JP2006204988A - Filter housing - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To promote filtration and defoaming of a filtrate by forming two or more bent parts in the upper end of the filter housing. <P>SOLUTION: A filter housing H comprises a cylindrical filter cartridge 1, a sleeve-shaped shell 2 housing the filter cartridge 1 in a standing state, a cover 5 fixed liquid-tightly at one end of the shell and/or integrated with the shell and a head 4 fixed liquid-tightly at the other end of the shell and having a liquid inlet port 4a and a liquid outlet port 4b and causes a filtrate to rise in the inside cavity of the filter cartridge 1 so as to be filtrated and defoamed. Bent parts 11a and 11b are formed respectively at a position of the cover 5 opposing the primary side of the filter cartridge 1 and at a position of the cover 5 opposing the secondary side of the filter cartridge 1. The cartridge sealing part 6 is engaged in the outer periphery of a sleeve-shaped post 10 standing at a position sufficiently separated in the vertical direction from the liquid outlet port 4b formed in the head 4, and the filter cartridge 1 is mounted on the cartridge sealing part 6 so as to be separated sufficiently from the liquid outlet port 4b. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a filter housing, and more particularly to a filter housing that facilitates defoaming and filtration from a filtered fluid (liquid).

  As shown in FIG. 4, in the conventional filter housing, a filter cartridge 21 functioning as a filter body formed in a cylindrical shape or a pleat shape in a shell 22 of an upright filter housing H ′ is sealed via a rod 23 as a cartridge seal. The nut 28 and the boss 31 are screwed onto the rod 23 at the upper and lower ends of the shell 22, and the upper and lower ends are sealed with the cover 25 and the head 24. A filtration space is formed. Here, the cover 25 and the head 24 are sealed in a liquid-tight manner at the upper and lower ends of the shell 22 via shell gaskets 27a and 27b. Furthermore, a liquid inlet port 24a and a liquid outlet port 24b are formed in the head 24 fixed to the lower end of the shell 22, and a drain valve 29 is attached to the bottom of the head 24 via a nipple 30 to the drain system. Communicate. On the other hand, a vent valve 32 is attached only to the secondary side of the cover 25 and the filter cartridge 21.

  In the conventional filter housing H ′ constructed as described above, the fluid to be filtered is introduced from the liquid inlet port 24a of the head 24 fixed to the lower end of the shell 22 as shown by the arrow in FIG. While the space formed between the inner wall of the shell 22 and the outer periphery of the filter cartridge 21 is raised, the filter element of the filter cartridge 21 is filtered through the radial direction thereof. The filtered fluid flows into a space formed between the circumference of the filter cartridge 21 and the rod 23, flows down the space as indicated by an arrow, and is discharged from the liquid outlet port 24b to a predetermined location. It is like that.

  Here, gas (bubbles) such as air accumulated between the upper end of the filter cartridge 21 and the cover 25 is exhausted out of the filter housing H ′ from the vent valve 32 provided in the cover 25 and, if necessary, Liquid is drained out of the filter housing H ′ by using a drain valve 29 of the head 24 provided at the lower end of the shell 22.

  Moreover, the filtration apparatus which reduces the bubble in liquid (for example, coating liquid) was also proposed (patent document 1).

However, in such a conventional filter housing H ′, the main purpose is to remove foreign substances from the liquid or gas to be filtered. Therefore, the outlet 25a of the gas generated in the filter housing H ′ is the primary filter. It was installed only on the side (outside of the filter cartridge 21). For this reason, when such a filter housing H ′ is used to remove bubbles from the liquid, the gas stored inside the filter cartridge 21 (corresponding to the primary side in the case of removing bubbles) is provided with a discharge port. Therefore, there is a problem that it flows out to the secondary side of the filter cartridge 21 and is mixed into the already filtered liquid. Further, since the cartridge seal portion 26 on which the filter cartridge 21 is placed is provided close to the liquid outlet port 24b side, the rise of bubbles is hindered.
JP 2004-49954 A

  The problem to be solved by the present invention is that in a filter housing used for filtering a liquid (for example, coating liquid), the efficiency of defoaming from the liquid is reduced, and bubbles already removed from the liquid are filtered into the filtered liquid. It is mixing.

  The present invention includes a tubular filter cartridge, a sleeve-like shell for standing and housing the tubular filter cartridge, a cover that is liquid-tightly fixed to one end of the shell or integrated with the shell, In a filter housing comprising a liquid inlet port and a head having a liquid outlet port that are liquid-tightly fixed to the other end of the shell, and wherein the filtered liquid rises in the lumen of the cylindrical filter cartridge and is filtered and degassed. A sleeve-like sleeve provided with a vent portion at a position facing the primary side and the secondary side of the cylindrical filter cartridge of the cover, and erected at a position sufficiently away from the liquid outlet port formed in the head in the vertical direction. The present invention relates to a filter housing in which a cartridge seal portion is fitted on the outer periphery of a post.

  The filter housing of the present invention can dramatically improve the defoaming efficiency from the filtered liquid and drastically prevent the bubbles removed from the liquid from being mixed into the filtered liquid.

Configuration of Filter Housing As shown in FIG. 1 attached, the filter housing H of the present invention is a cylindrical one or a plurality of cylinders that function as a filter body that is erected and accommodated in a erected sleeve-like shell 2. Filter cartridge 1. The filter cartridge 1 is attached via a cartridge seal portion 6 to a rod 3 whose lower end is screwed to a boss 13 attached to a head 4 fixed in a liquid-tight manner to a lower end of a shell 2 via a shell gasket 7a. ing. Specifically, the filter cartridge 1 has a structure in which air bubbles escape from the inner side (primary side) to the outer side (secondary side). Further, the outer periphery of the post 10 having a sufficient length in the form of a sleeve erected at the center of the head 4 and sufficiently separated from the liquid outlet port 4b (for example, about 50 mm or more, depending on the properties of the liquid, The cartridge seal portion 6 fitted into the lower portion may be fitted, and the filter cartridge 1 may be placed thereon, and filtered between the outer circumference of the rod 3 and the inner circumference of the sleeve-like post 10. A liquid flow path S ₁ is formed.

  Here, the sleeve-like post 10 is configured to be sufficiently long so that the liquid flowing into the filter cartridge 1 is short-cut and does not flow out to the liquid outlet port 4b, and the liquid is evenly distributed to the upper end of the filter cartridge 1. It is made to flow.

  Further, a cover 5 is fixed in a liquid-tight manner to the upper end portion of the shell 2 via a shell gasket 7 b (may be integrated with the shell 2), and is an upper end portion of the filter cartridge 1 inside the filter cartridge 1. A concave vent portion is provided at a corresponding position (center portion of the shell 2), and a vent valve 11a is connected to a nut 8 screwed into the cover 5 via a nipple 9.

  Further, an annular groove 5 a is formed in the cover 5 corresponding to the outer side of the upper end portion of the filter cartridge 1, and a nipple 12 in which the bottom of the groove 5 a is screwed into the top surface of the cover 5 is provided. Via the vent valve 11b.

  Therefore, in the filter housing H of the present invention, the bubbles degassed from the liquid from the two vent valves 11a (the bubbles inside the filter cartridge 1) and 11b (the bubbles outside the filter cartridge 1) are removed from the filter housing H. Exhausted.

Here, the liquid flow path S ₂ to be filtered between the circumferential portion of the filter cartridge 1 and the outer peripheral portion of the rod 3 is filtered between the outer peripheral portion of the filter cartridge 1 and the inner wall of the shell 2. A liquid flow path S ₃ is formed. Furthermore, a sufficient space 2a is formed between the lower end surface of the filter cartridge 1 placed on the cartridge seal portion 6 and the outflow hole 4c of the liquid outlet port 4b.

  Further, a head 4 is fixed to the lower end of the shell 2 via a shell gasket 7a in a liquid-tight manner or integrally formed. The head 4 includes a liquid inlet port 4a, a liquid outlet port 4b, Are formed at the same level horizontally or with a step. Furthermore, a drain valve 14 is provided through a nipple 15 screwed into the head 4 so as to communicate with the inlet of the liquid outlet port 4b. If necessary, the drain valve 14 is opened to allow the liquid in the shell 2 to flow. It can be discharged out of the shell 2.

  Further, since the filter housing H of the present invention is configured so that the shell 2, the head 4, the rod 3, or the cover 5 can be disassembled, it is easy to disassemble and clean them.

When the thus configured filter housing H of the present invention is used for, for example, filtration of a photosensitive solution applied to a photosensitive drum or filtration of a coating solution to photosensitive paper, as shown in FIG. Alternatively, they are arranged in a circulating manner. That is, as shown in FIG. 2, formulated from the upstream side tank T _1, the filter housing H of the present invention, arranged in the order of particulate removal filter F (may not be used) and tank T _2, in mixing tank T ₁ The raw material is mixed to produce a photosensitive solution, the photosensitive solution is filtered and defoamed with the filter housing H of the present invention, and further filtered with a filter F for removing fine particles, and then the filtered liquid (photosensitive solution) is stored in the tank T ₂ Store in. Here, it may be returned from the filter housing H for Filtered liquid blending tank T _1.

Method of Using (Operating) Filter Housing To use the filter housing of the present invention having such a configuration, first, when the filter housing H is used, for example, for defoaming a photosensitive solution as a filtrate, for example, FIG. 2, the filtered liquid is introduced from the liquid inlet port 4a provided at the lower end of the filter housing H shown in FIG. The introduced filtered liquid rises so as to flow from the inside to the outside of the filter cartridge 1 in the space S ₁ formed between the rod 3 erected so as to communicate with the liquid inlet port 4a and the post 10, It flows into a space (filtration space) S ₂ formed between the filter cartridge 1 fitted in the post 10 and the rod 3. Here, the filtered liquid flows from the radial direction into the filter cartridge 1 while rising in the space S ₂ , as indicated by the arrows, and passes through the filter medium to filter and remove the filtered liquid. Bubbles are generated and flow out to the secondary side.

  In particular, in the case of removing bubbles from the liquid, the primary side and the secondary side of the filter cartridge 1 are reversed, unlike general foreign matter removal. That is, the inside of the filter cartridge 1 becomes the primary side, and the liquid enters and rises from the lower part of the filter cartridge 1, flows from the primary side of the filter medium to the secondary side, and descends outside the filter cartridge 1 (secondary side). It heads for the liquid outlet 4b of the head 4.

Next, the filtered and defoamed liquid (for example, a photosensitive solution) flows down in the space S ₃ formed between the outer peripheral portion of the filter cartridge 1 and the shell 2, and passes through the space 2 a from the liquid outlet port 4 b. It is discharged out of the filter housing H (sent to the filter F for removing fine particles in the photosensitive liquid filtration and defoaming line shown in FIG. 2).

  On the other hand, the gas degassed from the filtered liquid is an annular or other shaped space 5 a in the cover 5 provided at a position corresponding to the upper end of the filter cartridge 1 and a vent space 8 a provided in the center of the cover 5. And the vent valves 11a and 11b are opened to exhaust the filter housing H.

In particular, in the filter housing H of the present invention, the cartridge seal portion 6 on which the filter cartridge 1 is placed is configured to form a space 2a therebetween at a position sufficiently separated from the outflow hole 4c of the liquid outlet port 4b. Has been. Bubbles to be from the secondary side of the filter cartridge 1 (the space S ₃ and space 2a) floating may try to move conveyed to the flow of liquid to the liquid outlet 4b of the filter housing H. At this time, when the flow rate of the liquid on the outside (secondary side) of the filter cartridge 1 is higher than the speed at which the bubbles float, the bubbles are discharged from the liquid outlet 4b together with the liquid flowing downward of the filter cartridge 1. .

  Here, when the liquid flow rate is constant, the flow rate of the liquid outside the filter cartridge 1 is the cross-sectional area as a flow path obtained by subtracting the outer diameter cross-sectional area of the filter cartridge 1 from the inner diameter cross-sectional area of the shell 2 of the housing. Determined by.

Here, for example, when the inner diameter of the shell 2 is 85 mm and the outer diameter of the filter cartridge 1 is 66 mm, the cross-sectional area is
((85/2) ² × 3.14) − ((66/2) ² × 3.14) = 2250 (mm ² )
It becomes.

On the other hand, when the cartridge seal portion 6 is sufficiently separated from the liquid outlet 4b (for example, 50 mm or more), the cross-sectional area further below the lower end of the filter cartridge 1 has an inner diameter of the shell 2 of 85 mm and an outer diameter of the post 10. If it is 27mm,
((85/2) ² × 3.14) − ((27/2) ² × 3.14) = 5100 (mm ² )
Thus, the cross-sectional area is about 2.3 times that of the former. Since the flow rate of the liquid is proportional to the cross-sectional area of the flow path, the lower part of the filter cartridge 1 is about 44% of the outer portion, and the bubbles can be easily floated, and the bubbles in the space 2a shown in FIG. it is possible to gain time to emerge in the space S ₂ and.

  In addition, a general filter cartridge has a coarse opening on the inlet side (“primary side”) and a fine opening on the outlet side (“secondary side”), and has a certain particle size distribution in the liquid. It intends to capture a group of particles (particles to be removed) in stages from large particles to small particles.

  As shown in FIG. 3, bubbles are removed from the liquid by capturing bubbles on the surface of the filter cartridge and causing fine bubbles not captured on the surface to collide and adhere to the fibers (filter medium) constituting the filter cartridge. It is carried out by two mechanisms: coalesced and grown by the surface tension to form a large bubble mass and then float and separate. When the opening on the primary side of the filter cartridge is smaller than the secondary side, the removal rate of bubbles due to collision and adhesion of the liquid to the filter medium on the surface of the filter cartridge is improved, and the secondary side from the primary side inside the filter medium. Bubbles are effectively combined and grown along the openings that increase toward the side, and the bubble removal rate is improved.

  In particular, the filter housing of the present invention is a fine material generated when a liquid having a high viscosity such as a photosensitive liquid or a coating liquid or a liquid having a low viscosity but containing a surfactant is applied and coated on a smooth surface. It is useful in the technical field that dislikes the uniformity of the surface of photosensitive paper or the like due to air bubbles.

The longitudinal cross-sectional view of the filter housing of this invention. The piping diagram at the time of using the filter housing of this invention for defoaming and filtration of a photosensitive solution. The conceptual diagram which shows the principle of the defoaming and filtration from the liquid by the filter housing of this invention. The longitudinal cross-sectional view of the conventional filter housing.

Explanation of symbols

H Filter housing 1 Filter cartridge (filter material)
2 Shell 3 Rod 4 Head 4a Liquid inlet port 4b Liquid outlet port 5 Cover 6 Cartridge seal part 7a, 7b Shell gasket 8 Nut 9 Nipple 10 Post 11a, 11b Vent valve 12 Nipple 13 Boss 14 Drain valve 15 Nipple

Claims (6)

  A tubular filter cartridge, a sleeve-like shell for standing and housing the tubular filter cartridge, a cover that is liquid-tightly fixed to one end of the shell or formed integrally with the shell, A filter housing comprising a liquid inlet port and a head having a liquid outlet port that are liquid-tightly fixed to the other end, and wherein the filtered liquid rises in the lumen of the cylindrical filter cartridge and is filtered and degassed. A filter housing, wherein vent portions are respectively provided at positions facing the primary side and the secondary side of the cylindrical filter cartridge.   A tubular filter cartridge, a sleeve-like shell for standing and housing the tubular filter cartridge, a cover that is liquid-tightly fixed to one end of the shell or formed integrally with the shell, A filter housing that is liquid-tightly fixed to the other end and has a liquid inlet port and a liquid outlet port, wherein the filtered liquid is filtered and degassed by rising the lumen of the filter cartridge; The cartridge seal portion is fitted on the outer periphery of the standing sleeve-like post at a position sufficiently away from the liquid outlet port formed in the above, and the filter cartridge is placed on the cartridge seal portion. Filter housing.   The vent portion is formed as a recess in the cover corresponding to the upper end portion of the rod erected on the head, and as a groove portion at a position corresponding to the upper end of the filter cartridge and corresponding to the secondary side. The filter housing according to claim 1.   The filter housing according to claim 1, wherein the filter cartridge, the shell, and the head or the cover are configured to be disassembled.   The filter housing according to claim 1, wherein the filtration liquid is a high-viscosity or low-viscosity liquid, and is used for filtering and defoaming the high-viscosity or low-viscosity liquid. The filter housing according to claim 1, wherein the highly viscous liquid is a photosensitive solution or a coating solution, and fine bubbles generated during coating and coating are removed in advance.

Images