converted can be easily obtained and it is possible to use various kinds of sub-pseudo-similar measuring apparatuses as well as general sub-pseudo-measuring apparatuses Of the present invention.

In addition, through the operation of the stirring wing and the circulating operation portion provided at the lower end of the chamber, the floating oil contained in the solvent in the chamber can be kept uniformly distributed without being deposited on the floor, It is possible to provide a sword correction system of a sub-pseudo-measurement device that can be improved.

1 is a perspective view of a sword correcting system of a sub-pseudo-similar measuring apparatus according to an embodiment of the present invention.
Fig. 2 is a plan view, a bottom view, and a front view of the ring-shaped nozzle body shown in Fig. 1;
FIG. 3 is a view showing an embodiment and a modification of the structure and the shape of the bottom plate and the injection nozzle shown in FIG. 1, respectively.
Fig. 4 is a view for showing the operating state of the measuring apparatus carrier of Fig. 1; Fig.
Fig. 5 is a view showing a modification of the structure or form of the measuring apparatus carrier shown in Fig. 1. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

2 is a plan view, a bottom view, and a front view of the ring-shaped nozzle body shown in FIG. 1, and FIG. 3 is a cross-sectional view of the ring-shaped nozzle body shown in FIG. 1 FIG. 4 is a view for showing the operation state of the check correction system shown in FIG. 1, and FIGS. 5A to 5C are diagrams for explaining the structure and the form of the bottom plate and the injection nozzle, 1 is a view showing a modification of the structure or form of the measuring apparatus carrier shown in Fig.

(Upper, lower, left, right, front, rear, and the like), which designate directions in the description of the invention and the claims, And each direction described below is based on this, unless otherwise specifically limited.

The gage correction system 100 of the sub-pseudo-similarity measuring apparatus according to the present invention is characterized in that the measured value (the output voltage V or the reflected acoustic intensity dB) (Information such as particle size, distribution, or concentration per volume (mg / L)) of the sample, and it is possible to easily obtain a relational expression that can be converted into a sub- (Check correcting operation) of the sub-pseudo-similar measuring apparatus 10 is performed, and the general application of the various kinds of sub-pseudo-similar measuring apparatus 10 is enabled.

Herein, the sub-similarity (S) is a term collectively referred to as background art, which is a term collectively referred to as a soil which is floated from the bottom due to the flow of water or waves in a river or a coast, and is moved in water.

The check correction operation is a process in which the measuring apparatuses 10 obtain information (measured value: output voltage V, reflected acoustic intensity (dB)) related to the particle size, distribution, (Mg / L) of the particle size or distribution or the volume per volume (S) of the measured sub-pseudo (S)) is accurately provided, and the parameter or the relational expression of the sub- Adjustment or correction.

For reference, there is a post-scatter scattering turbometer (OBS) as a measuring device 10 that provides a measure of the concentration of sub-pseudo-S in the form of an output voltage V, (S), such as VECTOR, AQUADOPP, PC-ADP or ABS. The measurement value provided in the form of the output voltage V or the reflected acoustic intensity dB is required to derive a relational expression for converting into the negative similarity S concentration, .

In addition, LISST-100X (Sequoia) is a measuring device 10 that directly provides information such as particle size, distribution, or concentration per volume (mg / L) of sub-similarity (S). The apparatus can be used to correct the measuring apparatuses other than those described above, and it can also be verified whether the correct measurement values are presented through the sine correction system 100 according to the present invention.

The gauge correction system 100 of the sub-pseudo-measurement apparatus according to the present invention includes a chamber 110, a measurement device carrier 120, a stirring wing 130, a circulation operation unit 140, a control unit 150, . Hereinafter, each of the above-described configurations will be described in detail with reference to the drawings.

The chamber 110 is a cylindrical component having a housing space 110a into which the solvent W and the subsidiary similarity S are introduced. The chamber 110 has a bottom plate 112 coupled to the bottom thereof, 111) are combined. In the present invention, the solvent (W) in the present invention mainly becomes fresh water or salt water, and the sludge-like (S) Refers to earth and sand that floats in the river or coast and moves in water. On the other hand, a solution in which the solvent S is mixed and mixed with the solvent W is defined as a suspension (SUS).

The chamber 110 according to the embodiment of the present invention is made of transparent acrylic synthetic resin so that the uniformity S of the sub-similarity S is uniformly distributed in the solvent W placed in the internal accommodation space 110a from the outside It is manufactured to have a height of about 1500 mm, a diameter of 500 mm and a thickness of 10 t. In this case, the size of the chamber 110 may be increased or decreased as needed.

A plurality of intake valves 114 are formed on the outer circumferential surface of the chamber 110 so as to be spaced apart from each other along the longitudinal direction of the chamber 110. This allows a suspension SUS sample to be taken out by the height of the chamber 110 .

The intake valve 114 is configured to allow the suspension SUS contained in the accommodation space 110a having various heights to be sampled as samples so that the suspension S It is possible to accurately acquire information on the post-processing. Here, the post-acquisition is a process in which a sampled suspension (SUS) sample is subjected to a post-treatment in the laboratory, that is, by filtering out only the like (S) from the suspension (SUS) or evaporating only the solvent (W) S), the particle size, the distribution, the concentration, and the like.

The information about the sub-similarity (S) physically or mechanically post-processed in the laboratory can be obtained by measuring the measured value of the measuring device 10 measured at the height at which the suspension (SUS) (V), the reflected sound intensity (dB), or the information of the particle size or distribution or the concentration per volume (mg / L) of the measured sub-pseudo (S) (in the case of measured values in the form of particle size or distribution or volume per volume (mg / L) of measured sub-similarity (S)], I will work.

It is needless to say that the plurality of intake valves 114 are electrically connected to the control unit 150 to be described later so that suspensions (SUS) samples can be controlled to be drawn out by the required amount for each height. Further, the control of the specific intake valve 114 will be described in connection with the control unit 150, which will be described later.

The measuring apparatus carrier 120 is a component which is vertically moved up and down in the receiving space 110a by the winch 121 in a state where at least one sub-similarity measuring apparatus 10 is mounted, The measuring device 10 is mounted in a row in the upper and lower rows. At this time, various attaching means such as a Velcro or an adhesive tape may be used.

The measuring device carrier 120 can be moved upward and downward by being connected to the winch 121 provided on the outer side of the measuring device 10 to facilitate the replacement or detachment of the measuring device 10, The statistical accumulation of the measurement values becomes possible in a manner in which the sensor 10 is operated a plurality of times.

This statistically accumulated measurement is a process of intercomparison with the acquired sub-similarity (S) information, which is post-processed and post-processed from the suspension (SUS) sample taken via the intake valve 114 at a height corresponding to the measured value (When the output voltage (V) and the reflected acoustic intensity (dB) are measured) can be more easily obtained, or the correction operation can be performed more reliably.

1 and 4, the measuring device carrier 120 according to the embodiment of the present invention includes a mounting frame 122 and a guide ring 124. The mounting frame 122 is vertically So that at least one or more sub-pseudo-similar measuring apparatuses 10 are mounted, and the upper end is connected to the winch 121 and the wire 121a to move up and down.

The guide ring 124 is formed in a ring shape through which the mounting frame 122 passes, and a plurality of the guide rings 124 are vertically spaced apart from one side of the inner circumferential surface of the chamber 110. The guide ring 124 stably guards the up and down movement of the mounting frame 122 and supports the mounting frame 122 at a fixed position without shaking so that the measuring apparatus 10 accurately measures the sub- So that it can measure the information about the user.

On the other hand, the structure of the winch 121, the wire 121a, and the pulley, which are provided for lifting and lowering the mounting frame 122 in the vertical direction, is a well-known technique, and a detailed description thereof will be omitted.

The stir wing 130 prevents the sub-pseudo S from being biased toward the bottom plate 112 due to its own weight and allows the sub-pseudo S to be dispersed and uniformly distributed in the solvent W introduced into the chamber 110 And is distributed. The stirring vane 130 is configured to generate an upward thrust force through the rotation operation and to reduce bubbles generated due to the upward thrust, Respectively.

When the stirring vane 130 performing the above-described function is positioned at the lower end of the accommodation space 110a, the gauge correction system 100 according to the present invention can be stably fixed to the floor with its center of gravity lowered, Interference with the arrangements such as the measurement apparatus carrier 120 and the circulation operation unit 140 to be described later can be reduced.

1, the stirring wing 130 according to the embodiment of the present invention includes a motor 132, an impeller 134, and a turbulence generating grid plate 136 as shown in FIG. The motor 132 is a power unit having a rotating shaft that is rotated by power supply. The motor 132 is provided at one side of the chamber 110 to provide rotational force under the control of the controller 150.

The impeller 134 receives a rotational force from the motor 132 in a state where the impeller 134 is directly connected to the rotation shaft of the motor 132 or through a gear box. The impeller 134 generates thrust force to the upper end of the accommodation space 110a. The blades of the rotor 134 are implemented in the form of four fixed wings, but it is needless to say that the blades can be implemented in two or more. At least one impeller 134 may be stacked vertically, and the number of the impellers 134 stacked vertically may be appropriately determined depending on the height of the chamber 110 in the vertical direction, that is, .

The turbulence generating grid plate 136 is a component for generating turbulence in the suspension (SUS) while rotating together with the impeller 134. The turbulence generating grid plate 136 is realized in the form of a vertical plate having a plurality of hollows formed in a constant arrangement. The turbulence generating grid plate 136 is directly connected to the rotation axis of the motor 132 at an upper portion of the impeller 134 or through a gear box.

At this time, the turbulence occurs in the course of the suspension (SUS) passing through the plurality of hollows according to the rotation of the turbulence generating grid plate 136. This turbulence plays a role of dispersing and removing bubbles which are additionally generated by the impeller 134 generating the upward thrust force from the lower side to a minute size. Accordingly, measurement interference or error of the sub-pseudo-similar measuring apparatus 10 due to bubbles is reduced.

The circulation operation unit 140 draws a suspension SUS at the lower end of the accommodation space 110a having a large distribution of sub-similarities S due to its own weight, (S) uniformly by a method of injecting the solvent S into the upper end portion of the chamber 110a so as to maintain the uniformity of the sub- W), that is, suspension (SUS).

The circulation operation unit 140 according to the embodiment of the present invention includes a circulation pump 142, a circulation pipe 144, and an injection nozzle unit 146 as shown in FIG.

The circulation pump 142 is a component for generating a discharge pressure for circulating the solvent W and the suspension SUS, that is, a part of the suspension SUS, which is provided on the outer side of the chamber 110, Control. The circulation pipe 144 includes a first circulation pipe 144a provided between the circulation pump 142 and the upper end of the chamber 110 and communicating with the upper end of the accommodation space 110a, And a second circulation pipe 144b provided between the plate 112 and communicating with the lower end of the accommodation space 110a.

That is, the suspension (SUS) on the side of the bottom plate 112 flows into the second circulation pipe 144b through the circulation pump 142 and the circulation pipe 144 that provide the circulation power, And can be introduced into the upper end of the accommodation space 110a through the first circulation pipe 144a. The base similarity S in the chamber 110 is not concentrated on the side of the bottom plate 112 by the basic circulation loop composed of the circulation pump 142 and the circulation pipe 144 and is uniformly distributed over the entire upper and lower ends of the chamber 110 Lt; / RTI >

The injection nozzle portion 146 is provided between the stirring vane 130 and the bottom plate 112 to prevent the sub-pseudo S from accumulating on the bottom plate 112 and to re- Which is not found in the prior art, and corresponds to the technical features of the present invention.

1 and 2, the injection nozzle unit 146 according to the embodiment of the present invention includes approximately the injection pump 146a, the ring-shaped nozzle body 146b, and the injection pipe 146c .

The injection pump 146a is a component for generating the discharge pressure for circulating the suspension SUS in the same manner as the circulation pump 142 described above and is provided on the outer side of the chamber 110 to be controlled by the controller 150 do.

The ring-shaped nozzle body 146b is composed of a ring-shaped tube body having a plurality of injection nozzles 146b1 directed toward the bottom plate 112. The one end of the ring-shaped nozzle body 146b is in communication with the stirring pump 130a And the bottom plate 112. [0033]

At this time, the ring-shaped nozzle body 164b may be of any structure or form as long as it can be connected to the injection pump 146a to inject the suspension (SUS). Therefore, as shown in FIG. 2, (That is, one end is communicated with the injection pump 146a and the other end is closed), but also in the form of a complete ring without interruption, one end of which can be made to communicate with the injection pump 146a Of course.

The injection pipe 146c is provided between the injection pump 146a and the chamber 110 to communicate with the accommodation space 110a.

The injection nozzle unit 146 having such a structure allows the suspension SUS in the chamber 110 to flow into the injection pipe 146c through the operation of the injection pump 146a that provides the circulating power, 142 to the ring-shaped nozzle body 164b. Then, the suspension SUS is circulated in such a manner that the suspension SUS is injected through the injection nozzle 146b1.

When the suspension SUS is injected by the injection nozzle 146b1 directed toward the bottom plate 112 as in the embodiment shown in Fig. 3 (a), the sub- (S) floats to the periphery, and the floating sub-similarity (S) is distributed uniformly in the upward direction again through the upper stirring vane (130), so that a uniform distribution of the sub- do.

As described above, since the injection nozzle 146b1 and the stirring blade 130 described above work together and complement each other, it is possible to prevent accumulation of the sub-pseudo S on the bottom plate 112, S can be more uniformly distributed over the entire upper and lower ends of the chamber 110. [

3 (b), the bottom plate 112 is formed with a round machined surface 112a having a concave shape along the inner edge of the bottom plate 112. As shown in FIG. The injection nozzle 146b1 is formed so as to pass through at least one of the round machining surface 112a side, the vertical bottom plate 112 side, and the inner circumferential surface side of the chamber 110. This structure is for further reducing the accumulation of the sub-similarity S in the inner edge region of the bottom plate 112 and for facilitating the floating of the sub-similarity S more easily.

As described above, the circulating operation unit 140 is operated in a superimposed manner with the stirring vane 130, so that the sub-pseudo S is not concentrated on the side of the bottom plate 112, and the solvent introduced into the chamber 110 It is possible to maintain a state of being dispersed or distributed in a more uniform degree in the wafer W.

The control unit 150 is connected to the measuring device 10 to receive and store the measured values and is connected to the winch 121 to control the vertical position of the measuring device carrier 120 and to control the rotation of the stirring wing 130, And controls the operation part 140 to control the uniformity of the suspension SUS in the accommodation space 110a.

The control unit 150 basically receives signals generated from the measuring device 10, the winch 121, the stirring vane 130 and the circulation operation unit 140 in a state of being electrically connected to them, A control command for transmitting the control command is transmitted. The electrical connection between the measuring device 10 and the control unit 150 may be integrally performed through the wire 121a provided between the winch 121 and the measuring device carrier 120.

The controller 150 according to the present invention may be implemented as a small or commercial computer such as a micro controller unit (MCU), a microcomputer, an Arduino, etc., and may be operated stably But it is preferable to be provided at an outer side of the chamber 110 adjacent to the winch 121, the circulation pump 142, the motor 132 and the injection pump 146a .

The object implementation of the test correction system 100 through the control unit 150 described above is performed by being coded in a programming language such as a machine language or the like and can be easily performed in various manners and forms Detailed description thereof will be omitted.

Meanwhile, as described above, the controller 150 is electrically connected to the plurality of intake valves 114, respectively, so that the suspension SUS can be controlled to be drawn out by an amount required for each height. In this case, the control unit 150 controls the winch 121 such that the measurement apparatus 10 is placed at a position corresponding to the intake valve 114 for each height, The measuring device 10 is operated to acquire and store, respectively. The control unit 150 controls the opening and closing of the intake valves 114 corresponding to the measured values of the heights, respectively, so that the suspension (SUS) samples are collected for each height.

(SUS) samples, which are stored and stored automatically under the control of the controller 150 and are required to be post-processed at the same time, are stored for each height It is possible to more quickly and easily perform the correction operation of the measuring apparatus 10 as well as to derive the correlation formula between the measured value information and the post processed sub-similarity (S) information.

Modifications to the structure or form of the measuring device carrier 120 will now be described with reference to Figures 5A to 5C.

5A, at least one guide protrusion 122a protruding from the outer circumferential surface of the mounting frame 122 and elongated along the longitudinal direction of the mounting frame 122 is provided on the mounting frame 122 Or more. The guide ring 124 is formed with a guide groove 124a recessed from the inner circumferential surface of the guide ring 124 so that the guide protrusion 122a is inserted and guided.

At this time, in the case of two or more guide protrusions 122a, it is preferable to be formed on the mounting frame 122 to be symmetrical to each other, and the number of the guide protrusions 122a can be increased approximately according to the size of the mounting frame 122 .

Up and down movement of the mounting frame 122 is stably guided through the guide protrusion 122a and the guide groove 124a as described above and the rotation of the mounting frame 122 provided with the measuring device 10 in the left and right direction is suppressed , The measuring apparatus 10 can accurately measure information on the sub-similarity (S).

Further, the guide groove 124a may be further provided with a pressing means 160 for pressing the guide protrusion 122a. The pressing means 160 may be provided in the guide groove 124a, And a fixed ball 162 elastically supported in the direction of the center of the guide ring 124 by the guide rails 164.

Through the pressing means 160, the mounting frame 122 can be firmly held in a state of being fitted in the guide ring 124, and the occurrence of a gap between the mounting frame 122 and the guide ring 124 can be prevented The vibration of the mounting frame 122 provided with the measuring apparatus 10 is fundamentally prevented.

5B, the inner peripheral surface of the guide ring 124 may be further provided with a pressing means 160 for pressing the mounting frame 122. The pressing means 160 may be embodied as a leaf spring 163 that is partially protruded in the direction of the center of the guide ring 124 while being accommodated in the inner circumferential surface of the guide ring 124.

This pressing means 160 also allows the mounting frame 122 to be firmly held in a state of being fitted in the guide ring 124 and prevents the occurrence of clearance between the mounting frame 122 and the guide ring 124 do.

5c, the inner circumferential surface of the guide ring 124 is further provided with a pressing means 160 for pressing the mounting frame 122, wherein the pressing means 160 includes a guide ring 124 And a fixing ball 162 elastically supported in the center direction of the guide ring 124 by the elastic body 164 in a state of being accommodated in the inner peripheral surface of the guide ring 124. [

This pressing means 160 can also maintain the position of the mounting frame 122 in a state where the mounting frame 122 is fitted in the guide ring 124 and prevents the gap between the mounting frame 122 and the guide ring 124 The precise and accurate measurement of the measuring apparatus 10 can be performed by fundamentally preventing the mounting frame 122 from shaking.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, such modifications or variations should not be individually understood from the technical spirit and viewpoint of the present invention, and modified embodiments should be included in the claims of the present invention.

W: solvent S: minor
SUS: Suspension 10: Measuring device
100: The sword correction system of the sub-pseudo-similar measuring apparatus according to the present invention
110: chamber 110a: accommodation space
111: cover plate 112: bottom plate
112a: round machining surface 114: intake valve
120: Measuring device carrier 121: Winch
121a: wire 122: mounting frame
122a: guide protrusion 124: guide ring
124a: guide groove 130: stirring blade
132: motor 134: impeller
136: turbulence generating grid plate 140: circulation operating part
142: Circulation pump 144: Circulation piping
144a: first circulation pipe 144b: second circulation pipe
146: jet nozzle unit 146a: jet pump
146b: ring-shaped nozzle body 146b1: injection nozzle
146c: injection pipe 150:
160: pressing means 162: fixed ball
163: leaf spring 164: elastic body

Claims (11)

A cylindrical chamber having a housing space in which a solvent and a floating syringe are inserted, the cylindrical chamber having a bottom plate;
A measuring device carrier lifting up and down in the receiving space by a winch in a state in which at least one sub-similar measuring device is mounted;
A stirring blade installed at a lower end of the containing space to perform a rotating operation so that the solvent and the suspended sol are mixed with each other to form a uniform suspension without bubbles;
A circulation operating portion communicating with the accommodating space at an upper end portion of the chamber and the bottom plate side to circulate the sub-pellets with the solvent; And
And a control unit for controlling the rotation of the stirring vane and the circulation operation unit to control the uniformity of the suspension in the accommodation space, And a control unit for controlling the control unit,
Wherein the measuring device carrier comprises:
A mounting frame formed so as to be vertically long so as to mount at least one sub-pseudo-similar measuring device and having an upper end connected to the winch and a wire so as to vertically move up and down; And a plurality of guide rings spaced up and down on one side of the inner circumferential surface of the chamber and having a ring shape through which the mounting frame passes and guiding the up and down movement of the mounting frame,
In the mounting frame,
At least one guide protrusion protruding from the outer circumferential surface of the mounting frame and elongated along the longitudinal direction of the mounting frame, wherein the guide ring is provided with a guide recessed from the inner circumferential surface of the guide ring, And a groove is formed in the groove. The method according to claim 1,
The circulation operation unit includes:
A circulation pump provided at an outer side of the chamber and under the control of the control unit;
A first circulation pipe provided between the circulation pump and the upper end of the chamber and communicating with the accommodation space; and a second pipeline provided between the circulation pump and the bottom plate and communicating with the accommodation space; And
And a jet nozzle unit provided between the stirring blade and the bottom plate to prevent the floating oil from accumulating on the bottom plate. 3. The method of claim 2,
The injection nozzle unit
A spray pump provided at an outer side of the chamber and controlled by the control unit;
A ring-shaped nozzle body provided between the stirring blade and the bottom plate in a state where one end portion is in communication with the injection pump, the ring-shaped nozzle body having a plurality of spray nozzles directed toward the bottom plate; And
And an injection pipe provided between the injection pump and the chamber and communicating with the accommodation space. The method of claim 3,
The chamber
And a plurality of intake valves spaced apart from each other in the longitudinal direction of the chamber so as to allow the suspension to be taken out by the height of the chamber. The method of claim 3,
In the bottom plate,
In order to reduce the accumulation of the floating oil in the inner edge region of the bottom plate,
A rounded surface of a concave shape is formed along an inner edge of the bottom plate,
The spray nozzle
And the through hole is formed so as to be directed to at least one of the side of the round machining surface, the side of the bottom plate, and the inner circumferential surface of the chamber. 3. The method of claim 2,
The stirring blade
A motor provided at an outer side of the chamber to provide a rotational force under the control of the controller;
At least one impeller which receives a rotational force of the motor and generates a thrust force at an upper end of the accommodating space; And
And a turbulence generating grid plate positioned above the impeller to receive the rotational force of the motor and generate turbulence in the suspension according to the rotation to reduce bubbles in the suspension. . delete delete The method according to claim 1,
In the guide groove,
Further comprising a pressing means for pressing the guide protrusion so that the mounting frame can be firmly held in a state of being fitted to the guide ring,
Wherein the pressing means comprises:
And a fixed ball which is elastically supported in the center direction of the guide ring by an elastic body while being accommodated in one side of the guide groove. The method according to claim 1,
On the inner circumferential surface of the guide ring,
Further comprising a pressing means for pressing the mounting frame so that the mounting frame can be firmly held in a state of being fitted to the guide ring,
Wherein the pressing means comprises:
And a plate spring which is formed in such a manner that a part of the leaf spring is convexly protruded in the center direction of the guide ring while being housed in the inner circumferential surface of the guide ring. The method according to claim 1,
On the inner circumferential surface of the guide ring,
Further comprising a pressing means for pressing the mounting frame so that the mounting frame can be firmly held in a state of being fitted to the guide ring,
Wherein the pressing means comprises:
And a fixed ball which is elastically supported in the center direction of the guide ring by an elastic body in a state of being housed in the inner peripheral surface of the guide ring.

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