KR20200088136A - Separator using spiral tube - Google Patents

Abstract

The present invention relates to a separation membrane using a spiral tube, comprising: a housing including an inlet port through which an inlet line communicates at a lower end, an outlet port through which a discharge line communicates at an upper end, a chamber formed at an upper end, a plurality of perforations, and a partition wall mounted to enable rotational interlocking; and a plurality of spiral tubes connected to allow each of perforations to be in communication with the lower surface of the housing and each hollow for the partition wall in a shape in which the hollow is formed while elastic line members are spirally stacked.

Description

Separator using spiral tube

The present invention relates to a separator having excellent treatment efficiency as well as excellent backwashing efficiency and durability using a structure such as a spiral tube having elasticity.

In general, a treatment technology using a separation membrane is widely used for water treatment of wastewater, wastewater, purified water, and gas treatment of harmful gases.

In the above, the membrane is a liquid or solid membrane capable of separating a mixture by selectively passing a specific component, and is also referred to as a membrane, an osmosis membrane, or a semi-permeable membrane, and cellulose. There are also various types of acetate separators, polymer separators, ceramic separators, and metal separators.

On the other hand, the separation membrane as described above is effective for desalination of seawater, water purification, sewage treatment, wastewater treatment, and separation of raw materials in the food industry. Production of ultrapure water used for concentration, boiler and semiconductor cleaning processes, and effective in wastewater. Applications such as material recovery and recycling technologies are diversifying.

As a related art related to the separator, in Korean Patent Registration No. 10-1031673, a raw water tank temporarily storing a large amount of raw water; A raw water moving pipe which is connected to a raw water outlet installed on one side of the raw water tank and forms a flow path such that raw water discharged from the raw water tank flows back into the raw water tank through the raw water inlet provided in the raw water tank; A hollow cylindrical separation membrane module provided with one or two or more on the path of the raw water moving pipe and having a filter part detachably disposed therein to purify raw water supplied through the raw water moving pipe; A hollow cylindrical one-sided open membrane module connection unit installed between the separator module and the raw water moving tube and through which raw water supplied through the raw water moving tube flows; A hollow cylindrical two-sided open membrane module connector provided between the separator modules and through which the raw water supplied through the raw water moving tube flows; A treatment water transfer tube provided to be connected to a side of the one or both open membrane module connecting portions and through which the purified water passing through the filter unit installed in the membrane module flows; And a treated water tank for temporarily storing purified water flowing through the treated water moving pipe.

However, in the case of the above-described technology, when constructing the separation membrane module, if a plurality of hollow fiber membranes have fixed top and bottom ends, foreign matter or the like is deposited between the hollow fiber membranes during the filtration process, a problem may occur in the hollow fiber membrane, such as deformation or damage. .

Republic of Korea Patent Registration No. 10-1031673

Accordingly, in order to solve the above problems, in the present invention, even in the case of depositing foreign substances in the filtration process due to a structure such as imparting elasticity to a plurality of unit pipes forming a separation membrane, by automatically removing foreign substances through elastic restoring force, etc. It is intended to provide a separator having excellent treatment efficiency as well as excellent durability.

The separation membrane using the spiral tube of the present invention (hereinafter referred to as "the separation membrane of the present invention") for achieving the above object, an inlet port through which an inlet line communicates at the bottom, an outlet through which an outlet line communicates at the top, and a chamber at the top A housing including a partition wall in which a plurality of perforations are formed and mounted to enable rotational movement; It characterized in that it comprises; a plurality of spiral pipes are connected so that the hollow is in communication with each other in the lower surface of the housing and the partition wall in the shape of the hollow formed inside while the elastic wire member is laminated in a spiral .

As an example, a pressure sensor module composed of a plurality of pressure sensors is configured on a side surface of the housing to detect whether the inside of the housing is blocked by a pressure difference between the pressure sensors.

In one example, the discharge line is characterized in that the backwashing injection line is connected by a valve.

As an example, a plurality of wings protrude from a surface of the partition wall that is in contact with the chamber, and the partition wall is rotated according to the supply of backwash water in the backwash water injection line.

As an example, the spiral tube is composed of an outer tube and an inner tube that each hollow elastic member is formed while being stacked in a spiral, and the wire member constituting the inner tube is more charged than the wire member constituting the outer tube. It is characterized by being made of this high material.

The separation membrane of the present invention as described above has an advantage of excellent treatment efficiency as well as excellent backwashing efficiency due to the fixed structure of a spiral tube having elasticity and a spiral tube to enable rotation, and has excellent durability by resilience.

1 is a side cross-sectional view showing a basic example of the present invention,
Figure 2 is a perspective view showing a spiral tube in one configuration of the present invention,
3 is a plan view showing a partition wall in one configuration of the present invention,
Figure 4 is a cut-away cross-sectional view showing a state in which the spiral tube is a configuration of the present invention,
5 is an operational state diagram of a spiral tube that is one configuration of the present invention,
Figure 6 is a side cross-sectional view showing an embodiment of a spiral tube that is one configuration of the present invention,
7 is an operational state diagram of an embodiment of the present invention,
8 is a schematic diagram of another embodiment of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as a meaning and concept consistent with the technical idea of.

The separation membrane 1 of the present invention, as shown in FIG. 1, etc., the inlet 22 through which the inlet line 6 communicates at the bottom, the outlet 21 through which the outlet line 4 communicates at the top, and a chamber at the top ( 23) is formed and a plurality of perforations (241) is formed and the housing (2) including a partition wall (24) is mounted to enable rotational movement; The hollow member 32 is formed in a spiral shape while the elastic wire member 31 is formed inside, and the hollow 32 is formed in each of the perforations 241 in the lower surface of the housing 2 and the partition wall 24. It is characterized in that it comprises a; a plurality of spiral pipes (3) are connected to communicate.

The housing 2 has an inlet 22 through which the inlet line 6 communicates with the bottom, so that the fluid to be treated flows into the housing 2 through the inlet line 6 and the inlet 22. Is to do.

The fluid to be treated in this way is to be discharged to the outside through the discharge mechanism 21 and the discharge line 4 at the top of the treatment fluid filtered foreign matter through the operation mechanism shown below.

In particular, the housing 2 is mounted so that the partition wall 24 is rotatable at an upper end so that the chamber 23 is formed on the partition wall 24.

The reason why the partition wall 24 in the housing 2 is mounted to enable rotational interlocking is when an obstruction or the like occurs during the filtration process of the spiral tube 3, in the case of depositing foreign substances between the spiral tubes 3, etc. It is to prevent deformation and destruction of the spiral tube 3 by making one end of the spiral tube 3 a free end.

For example, when foreign matter is deposited between the spiral pipes 3, the foreign substances are automatically detached by rotation of the partition walls 24, and the partition walls 24 are restored to the original position by the restoring force of the spiral pipes 3 It is to prevent deformation and destruction of the spiral tube 3 as mentioned above.

The structure in which the partition wall 24 is mounted to be rotatable in the housing 2 can be implemented by various known techniques such as ball bearings, and thus detailed description thereof will be omitted.

A plurality of perforations 241 are formed in the partition wall 24, and as shown in FIG. 4, the spiral tube 3 is fixed to the partition wall 24, but the hollow 32 communicates with the perforation 241. Is fixed. As shown in FIG. 5, the fluid that has been filtered as described above is mounted on the hollow 32 of the spiral tube 3 and stored upward in the chamber 23 to be discharged to the outlet 21.

The spiral tube 3 has a shape in which a hollow member 32 is formed in a spiral shape, and a hollow 32 is formed therein, so that each perforation is formed on the lower surface of the housing 2 and the partition wall 24. 241) corresponds to a configuration in which the hollow 32 is connected to communicate.

The spiral tube 3 is a structure in which the elastic wire members 31 are spirally stacked, and naturally has an elastic restoring force as it has a spring-like structure. Due to this structure, as shown in FIG. 5, the fluid to be treated flowing into the inlet 22 passes between pitches of each wire member 31 so that foreign matter is filtered and the fluid filtered with foreign matter is the hollow 32. Riding upwards.

As mentioned above, when the elastic restoring force of the spiral tube 3 and the rotational movement of the partition wall 24 are interlocked organically, uneven pressure such as deposition of foreign substances is formed, so that desorption of foreign substances is automatically performed. It is to make the restoration possible.

The material of the wire member 31 constituting the spiral tube 3 should have elasticity and rust resistance, and the material is not particularly limited, but anti-corrosion-treated iron wire may be applied.

In addition, in FIG. 6, one embodiment of the spiral tube 3 is shown, and the spiral tube 3 of the present embodiment has an outer surface in which hollow members are formed while the elastic wire members 31a and 31b are spirally stacked, respectively. An example consisting of 3a) and an inner tube 3b is shown.

Particularly, in this embodiment, the line member 31b constituting the inner tube 3b is made of a material having a higher charging sequence than the line member 31a constituting the exterior 3a.

In this way, as the exterior 3a and the inner tube 3b are brought into contact with each other, static electricity is generated by causing friction between the exterior 3a and the inner tube 3b in a filtration process or the like. When static electricity is generated in this way, the inner tube 3b is charged with a positive (+) charge, and the exterior 3a is a wire member 31b constituting the inner tube 3b to be charged with a negative (-) charge. Is to be made of a material having a higher charging sequence than the wire member 31a constituting the exterior 3a.

It is intended to prevent foreign substances from flowing into the hollow 32 by allowing foreign substances to be adsorbed by static electricity mainly in the external appearance 3a. That is, the foreign matter is adsorbed by the outer surface 3a forming the outer surface, thereby increasing the processing efficiency by controlling the inflow of the foreign material to the inner tube 3b as much as possible.

In general, in the case of foreign matter such as dust, it has a positive (+) charge, so in order to adsorb foreign matter having such a positive (+) charge, the external appearance (3a) is a negative (-) charge due to friction with the inner tube (3b). As it should be charged, in order for the external appearance 3a to be charged with a negative (-) charge by frictional electrification, the inner tube 3b must be made of a material having a higher charging sequence than the external appearance 3a.

For example, the wire member 31b constituting the inner tube 3b is made of iron and the wire member 31a constituting the exterior 3a is made of a rubber material having a lower charging sequence than the iron material.

In addition, the present invention proposes another embodiment in FIG. 8. In this embodiment, the basic example and other configurations shown in FIG. 1 are the same, but in this embodiment, the pressure sensor module 7 and the control unit 8 are What makes it more configurable is different.

The pressure sensor module 7 is composed of a plurality of pressure sensors (71, 72, 73, 74) on the side of the housing (2). In FIG. 8, four pressure sensors are provided in four directions. Bar, the number is optional.

The pressure sensor module 7 may detect a pressure difference between pressure sensors during a processing process to detect whether an occlusion occurs inside.

For example, when the pressure value sensed by one pressure sensor 71 is significantly smaller or larger than other pressure sensors 72, 73, and 74, a problem such as occlusion or breakage occurs in a portion where the pressure sensor 71 is located. There is a sense that the non-uniform treatment is performed.

When the occlusion or the like is detected as described above, the backwashing process described below is performed. That is, if it is determined that the control unit 8 is abnormal through the pressure value, it is determined that the washing process is started by operating the backwashing injection line 5 as shown in FIG. 1.

The backwash water injection line 5 is connected to the discharge line 4 by a valve so that the backwash water flows into the upper portion of the housing 2 through the outlet 21.

In particular, in the case of the present invention, in order to increase the backwashing efficiency, the embodiment shown in FIG. 7 is presented.

In this embodiment, a plurality of wings 242 protrude from a surface of the partition wall 24 in contact with the chamber 23.

With this configuration, when backwash water flows into the chamber 23 through the backwash water injection line 5, the backwash water hits the wing 242. In this process, as shown in FIG. 7, the partition wall 24 is rotated, and the spiral tube 3 is elongated according to this rotation.

The extension of the spiral tube 3 increases the pitch (P) interval between the line members 31 constituting the spiral tube 3 and the foreign matter deposited between the line members 31 by backwashing water flowing through the hollow 32 (S) is detached from the spiral tube (3). When the backwashing process is finished or the backwashing water is periodically injected, the partition wall 24 and the spiral tube 3 are restored to their original positions by the elastic restoring force of the spiral tube 3.

The present invention as described above has been described with reference to one embodiment shown in the drawings, but this is only an example, and a person having ordinary knowledge in the art can perform various modifications and other equivalent embodiments therefrom. Will understand Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims.

1: separation membrane 2: housing
3: Spiral tube 4: Discharge line
5: backwashing injection line 6: inflow line
7: Pressure sensor module

Claims (5)

A housing including an inlet port through which the inlet line communicates with the lower end, an outlet through which the discharge line communicates with the upper end, and a partition wall on which the chamber is formed on the upper end and a plurality of perforations are formed and mounted to enable rotational movement;
A plurality of spiral tubes connected to each other through the perforations in the lower surface of the housing and the partition wall in a shape in which hollow lines are formed inside while the elastic wire members are spirally stacked;
Separation membrane using a spiral tube, characterized in that it comprises a.
According to claim 1,
A separation membrane using a spiral tube characterized in that a pressure sensor module composed of a plurality of pressure sensors is configured on a side surface of the housing to detect whether the inside of the housing is blocked by a pressure difference between the pressure sensors.
According to claim 1,
A separator using a spiral tube, characterized in that a backwashing water injection line is connected to the discharge line by a valve.
According to claim 3,
A separation membrane using a spiral tube characterized in that a plurality of wings protrude from a surface of the partition wall in contact with the chamber, so that the partition wall rotates according to the supply of backwash water from the backwash water injection line.
According to claim 1,
The spiral tube is composed of an outer tube and an inner tube that each hollow elastic member is formed while being stacked in a spiral, and the wire member constituting the inner tube has a higher charging sequence than the linear member constituting the outer tube. The separation membrane using a spiral tube, characterized in that consisting of.

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