KR20090109602A - The module structure of ultra filteration system for on-line analyzer - Google Patents

Abstract

PURPOSE: Hollow fiber membrane module structure for an ultra filtration system used for an online analyzer is provided to minimize waste of workforce, and to offer quick response of process change. CONSTITUTION: Hollow fiber membrane module structure for an ultra filtration system includes a hollow fiber membrane(111a), a fastening plate(120), and a vibrator(130). A plurality of hollow fiber membranes are installed at a module housing(110). The fastening plate includes a penetration hole and a binding hole. The vibrator removes impurities caught in the hollow fiber membrane by vibrating the hollow fiber membrane and the fastening plate.

Description

The module structure of ultra filteration system for on-line analyzer

The present invention relates to a hollow fiber membrane module structure that is part of the configuration of a system for pre-processing a sample so that an online analyzer can analyze a sample containing suspended solids. More specifically, most analytical samples (pH, NH3-N, NO3-N, heavy metals, anions, cations, etc.) are not air sensitive, but some DO (Dissolved Oxygen) and ORP (Oxidation Reduction Potential) oxidations. Reduction potential) and highly volatile materials are affected by air.

In order to blow off the hollow fiber membrane pore blocking of suspended solids, in the method of blowing out the foreign matter attached to the surface of the hollow fiber membrane, the analytical samples affected by the air, such as the DO value, ORP value and volatile components, are changed so that DO, ORP and Differences between the actual volatile component actual values and the DO, ORP and volatile component measured values can occur.

In the case of the sample affected by air, there is a problem in that it is impossible to remove foreign substances attached to the hollow fiber membrane by injecting air, thereby inducing a vibration to the hollow fiber membrane module, thereby inducing a vibration device to shake off impurities or debris caught in the hollow fiber membrane, By adopting a method that measures the water level of raw water sucked inside the module housing and automatically operates the system, even samples affected by air can be sampled stably by the on-line analyzer without deterioration of the sample by air. Hollow fiber membrane module structure of ultrafiltration system for on-line analyzer to produce.

In general, an on-line analyzer analyzes various types of water, such as household water and household water, to determine whether the use is appropriate. In other words, in the case of household water, it is used to determine whether components contained in the water are suitable for use as drinking water. In the case of factory wastewater, it is used to measure how harmful the discharged water is to the natural environment, and it is used to measure how harmful the water discharged from the barn or pig house is. Measurement errors due to blockage of the flow path, valve blockage, etc. An analysis reliability deterioration phenomenon occurs due to electrode film formation or the like. An ultra-filtering system is installed in front of the on-line analyzer to filter suspended solids in the analytical sample, allowing the on-line analyzer to continuously detect accurate concentrations. Of course, as described above, the ultrafiltration system for an on-line analyzer is inherently insignificant, and thus there is virtually no conventional technology.

Only No. 10-2006-34151 filed by the applicant of the present invention to the Korean Intellectual Property Office will be the only one. Looking at the configuration and operation of the system are as follows. The invention will be described with reference to FIGS. 1 to 3.

In the present invention, as shown in FIG. 1, the raw water sample 1 is pumped through the first pump 11 and obtained into the first pipe 21. Then, the obtained raw water sample 1 enters the hollow fiber membrane module 70 and comes out through the fourth pipe 23 connected to the lower portion of the hollow fiber membrane module 70 in a state of filtering solid material. Then, the filtered analysis sample P from the fourth pipe 23 comes to the fourth open / close valve 33 through the fifth pipe 104, and the fourth open / close valve 33 is a bidirectional valve. . Therefore, the other side of the fourth opening / closing valve 33 is different from the direction for collecting the analysis sample and is obtained in the direction of the first flow meter 61 by the pumping force of the second pump 13. While passing through the fifth opening / closing valve 34 while measuring the amount of the analytical sample P produced through the first flow meter 61, the insoluble solids of the raw water sample 1 are transferred to the analytical sample collection tank 40. It is to store the filtered analysis sample (P).

This stored sample P may be used for analysis or may be used to clean the hollow fiber membrane filter 75, as will be described later. That is, in the case of the on-line analyzer filtering system of the present invention, the solids are filtered and the filtered analysis sample is sent to the on-line analyzer to analyze the components thereof.

However, referring to FIGS. 1 and 3, the analytical sample P obtained into the hollow fiber membrane filter 75 is collected in the lower tank 73 shown by gravity, and collected in the lower tank 73. The excitation analysis sample (P) is to be collected in the analysis sample collection tank 40, as described above. However, when the system of the present invention is continuously operated to perform the process of filtering the solids A, the hollow fiber membrane filter 75 is clogged with the solids A. Then, in order to solve this problem, the hollow fiber membrane module 70 of the present invention is washed using the analysis sample P collected in the analysis sample collection tank 40. That is, the analysis sample P collected in the analysis sample collection tank 40 discharges the portion overflowing through the illustrated tenth pipe 81 and is always collected at the highest water level. Therefore, the collected analysis sample (P) is pulled out, and the second pump 13, the first flow meter 61, and the fifth open / close valve 34 in both directions through the fourth open / close valve 33 in both directions. It passes through the tube (105). Of course, since the fourth opening / closing valve 33 is a bidirectional valve, it can be converted to a state in which one side is blocked and one side is open as shown in FIG. 1B.

Therefore, the analytical sample P passing through the ninth tube 105 passes through the fourth tube 23 and is obtained into the lower tank 73. That is, it is obtained in the direction opposite to the direction to filter the analysis sample (P). The sample for analysis (P) introduced into the lower tank (73) is discharged into the inside of the hollow fiber module housing 71 through the filter hole 74 of the hollow fiber membrane filter 75 by the water pressure. will be. Of course, as described above, the analytical sample (P) is already in the filtered state of the solid (A) is easy to pass through the filter hole 74 of the hollow fiber membrane filter (75). Therefore, in the on-line detection process, the solids A stuck or blocked in the filter hole 74 of the hollow fiber membrane filter 75 may be discharged as shown in FIG. 3.

Alternatively, there is also a method of cleaning using air, as shown in FIGS. 1 and 3, at the bottom of the diffuser 77, through the first pressure gauge 86 and the supply pipe 111, into the diffuser 77. Blow the air to shake off the hollow fiber membrane filter (75). That is, the diffuser 77 is formed inside the hollow fiber membrane filter 75, and the discharge hole 76 shown at the bottom thereof is formed. Therefore, the air supplied at high pressure through the first pressure gauge 86 passes through the supply pipe 111 and is obtained into the diffuser 77. However, the cylindrical diffuser 77 has only a discharge hole 76 formed at its lower end. Therefore, it is strongly ejected to the discharge hole (76).

At this time, the air is to shake off the hollow fiber membrane filter 75 provided on the outside, and in this process it can shake off impurities or solids (A) stuck in the filter hole 74 of the hollow fiber membrane filter 75. . That is, the solids (A) or suspended matter caught in the filter hole 74 of the hollow fiber membrane filter 75 is separated by this vibration can be prepared to perform a more accurate work in the next analysis work It is.

The disadvantages of the conventional filtering system, such as DO, ORP, and highly volatile substances, which are affected by air or oxygen by air injection, blow off the hollow fiber membrane filter 75 by blowing air into the housing. Differences, or errors, may occur between on-line analyzer readings and actual raw material values.

In addition, if the system is operated while the raw water sample does not occupy the inside of the housing, the hollow fiber membrane is exposed to the air and the air is sucked to the exposed hollow fiber membrane area, which may lead to the deterioration of the sample in the case of DO, ORP and volatile measurement samples. Can be.

The present invention is a hollow fiber membrane module structure which is a part of the system configuration for pre-processing the sample so that the online analyzer can analyze the sample containing suspended solids, causing vibrations inside the hollow fiber membrane module to the surface of the hollow fiber membrane Built-in vibration device to shake off the suspended solids prevents the hollow fiber membrane flow rate decreases, and measures the level of raw water flowed into the module housing to detect the hollow fiber membrane in the air beforehand. Hollow fiber membrane module of ultra-filtration system for on-line analyzer which can stably produce DO (Dissolved Oxygen), ORP (Oxidation Reduction Potential) and ORP (Oxidation Reduction Potential) and volatile components analysis without alteration. We want to provide a structure.

The present invention provides a hollow fiber membrane unit structure comprising: a plurality of hollow fiber membranes (111a) installed in the module housing (110); A disk-shaped fastening plate 120 having a plurality of membrane through-holes 121 and a coupling hole 122 formed at a center thereof so as to be fitted into the long hollow fiber membrane 111a; Vibration device 130 is fitted in the coupling hole 122 of the fastening plate 120; Ultra-filtration system for on-line analyzer that combines the vibration of the vibration device 130 shakes the fastening plate 120 and the hollow fiber membrane (111a) to shake off the floating material to prevent the floating material on the surface of the hollow fiber membrane (111a) The hollow fiber membrane module structure.

According to the present invention, the vibrator 130 includes: a cylindrical motor case 131; A cam 133 eccentrically coupled to the shaft 132 and inserted into the motor case 131; A cover 137 having a stepped portion 136 fitted into the opening 135 at both ends of the motor case 131; To generate vibrations; The motor 134 is a hollow fiber membrane module structure of an ultrafiltration system for an on-line analyzer, in which any one of electric, air, and hydraulic motors can be used.

The present invention is a hollow fiber membrane module structure, the settling tank 141 coupled to the lower end of the module housing 110 is formed in a cylindrical shape; A discharge pipe 142 coupled to a lower portion of the settling tank 141; A valve 143 coupled to one side of the discharge pipe 142; By combining the opening and closing of the valve 143 is a hollow fiber membrane module structure of the ultra-filtration system for on-line analyzer that can remove impurities in the module housing 110.

The present invention provides a hollow fiber membrane module structure comprising: a utility supply pipe 152 inserted into the upper utility supply pipe holder 151 of the module housing 110 and lowered into the housing; Upper and lower stoppers 153 and 153a for controlling an up and down interlocking width at an end of the utility supply pipe 152; A cylindrical float 155 inserted between the stopper 153 and 153a between the utility supply pipe 152 and having a permanent magnet 154 embedded therein; A reed switch 152b formed in the center of the utility supply pipe 152 between the stoppers 153 and 153a; When the number of raw water is coupled to the inside of the module housing 110, the float 155 rises according to the water level of the water, and the permanent magnet measures the level of the raw water by grounding the reed switch 152b. Hollow fiber membrane module structure of ultrafiltration system for analyzer.

The present invention may cause a phenomenon in which the flow rate through the hollow fiber membrane is reduced by accumulating the hollow fiber membrane suspended solids due to prolonged use unless the air blown to the hollow fiber membrane to shake off the suspended solids attached to the surface of the hollow fiber membrane. Most analytical samples (pH, NH3-N, NO3-N, Pb, Cr, Cu, anionic cations, etc.) are not affected by air, but the measurement samples such as DO, ORP and highly volatile components are suspended. In the method of blowing out the foreign matter adhering to the surface of the hollow fiber membrane by blowing air to prevent the hollow fiber membrane pore blocking, the sample may change due to the air, which may cause a difference or error between the online analysis value and the actual raw material value.

The hollow fiber membrane clogging caused by long-term use decreases the flow rate through the hollow fiber membrane, and it is suspended to produce samples for DO, ORP and volatile component analysis through the vibration device produced by the motor rotating at high speed without blowing air. If the raw water sample supply is not smooth inside the housing, the raw water sample level will be lower than the top of the hollow fiber membrane, and the hollow fiber membrane will be exposed to the air, and the air will be sucked into the exposed hollow fiber membrane, resulting in deterioration of the sample. It is a useful invention that provides a water level sensor function that blocks the inclusion of air in the sample for analysis to detect that the raw water level inside the module housing is lower than the top of the hollow fiber membrane to prevent the production of analytical samples including air.

In addition, the present invention provides continuous analysis of solids in liquid samples containing a large amount of solids in the fields of environment, food, chemistry, microorganisms, etc., and makes the samples the best state that an on-line analyzer can analyze. Reliable sample analysis, real-time process change detection and rapid response can be achieved, and manpower waste due to online analyzer life extension and analyzer maintenance and calibration can be minimized.

The present invention relates to a system for continuous filtration analysis of samples containing large amounts of suspended solids. Then, in order to explain the present invention more easily, the suspended solids and the hollow fiber membrane filter will be described.

These solids that do not dissolve in water and float in water are called suspended solids. More specifically, these suspended solids are suspended, colloidal, or dissolved depending on the particle size. It refers to particles having a thickness of at least μm, and refers to particles having a size of 0.1-0.001 μm in the colloidal state, and particles having a size of 0.001 μm or less in the dissolved state. Here, belonging to the suspended solids (SS) of the present invention refers to particles of 0.1 μm or more and colloidal particles of 0.01 μm or more, which must be continuously separated before detection to determine the accuracy of the detection.

 Therefore, the Ultra Filtering System of the present invention is a method for separating particles dispersed in a liquid using a filter hole having a pore size of about 0.01 to 0.6 μm. The membrane to be separated is a hollow filter (Hollow Filter), literally a tube in the form of a hollow tube.

The filtration capacity of this ultrafiltering system is such that low-molecular substances (K, Mg, Ca, Na, Cl) in raw water are permeated through the membrane and high-molecular substances (SS, E. coli, virus, bacteria, bacterial vibrio, red algae) , Oil, colloidal solution, pyrogen, etc.) are all concentrated and removed. Hollow Fiber Module is a bundle of dozens or thousands of hollow fibers with an outer diameter of 3mm or less and placed in a pressure vessel. Suspended solids filtration is carried out through the hollow fiber membrane, in which the raw water containing the suspended solids is pressurized and introduced into the pressure vessel, and the introduced raw water flows out of the hollow yarns (cross flow). And the permeate is sucked by the second pump 13 through the middle of the hollow fiber to depressurize, and the solute and water passing through each hollow fiber membrane are combined in the upper module collection tank of the hollow fiber membrane module and then go out of the module again. It will be collected in the sample collection tank. In addition, the hollow fiber membrane has the advantage of excellent filtration efficiency due to the large area of the treated membrane per unit volume. However, since it has self-supporting properties, backwashing is possible. .

In general, automatic backwashing on samples that are easily contaminated allows continuous production of a certain amount of analytical samples at all times, enabling the best normal operation of an on-line analyzer.

Next, the configuration of the present invention and its operation will be described in detail with reference to FIGS. 4 to 9. In the hollow fiber membrane unit structure, there are a plurality of hollow fiber membrane (111a) installed in the module housing 110, the coupling hole 122 in the plurality of membrane through-holes 121 and the center to be fitted to the long hollow fiber membrane (111a) There is a disk-shaped fastening plate 120 is formed, there is a vibration device 130 fitted in the coupling hole 122 of the fastening plate 120. Therefore, by combining them, the vibration of the vibration device 130 may shake the fastening plate 120 and the hollow fiber membrane 111a to remove impurities trapped in the hollow fiber membrane 111a. That is, in fact, the system of the present invention is the same or similar in form to the conventional hollow fiber membrane system and its operation. However, there is a big difference in that the hollow fiber membrane module separately performs a function of dropping the hollow fiber membrane 111a fitted into the module housing 110 by vibration. As described, if the impurities or solids are caught in the hollow fiber membrane (111a), the filtering operation is a problem, because the sample production is difficult, the hollow fiber membrane module of the present invention must be performed to remove the solids. However, in the method of spinning at high pressure through air as in the conventional method, DO, ORP, and highly volatile substances, which are affected by air or oxygen by air injection, are changed from the sample to the difference between the on-line analyzer analysis value and the actual raw material value. An error may occur.

 Therefore, in the present invention, the vibration device 130 is coupled to the hollow fiber membrane 111a to be shaken out through the vibration. Therefore, the method of using the conventional air and the method of back washing the sample may be used simultaneously with the vibrator 130 as in the present invention. No, it will be more noticeable in terms of its effectiveness.

4 and 6, the vibration device 130 is coupled to the disk-shaped fastening plate 120. And the fastening plate 120 is a state in which a plurality of membrane through-holes 121 are formed. Therefore, if the vibrator 130 starts to vibrate, the fastening plate 120 will be shaken, and the hollow fiber membrane 111a fitted to the fastening plate 120 is also shaken to shake off the floating material or solids stuck on the surface. To lose. At this time, the detailed configuration of the vibration device 130 as shown in Figure 6, the vibration device 130, there is a cylindrical motor case 131, the cam 133 eccentric to the shaft 132 is coupled There is a motor 134 is inserted into the motor case 131, there is a cover 137 having a stepped portion 136 is fitted into the opening 135 of both ends of the motor case 131. Therefore, they combine to generate vibration.

That is, the vibration device 130 of the present invention has a simple structure, in which a motor 134 including an eccentric cam 133 is inserted into the cylindrical motor case 131. The cover 137 is fastened to the openings 135 at both ends of the motor case 131, and the cover 137 forms a separate step 136 for a watertight action. Therefore, even if the motor case 131 is immersed in raw water and vibrates, water does not leak into the inside, so that the electrical connection of the motor 134 is not abnormal.

Of course, at this time, the motor 134 that can be used in the present invention, any one of the electric, air, or hydraulic motor 134 may be used. Not only a method of using electricity as its power or a method of transmitting rotational force using air, but also a motor 134 using hydraulic pressure may be used.

In addition, the present invention, in the hollow fiber membrane module structure, there is a sedimentation tank 141 coupled to the lower end of the module housing 110 is formed in a cylindrical shape, there is a discharge pipe 142 coupled to the lower portion of the sedimentation tank 141, There is a valve 143 coupled to one side of the discharge pipe 142. Therefore, they can combine to remove impurities in the module housing 110 through the opening and closing of the valve 143. That is, a plurality of impurities and solids stuck to the hollow fiber membrane 111a through the vibrator 130 are simply removed without a separate cleaning operation. A separate discharge pipe 142 is coupled to the settling tank 141 coupled to the lower end of the module housing 110, and the valve 143 is opened because a valve 143 is formed at one side of the discharge pipe 142. Most of the flow rate introduced into the module housing through the first pipe (reference numeral 21 in Fig. 1) is discharged to the upper drain line (83: 2nd pipe in Fig. 1) by the inlet pressure and some flow rate is settling tank 141 Along with the solid precipitated in the discharge pipe 142 is discharged.

When the valve 143 is opened, the raw water in the module housing 110 will come out, and in this process, impurities or solids shaken out through the vibration device will come out together.

In addition, in the hollow fiber membrane module structure, there is a utility supply pipe 152 inserted into the upper utility supply pipe holder 151 of the module housing 110 downward into the housing, the upper and lower linkage width at the end of the utility supply pipe 152 There is an upper and lower stopper (153, 153a) for controlling the, is inserted into the utility supply pipe 152 between the stopper (153, 153a), there is a cylindrical float 155 with a permanent magnet 154 built in the inner peripheral surface. In addition, there is a reed switch 152b formed in the center of the utility supply pipe 152 between the stoppers 153 and 153a. Therefore, when these are combined and the raw water rises inside the module housing 110, the float 155 rises according to the water level of the water, and the permanent magnet measures the level of the raw water by grounding the reed switch 152b. It is.

The utility supply pipe 152 fitted in the center of the utility supply pipe holder 151 of the module housing 110 is a long rod, as shown. And the end has an edge limiting the two movements, which is a stopper (153, 153a) formed at regular intervals. A separate ground part is formed in the float 155 sandwiched between the stoppers 153 and 153a. That is, the permanent magnet 154 is coupled to the inner peripheral surface of the cylindrical float 155 in a molded state. Therefore, as shown in FIG. 9, when the raw water is sucked through the pump, the level of the raw water rises to a certain level, and is interviewed with the end of the float 155 and floats with the rising of the raw water level by buoyancy. (155) is also rising. Of course, in the case of the float 155, since there are separate stoppers 153 and 153a at both upper and lower ends, the downward position and the upward position are limited.

In the present invention, the float 155 is characterized in that the raw water is accommodated in the interior of the module housing 110 and rises to a certain height, that is, the position of the lower stopper 153 and the water level is increased while interviewing the bottom surface of the float 155. Until it does nothing. Then, when the water level of the raw water further rises and the float value 155 that rises with the raw water due to the buoyancy of the float 155 comes near the center of the upper and lower stoppers 153 and 153a, the float 155 The magnetic force is generated in the permanent magnet 154 molded in the inside of the to pull the reed switch 152b provided in the inside of the utility supply pipe 152 to ground. Of course, the inner circumferential surface of the utility supply pipe 152 is electrically energized because the conductive material of the metal is coated or molded to operate the system of the present invention. That is, while the reed switch 152b is grounded with the inner circumferential surface of the utility supply pipe 152, the pump and the motor used in the present invention start the operation to operate the system. The operation of this system refers to the process of increasing the suction power of raw water, filtering as a measurable sample while flowing the raw water, and measuring the sample online.

Furthermore, when the raw water is pulled out and the float 155 is downward again due to gravity, the reed switch 152b is separated from the contact point and the operation of the system is stopped.

And the unexplained reference symbol a of FIG. 8 is polyurethane or epoxy, and b is a fastening plate.

1 is a view showing an operating state of a conventional hollow fiber membrane module system,

2 is a view showing a filtering state of a general hollow fiber membrane,

3 is a view showing a conventional method of washing a hollow fiber membrane,

Figure 4 is an exploded perspective view showing an exploded hollow fiber membrane module of the present invention,

5 is a view showing an online measurement process of the hollow fiber membrane module of the present invention,

6 is an exploded view illustrating the vibration device of the present invention;

7 is a view showing a method of raw water level measurement of the present invention,

8 is a cross-sectional view showing the hollow fiber membrane module of the present invention;

9 is a diagram illustrating a cutting of the water level measurement system of the present invention.

<Brief description of the major symbols in the drawing shown>

110; Module housing 111a; Hollow fiber membrane

120; Fastening plate 122; Joiner

130; Vibration device 131; Motor case

132; Shaft 133; cam

135; Opening 136; Step

137; Cover 141; Sedimentation tank

142; Discharge line 143; valve

151; Utility supply pipe holder 152; Utility supply pipe

153, 153a; Stopper 155; pontoon

Claims (5)

In the hollow fiber membrane unit structure, A plurality of hollow fiber membranes 111a installed in the module housing 110; A disk-shaped fastening plate 120 having a plurality of membrane through-holes 121 and a coupling hole 122 formed at a center thereof so as to be fitted into the long hollow fiber membrane 111a; Vibration device 130 is fitted in the coupling hole 122 of the fastening plate 120; The combination of the vibration of the vibration device 130 to shake the fastening plate 120 and the hollow fiber membrane (111a) to remove impurities trapped in the hollow fiber membrane (111a) hollow of the ultra-filtration system for on-line analyzers Desert module structure. The method of claim 1, The vibration device 130, A cylindrical motor case 131; A cam 133 eccentrically coupled to the shaft 132 and inserted into the motor case 131; A cover 137 having a stepped portion 136 fitted into the opening 135 at both ends of the motor case 131; Hollow fiber membrane module structure of the ultra-filtration system for on-line analyzer, characterized in that for generating vibration by coupling. The method of claim 2, The motor 134, Hollow fiber membrane module structure of the ultra-filtration system for on-line analyzer, characterized in that any one of the electric, air, hydraulic can be used. In the hollow fiber membrane module structure, A settling tank 141 coupled to the lower end of the module housing 110 formed in a cylindrical shape; A discharge pipe 142 coupled to a lower portion of the settling tank 141; A valve 143 coupled to one side of the discharge pipe 142; The hollow fiber membrane module structure of the ultra-filtration system for on-line analyzers, characterized in that by combining the opening and closing of the valve 143 to remove impurities in the module housing (110). In the hollow fiber membrane module structure, A utility supply pipe 152 inserted into the upper utility supply pipe holder 151 of the module housing 110 and lowered into the housing; Upper and lower stoppers 153 and 153a for controlling the interlocking width of the upper and lower ends of the utility supply pipe 152; A cylindrical float 155 inserted between the stopper 153 and 153a between the utility supply pipe 152 and having a permanent magnet 154 embedded therein; A reed switch 152b formed in the center of the utility supply pipe 152 between the stoppers 153 and 153a; When the raw water fills the inside of the module housing 110, the float 155 rises according to the water level of the water, and the permanent magnet measures the water level in such a manner as to ground the reed switch 152b. Hollow fiber membrane module structure of ultrafiltration system for on-line analyzer.

Images