KR20040058702A - Floc size particle counting system - Google Patents

Abstract

PURPOSE: A particle calculation system is provided to detect the number of particles in an exact flock size by finely adjusting the absorption of an absorption cylinder through a lead screw. CONSTITUTION: A particle calculator(10) detects particles by installing in one side of a passage to be connected with an inlet portion. A storage portion(20) is connected with the passage via the particle calculator. The storage portion has a certain storage space. An absorption cylinder(40) is connected with an absorption passage in one side of the storage portion and equipped with a piston(45). Driving devices(50) drives the stroke of the piston. An outlet portion(26) is connected with the storage portion. The outlet potion is an outlet to discharge the sample outside. Thereby, the reduction of the pressure inside the absorption cylinder is controlled precisely by precisely controlling the moved amount of a lead screw. Therefore, the sample is absorbed by finely reducing the internal pressure of the absorption cylinder.

Description

Flock Detection Particle Counting System {FLOC SIZE PARTICLE COUNTING SYSTEM}

The present invention relates to a particle counting system for detecting floc sized particles, and more particularly to a floc size using an inhalation cylinder having a structure capable of slowly inhaling a sample at a constant pressure so as not to break the floc sized particles. The present invention relates to a particle counting system for floc detection, which accurately measures the number of particles.

In the water purification process that replaces raw water, which is the source of domestic water, with tap water, the quality of raw water becomes worse and the water quality standards of tap water become stronger as a result of water pollution, which necessitates the improvement of the conventional water purification system and its operation method. have.

Conventional water purification processes are largely divided into flocculation, precipitation, and filtration processes, in which flocculants are injected to flocculate very small colloidal materials to form flocs, and then removed in a subsequent precipitation or filtration process. Done.

At this time, the floc is neutralized by mixing the negative particles in the raw water with the positive flocculant in the mixing process and causing the particles to collide by stirring the neutralized particles in the floc forming process. The flocs are optimized and settle well and settle in the sedimentation basin and enter the supernatant filter.

Once the floc is formed, it should be introduced into the sedimentation basin without breaking as much as possible, so that the sedimentation occurs well and the subsequent filtration efficiency is improved and finally the efficiency of water purification is good. However, in the floc forming step of the flocculation step, the floc already formed during the floc forming paper breaks again, which is a problem.

In order to improve this, it is necessary to find an optimal process in which the floc is not broken. In order to achieve this, it is necessary to measure each of the floc breaks while changing the process conditions. At this time, a particle counter is used to measure the number of particles of floc size.

4 is a layout view briefly showing the main configuration of a conventional particle counting system. As shown in FIG. 4, the conventional particle counting system has a main configuration of the inlet 1, the particle counter 10, and the suction pump 80. Detailed configuration of the washing structure, etc. is omitted here for the sake of simplicity.

The conventional particle counting system is to operate the impeller 81 of the suction pump 80 to introduce the sample sample into the inlet (1). That is, the sample is sucked by the rotation of the suction pump 80 and discharged through the discharge port 82 installed in the suction pump 80, and the sample sample is forcibly discharged as a result of the variation of the internal pressure in the inlet ( A sample sample is drawn from 1).

The conventional particle counting system draws a sample sample using a suction impeller having a rotational speed of several hundreds to thousands of rpm, so that the internal air pressure drop is large, and the sample sample flows in at a high speed. The floc was broken, making it difficult to measure the exact amount of floc, and the range of measurement errors was also a big problem.

In other words, the particle size of the particles, which can be measured by the particle counting system, is limited to about 100 microns or less, and it is difficult to measure particles of several hundred microns.

The present invention has been made to solve the above problems, and an object of the present invention is to finely adjust the suction of the suction cylinder using a lead screw or the like in the particle counting system so that the particles of the floc contained in the sample sample are not broken. By providing a particle counting system that detects the exact number of particles of the floc size.

The object of the present invention is an inlet for the sample sample is introduced; A particle counter installed at one side of a flow path connected to the inlet to detect particles; A receiving part connected to the flow path after passing through the particle counter and having a predetermined receiving space; A suction cylinder connected to a suction path formed at one side of the accommodation part and provided with a piston; Drive means for driving the stroke of the piston; And it can be achieved by the floc detection particle counting system characterized in that it comprises a discharge portion which is communicated with the receiving portion and is an outlet for discharging the sample sample to the outside.

In addition, in order to achieve the above object, the piston has a lead screw coupled to one side, and the driving means is preferably a motor connected to the lead screw.

In addition, in order to achieve the above object, the driving means is preferably a hydraulic cylinder having a piston rod connected to the piston.

In addition, it is preferable to further comprise a washing means consisting of a washing material inlet, the washing material outlet and the washing material dissipating unit for the water and air is introduced and discharged for washing to one side of the receiving portion to achieve the above object.

In addition, in order to achieve the above object, the particle counter is preferably a particle counter for measuring floc sized particles.

In addition, in order to achieve the above object, it is preferable that a filter is further installed in the suction passage between the accommodation portion and the suction cylinder.

Other objects, specific advantages and novel features of the invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

1 is a layout view schematically showing the configuration of a particle counting system for detecting flocs according to an embodiment of the present invention;

Figure 2 is a perspective view showing a suction cylinder and the driving means of the particle counting system for detecting flocs according to an embodiment of the present invention,

Figure 3 is a perspective view showing a suction cylinder and another driving means of the particle counting system for detecting flocs according to an embodiment of the present invention,

4 is a layout view briefly showing the main configuration of a conventional particle counting system.

Explanation of the Main References

1: inlet 10: particle counter

11: sensor 20: receiver

30: cleaning device 40: suction cylinder

45: piston 50: servo motor

60: screw 61: screw nut

70: hydraulic cylinder

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the particle counter for detecting the floc according to an embodiment of the present invention.

1 is a layout view schematically showing the configuration of a particle counting system for detecting flocs according to an embodiment of the present invention. As shown in FIG. 1, the floc detection particle counting system according to the present invention has a large inlet 1, a particle counter 10, a receiving part 20, a suction cylinder 40, and driving means 50, 70. ), The discharge unit 26 and the washing means 30.

The inlet part 1 is installed at one side of the flow path adjacent to the inlet 3 of the flow path formed so that the sample to be measured can be introduced into the particle counting system, the sample of the washed sample and the outlet 3 of the flow path from which the water is discharged. It consists of a second switch valve 4 which selectively opens or closes the inlet 3 or the outlet 2.

A sensor 11 connected to the particle counter 10 is installed at one side of the flow path passing through the second switch valve 4, and the sensor 11 is connected to the particle counter 10 that measures the number of floc particles. Particle counter 10 applied to the particle counting system of the present invention can measure the particle size of 40 ~ 6500 microns (micron), for example, PAMAS 3116 FM system can be used.

The flow passage passing through the sensor 11 is connected to the receiving portion 20 for receiving the sample sample through the sensing element 12. Receiving unit 20 is a cylinder formed with a predetermined internal space to accommodate a sample, one side of the receiving unit 20 is formed with an inlet 3 of the flow path to the suction cylinder 40 to be described later, The washing material dissipation part 31 of the washing means 30 to be built-in, and the discharge port 22 for communicating with the discharge part 26 through which the air introduced into the receiving part 20 is discharged is formed. A second open / close valve 25 for opening and closing the flow path is installed between the discharge part 26 and the discharge port 22.

A third opening / closing valve 43 for opening and closing the flow passage is installed in the flow passage connecting the accommodation portion 20 and the suction cylinder 40, and foreign matter is transferred to the suction cylinder 40 through the third opening and closing valve 43. A filter 42 is installed to prevent the inflow. The suction cylinder 40 has a suction cylinder inlet 41 is formed on one side to communicate with the flow path connected to the receiving portion 20, the inside of the suction cylinder 40 in a straight line in the suction cylinder 40 The piston 45 is provided to reciprocate. The suction cylinder 40 is sealed except the suction cylinder inlet 41 so that the internal pressure can be lowered by the movement of the piston 45.

Figure 2 is a perspective view showing a suction cylinder and the driving means of the particle counting system for detecting flocs according to an embodiment of the present invention. As shown in FIG. 2, the box-shaped coupling portion 62 is a piston 45 for connecting the piston 45 installed in the suction cylinder 40 and the lead screws 60 and 61 installed in the servomotor 50. And the servo motor 50. The lead screws 60 and 61 are composed of a screw 60 and a screw nut 61, and are mounted to the servo motor 50 and the coupling part 62, respectively.

The coupling portion 62 has a center-penetrated shape, in which a screw nut 61 of the lead screws 60 and 61 is mounted, and a pair of supporting rods 46 extended to the piston 45 on both sides of the front surface. Are symmetrically coupled. The screw nut 61 is connected to the servomotor 50 and is rotatable with a screw 60 that is rotatable.

As shown in FIG. 1, the washing means 30 installed at one side of the receiving part 20 includes a water inlet 32, an air inlet 33, a first switch valve 34, and a first open / close valve 35. ) And the cleaning material dissipation unit 31. Water is injected into the water inlet 32 by the pump (not shown) and air is injected into the air inlet 33.

The flow paths respectively connected from the water inlet 32 and the air inlet 33 are joined together, and the first switch valve 34 is provided therein. A flow path extending through the first switch valve 34 is connected to the accommodating portion 20, and a washing material dissipating portion 31 for dissipating water or air to the accommodating portion 20 is provided at an end of the flow passage. The cleaning material dissipation unit 31 has a nozzle (not shown) on one side to spray water at a high pressure. On the flow path connecting the cleaning material dissipation unit 31 and the first switch valve 34, a first on-off valve 35 for opening and closing the flow path is installed.

The servomotor 50, the open / close valves 25, 35, 43, the switch valves 4, 34 and the particle counter 10 all operate under the control of a central controller (not shown) of the particle counting system.

3 is a perspective view showing a suction cylinder and another driving means of the floc detection particle counting system according to an embodiment of the present invention. As shown in FIG. 3, when the hydraulic cylinder 70 is used as a means for driving the piston 45 installed in the suction cylinder 40, the piston rod 71 and the piston 45 of the hydraulic cylinder 70 are used. Couplings 74 are interposed in order to connect the propped support rods 47.

The hydraulic cylinder 70 is formed by symmetrically protruding the first inlet 72 and the second inlet 73 on both sides of the outer surface, the hydraulic cylinder 70 is the first inlet 72 and the second inlet 73 It is connected to a hydraulic pump (not shown) via a tube 74 connected to it.

Hereinafter will be described in detail the method of operation of the floc detection particle count system according to an embodiment of the present invention having the above configuration.

1 is a layout view schematically showing the configuration of a particle counting system for detecting flocs according to an embodiment of the present invention. Hereinafter, a process of measuring the number of floc particles will be described with reference to the layout shown in FIG. 1.

(1) The first on-off valve 35 is in a closed state, the second on-off valve 25 and the third on-off valve 43 are in an open state, and the first switch valve 34 ) Is normally open and the second switch valve 4 is in a normal close state. The first switch valve 34 opens only the water inlet 32 in the normal open state and only the air inlet 33 in the normal closed state. The second switch valve 4 opens the inlet 3 of the inlet 1 and closes the outlet 2 in the normally open state, and closes the inlet 3 and opens the outlet 2 in the normal closed state. do. In the following description, redundant descriptions of the normal closed state and the normal open state are omitted for brevity.

(2) The servo motor 50 is driven to move the piston 45 toward the suction cylinder inlet 41, and when the piston 45 reaches the suction cylinder inlet 41, the second on-off valve 25 is closed. do.

(3) The second switch valve (4) is switched to the normally open state to open the inlet (3) of the inlet (1), the servo motor 50 is driven to drive the piston (45) to the servo motor (50). Move to). At this time, by rotating the servo motor 50 at a low speed, the piston 45 gradually moves inside the suction cylinder 40, and thus the internal pressure of the suction cylinder 40 decreases finely. The receiving portion 20 in communication with the suction cylinder 40 also sucks the sample sample from the inlet 3 of the inlet portion 1 with a slight pressure while the internal pressure gradually decreases so that the floc is not broken.

(4) When the sensing element 12 installed just before the receiving unit 20 detects the sample sample, the particle counter 10 starts to measure the number of floc particles contained in the sample sample.

(5) When the piston 45 moves to the end of the suction cylinder 40 on the servomotor 50 side, the second switch valve 4 is normally closed, and the inlet 3 of the inlet 1 is closed. The furnace outlet 2 is opened and the second on-off valve 25 is opened, and then the piston 45 is moved toward the suction cylinder inlet 41 again.

(6) While the piston 45 is moving, the water is introduced through the water inlet 32 with the first opening / closing valve 35 in an open state and is radiated to the receiving part 20 through the washing material radiating part. 1 closing valve 35 is closed and the discharged water is discharged through the outlet (2) after washing the receiving portion (20).

(7) The second on-off valve 25 is in a closed state, the first on-off valve 35 is in an open state, and water is introduced from the water inlet 32, and the first on-off valve 35 is in a closed state. And, the water radiated through the radiator is discharged through the outlet (2) of the inlet (1) while washing the sensor 11 of the particle counter (10).

(8) When the piston 45 reaches the inlet cylinder inlet 41, the third open / close valve 43 is closed, the first open / close valve 35 is open, and the first switch valve 34 Is converted to a normal closed state and air is injected into the receiving portion 20 through the air inlet 33 to dry the containing portion 20, and then the air is discharged to the discharge portion 26 through the outlet 22. .

(9) When drying is completed, the first switch valve 34 is in a normally open state, and the first on-off valve 35 is switched to a closed state.

The measurement of the number of floc particles of the new sample sample is then performed while repeating the first steps (1) to (9).

In a preferred embodiment of the present invention, the particle counting system is applied to a system for detecting particles of floc size, but the present invention is not limited thereto. Will be included.

In addition, although the position of the lead screw adopted in the preferred embodiment of the present invention is concentric with the piston, the present invention is not limited to this, and the present invention is not limited thereto. It is also possible.

In addition, the structure of the washing means adopted in the present invention is only a preferred embodiment and the scope of the present invention includes a modification to enable the washing and drying, in particular including both the position and the number of the opening and closing valves, switch valves do.

In addition, the arrangement adopted in the present invention is only a preferred embodiment and is not intended to limit the scope of the present invention, and other modified arrangements including a suction cylinder using a lead screw will also be included in the scope of the present invention.

Further, in the preferred embodiment of the present invention, the lead screw is used as the means for driving the piston, but the present invention is not limited thereto, and includes other means using the lead of the screw.

According to the floc detection particle counting system according to an embodiment of the present invention having the above-described configuration, the internal pressure of the suction cylinder can be precisely controlled by the amount of movement of the lead screw connected to the piston according to the rotational speed of the servomotor. It is possible to precisely control the reduction, and thus there is an advantage in that the sample sample can be sucked while finely reducing the internal pressure of the suction cylinder.

By making the sample sample inlet rate very small, the number of floc particles can be measured without breaking the flocs contained in the sample sample, which makes it possible to measure floc particles that could not be measured conventionally. There is a significant effect of improving performance.

As the number of particles included in the sample sample can be accurately measured, the optimum water purification process can be found while changing the conditions of the water purification process. It can be operated, which contributes to improving the efficiency of the installation.

By adjusting the speed of the stroke of the suction cylinder of the particle counting system according to the size of the particles contained in the sample sample, there is an effect that can be used to detect particles of various sizes.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as fall within the spirit of the invention.

Claims (6)

An inlet 1 through which a sample sample flows; A particle counter 10 installed at one side of a flow path connected to the inlet 1 to detect particles; A receiving part 20 connected to the flow path after passing through the particle counter 10 and having a predetermined receiving space; A suction cylinder 40 connected to a suction path formed at one side of the accommodation part 20 and provided with a piston 45; Drive means (50, 70) for driving the stroke of the piston (45); And Flock detection particle counting system, characterized in that it comprises a discharge portion 26 that communicates with the receiving portion 20 and is an outlet for discharging the sample sample to the outside. The method of claim 1, wherein the piston 45 is coupled to one side of the lead screw (60, 61), the drive means 50 is characterized in that the motor 50 is connected to the lead screw (60, 61). Particle counting system for floc detection. The particle counting system for floc detection according to claim 1, wherein the driving means (70) is a hydraulic cylinder (70) having a piston rod (71) connected to the piston (45). According to claim 1, wherein the washing means 30 consisting of the cleaning material inlet (32, 33) and the cleaning material dissipation unit 31 to the water and air is introduced and discharged to one side of the receiving portion 20 for washing; Flock detection particle counting system, characterized in that it further comprises. The particle counting system for floc detection according to claim 1, wherein the particle counter (10) is a particle counter (10) for measuring particles of floc size. The particle counting system for floc detection according to any one of claims 1 to 3, wherein a filter (42) is further provided in a suction path between the receiving portion (20) and the suction cylinder (40).