WO2021106909A1

WO2021106909A1 - Assembly-type reduced-pressure filtration device

Info

Publication number: WO2021106909A1
Application number: PCT/JP2020/043757
Authority: WO
Inventors: 隆司金城
Original assignee: 株式会社ロキテクノ
Priority date: 2019-11-26
Filing date: 2020-11-25
Publication date: 2021-06-03
Also published as: TW202126372A; TWI754467B; JP2021084054A; JP7353941B2

Abstract

There are demands for an assembly-type reduced-pressure filtration device with which assembly and changes to the configuration can be achieved using a simple structure, and with which a hermetically sealed state can be guaranteed. This demand can be satisfied by means of an assembly-type reduced-pressure filtration device provided with a pump unit, a pre-filtration liquid reservoir unit, and a post-filtration liquid reservoir unit, wherein the pump unit, the pre-filtration liquid reservoir unit, and the post-filtration liquid reservoir unit each include a coupling unit comprising a flange having a first flange shape, a flange having a second flange shape, and a coupling seal member.

Description

Assembled decompression filtration device

The present invention relates to a filtration device, and more particularly to an assembly type decompression type filtration device.

In the filtration of liquids, a pressurizing type filtration device is generally used in which the back pressure of the liquid is increased by a pressurizing means to cause the liquid to flow, and the liquid is passed through a filter to perform filtration. In such a filtration device, a flow circuit through which a liquid flows is generally composed of a pipeline. On the other hand, as disclosed in Patent Document 1, for example, the internal pressure of the container for storing the filtered liquid which is the liquid after filtration is reduced, and the liquid is passed through the filter when being sucked into the container. There is a decompression type filtration device that performs filtration. Such an apparatus generally includes a container for containing a liquid to be filtered, a container for storing the filtered liquid after filtration, and a means for reducing the pressure in the container for storing the filtered liquid.

Patent Document 1 discloses a filtration system in which filtration is performed through a sample filter arranged between a sample container and a filtrate storage bottle, and the filtered filtrate is introduced into the filtrate storage bottle. ing. Generally, a decompression type filtration device has a relatively compact structure because it executes filtration at a low differential pressure of atmospheric pressure or less.

International Publication No. WO2008 / 52642 Pamphlet

Due to the compact structure of conventional decompression filtration devices, the capacity of the container that holds the liquid to be filtered and the capacity of the container that stores the filtered liquid after filtration are relatively small and do not necessarily match the amount of liquid to be filtered. There is. Therefore, it is convenient if the decompression type filtration device can be easily configured according to the amount of the liquid to be filtered, and an assembly type decompression type filtration device is desired.
On the other hand, since it is preferable that the assembly type decompression type filtration device has a simple configuration, it is necessary to increase the degree of sealing of the assembled joint portion, and the assembly type decompression that can be easily assembled or changed while guaranteeing a high degree of sealing. A type filtration device is desired.

A tubular pump unit housing extending so as to have a hollow inside and a central axis, a degassing pump is arranged inside the pump unit housing, and an intake hole of the degassing pump is provided on one end side of the pump unit housing. It has a pump unit and a tubular pre-filter liquid reservoir unit housing that has a filter member arranged at one end, an opening at the other end, and is hollow and extends so as to have a central axis, and performs filtration inside the pump unit. A pre-filtration liquid reservoir unit that can inject liquid from the other end and store the pre-filtration liquid inside, and a tubular after filtration that has openings at both ends and is hollow so that the inside has a central axis. A post-filtered liquid reservoir unit having a liquid reservoir unit housing and having an isolation member that divides the inside of the post-filtered liquid reservoir unit housing into a storage chamber and an exhaust chamber, and the pre-filtered liquid is placed in the storage chamber. A post-filtered liquid reservoir unit capable of storing the filtered post-filtered liquid, a first coupling unit that binds the pump unit housing and the post-filtered reservoir unit housing, the post-filtered liquid reservoir unit housing, and the pre-filtering liquid reservoir unit housing. This is solved by a prefabricated vacuum filter equipped with a second coupling unit that couples the liquid reservoir unit housing.

A tubular pump unit housing extending so as to have a hollow inside and a central axis, a degassing pump is arranged inside the pump unit housing, and an intake hole of the degassing pump is provided on one end side of the pump unit housing. It has a pump unit and a tubular pre-filter liquid reservoir unit housing that has a filter member arranged at one end, an opening at the other end, and is hollow and extends so as to have a central axis, and performs filtration inside the pump unit. A plurality of pre-filtration liquid reservoir units capable of injecting liquid from the other end and storing the pre-filtration liquid inside, and a tubular shape having openings at both ends and hollow inside so as to have a central axis. A post-filtered liquid reservoir unit having a post-filtered liquid reservoir unit housing and having an isolation member that divides the inside of the post-filtered liquid reservoir unit housing into a storage chamber and an exhaust chamber, and the pre-filtering liquid reservoir unit in the storage chamber. A plurality of post-filter liquid reservoir units capable of storing the filtered liquid, and a plurality of binding seals connecting the plurality of pre-filter liquid reservoir unit housings and the plurality of post-filter liquid reservoir unit housings, respectively. An assembly-type decompression filtration device including a member, wherein each of the plurality of post-filtered liquid reservoir unit housings is located at an end portion of each of the plurality of post-filtered liquid reservoir unit housings on the side of the exhaust chamber. A flange in the form of a first flange extending in a direction perpendicular to the central axis of each of the post-filtered liquid reservoir unit housings, and the end of each of the plurality of post-filtered liquid reservoir unit housings on the side of the storage chamber. Each of the plurality of pre-filtration liquid reservoir unit housings includes a second flange-shaped flange extending in a direction perpendicular to the central axis of the post-filtration liquid reservoir unit housing, and each of the plurality of pre-filtration liquid reservoir unit housings of the plurality of pre-filtration liquid reservoir unit housings. A flange in the form of a first flange extending in a direction perpendicular to the central axis of the pre-filtration liquid reservoir unit housing at one end thereof, and a center of the pre-filtration liquid reservoir unit housing at an end opposite to the one end. A second flange-shaped flange extending in a direction perpendicular to the shaft is provided, and a second flange-shaped flange extending in a direction perpendicular to the central axis of the pump unit housing is provided at one end of the pump unit. The first flange form has a conical trapezoidal shape having a slope that narrows downward in the vertical direction, and the second flange form has a slope that narrows upward in the vertical direction. Each of the plurality of coupling seal members has a conical trapezoidal shape, and each of the plurality of coupling seal members has a cylindrical wall surface and a tab extending in the radial direction of the cylinder over the entire inner surface of the wall surface at substantially the center of the inner surface of the wall surface. The tab can be arranged on the flange of the second flange form so as to be sandwiched between the flange of the first flange form and the flange of the second flange form. It can be fitted to the flange of the first flange form so as to wrap around the flange of the first flange form, whereby the pump unit housing, each of the plurality of pre-filtration liquid reservoir unit housings, and the plurality of The solution is to use an assembly-type decompression type filtration device that can be combined with each of the post-filter liquid reservoir unit housings.

According to the present invention, an assembled decompression type filtration device that can be assembled or changed in a simple structure and is guaranteed to be in a sealed state is realized.

The perspective view which showed the whole of the assembly type decompression type filtration apparatus which is an embodiment of this invention is shown. It is a perspective view which showed the separated state of the coupling unit of the assembly type decompression type filtration apparatus which is an embodiment of this invention. It is sectional drawing which showed the separated state of the coupling unit of the assembly type decompression type filtration apparatus which is an embodiment of this invention. It is sectional drawing which showed the coupling state of the coupling unit of the assembly type decompression type filtration apparatus which is an embodiment of this invention. It is a combined state cross section of the assembly type decompression type filtration apparatus which is an embodiment of this invention, and is the figure which showed the cross section 3-3 of FIG. It is a figure which showed the cross section 4-4 of FIG. It is sectional drawing of the separated state of the assembly type decompression type filtration apparatus of this invention. It is sectional drawing of the state in which the pre-filtration liquid reservoir which is a part of the structure of the assembly type decompression type filtration apparatus of this invention was additionally added. It is sectional drawing of the state which added the liquid reservoir after filtration which is a part of the structure of the assembly type decompression type filtration apparatus of this invention. It is a schematic diagram of the combination example which added the pre-filtration liquid reservoir and the post-filtration liquid reservoir in the assembly type decompression type filtration apparatus of this invention.

First, the assembled decompression type filtration device 1 (hereinafter, simply a filtration device) according to the embodiment of the present invention will be described with reference to FIGS. 1 to 5. FIG. 1 is a perspective view of the combined state of the filtration device 1. FIG. 2A is a perspective view showing a separated state of the coupling unit 5 of the filtration device 1, and FIG. 2B is a cross-sectional view thereof. FIG. 2C is a cross-sectional view showing the coupling state of the coupling unit 5 of the filtration device 1. FIG. 3 is a cross-sectional view of the combined state of the filtration device 1. FIG. 4 is a view showing a cross section 4-4 of FIG. 3, which is a cross section of the filtration device 1 as viewed from the stop axis direction. FIG. 5 is a cross-sectional view of the filtration device 1 in a separated state.

The filtration device 1 includes a pump unit 11, a post-filtration liquid reservoir unit 12, and a pre-filtration liquid reservoir unit 13. Here, in the present specification, the liquid to be filtered is referred to as "pre-filtration liquid", and the liquid obtained by filtering the pre-filtration liquid is referred to as "post-filtration liquid". The pre-filtration liquid reservoir unit 13 can be configured to be located above the post-filtration liquid reservoir unit 12, and the post-filtration liquid reservoir unit 12 can be configured to be located above the pump unit 11. The pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 include a pump unit housing 111, a post-filtration liquid reservoir unit housing 121, and a pre-filtration liquid reservoir unit housing 131, respectively. The pump unit housing 111 of the pump unit 11, the post-filtration liquid reservoir unit housing 121 of the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit housing 131 of the pre-filtration liquid reservoir unit 13 are hollow cylindrical housings. And have a common diameter.

A coupling unit 5 is arranged between the pre-filtration liquid reservoir unit 13 and the post-filtration liquid reservoir unit 12, and a coupling unit 5 is arranged between the post-filtration liquid reservoir unit 12 and the pump unit 11. The coupling unit 5 between the pre-filtration liquid reservoir unit 13 and the post-filtration liquid reservoir unit 12 and the coupling unit 5 between the post-filtration liquid reservoir unit 12 and the pump unit 11 have a common form. First, the coupling unit 5 will be described here. The coupling unit includes a first flange 51, a second flange 53, and a coupling seal member 52. The coupling seal member 52 is an independent member of the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13. The coupling seal member 52 is a member that connects the pump unit 11 and the post-filtration liquid reservoir unit 12 and the post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13.

The first flange 51 and the second flange 53 are thin flanges in the shape of a truncated cone, respectively. In the openings at both ends of the pump unit housing 111 of the pump unit 11, the post-filtration liquid reservoir unit housing 121 of the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit housing 131 of the pre-filtration liquid reservoir unit 13. Commonly, one end has a first flange 51 extending in a direction perpendicular to the central axis of the housing to be mounted, and the other end has a central axis of the housing to be mounted. The second flange 53 is arranged so as to extend in the vertical direction. The first flange 51 has a first holding surface 51a which is a surface perpendicular to the central axis of the housing to be attached. Similarly, the second flange 53 also has a second holding surface 53a, which is a surface perpendicular to the central axis of the housing to be mounted. The first holding surface 51a and the second holding surface 53a form the top surface in the shape of a truncated cone, and serve as the end faces of the respective housings. The first flange 51 spreads in the radial direction of the housing from the outer periphery of the first holding surface 51a of the first flange 51 in the direction of the central axis of the housing to which the first flange 51 is attached and away from the first holding surface 51a. An alignment surface 51b, which is an inclined surface in the shape of a truncated cone, is formed. The second flange 53 also spreads in the radial direction of the housing from the outer periphery of the second holding surface 53a of the second flange 53 in the direction of the central axis of the housing to which the second flange 53 is attached and away from the second holding surface 53a. The alignment surface 53b, which is an inclined surface in the shape of a truncated cone, is formed. The slope and length of the alignment surface 51b and the slope and length of the alignment surface 53b can be freely set. The first flange 51 and the second flange 53 are arranged at the ends of the housing units of the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13, and are typically the first flange 51 and the second flange 51. The shape can be the same except that the alignment surface 51b, which is a truncated cone-shaped slope of the flange 53, and the alignment surface 53b are narrowed in different directions. That is, the first flange 51 and the second flange 53 have the same shape when viewed toward the openings at both ends along the central axis of the housing. That is, the slope and length of the alignment surface 51b and the slope and length of the alignment surface 53b can be set to be the same. However, the slope and length of the alignment surface 51b may be set to be different from the slope and length of the alignment surface 53b.

In the coupling unit 5 between the pre-filtration liquid reservoir unit 13 and the post-filtration liquid reservoir unit 12, in the combined state, the first flange 51 of the pre-filtration liquid reservoir unit housing 131 of the pre-filtration liquid reservoir unit 13 is the post-filtration liquid reservoir. The unit 12 faces the second flange 53 of the liquid reservoir unit housing 121 after filtration. Further, in the coupling unit 5 between the post-filtered liquid reservoir unit 12 and the pump unit 11, the first flange 51 of the post-filtered liquid reservoir unit housing 121 of the post-filtered liquid reservoir unit 12 is the pump unit of the pump unit 11 in the coupled state. It faces the second flange 53 of the housing 111.

The coupling seal member 52 is made of a flexible resin, for example, neoprene rubber, and has a cylindrical wall section having a ring-shaped cross section as a wall surface. The thickness of the coupling seal member 52 (the length of the cylinder) is longer than the thickness of the first flange 51 and the second flange 53, respectively. The coupling seal member 52 is used when the housings of the pump unit 11 and the liquid reservoir unit 12 after filtration are connected to each other, or the housings of the liquid reservoir unit 12 after filtration and the liquid reservoir unit 13 before filtration are connected to each other. The center of the ring shape of the cross section of 52 is arranged so as to be the position of the central axis of each housing connected by the coupling seal member 52, and the first flange 51 and the second flange 53 are arranged on the coupling seal member 52. It is attached to the pump unit 11, the post-filter liquid reservoir unit 12, and the pre-filter liquid reservoir unit 13 so as to be introduced inside. The coupling seal member 52 has a tab 52b extending in the radial direction of the cylinder on the inner surface of the wall surface having a cylindrical shape, substantially at the center of the wall surface in the height direction, over the entire inner surface of the wall surface. That is, the tab 52b extends from the inner wall of the coupling seal member 52 to the inside of the coupling seal member 52 in a direction perpendicular to the central axis of the housing to be coupled over the entire inner surface of the coupling seal member 52. It's extended so much. The predetermined extension length is preferably longer than the respective lengths of the first holding surface 51a of the first flange 51 and the second holding surface 53a of the second flange 53. From the base of the tab 52b on which the tab 52b on the inner surface of the joint seal member 52 extends, from the center of the ring shape of the joint seal member 52 as the distance from the base of the tab 52b increases in the direction of the cylindrical central axis of the joint seal member 52. It has

slopes

52a and 52c that spread in the direction of separation. The slope 52a and the slope 52c extend in opposite directions with respect to the tab 52b, the slope 52a side corresponds to the second flange 53 side, and the slope 52c side corresponds to the first flange 51 side.

The alignment surface 51b, which is the slope of the conical base of the first flange 51, and the alignment surface 53b, which is the slope of the conical base of the second flange 53, have complementary shapes corresponding to the slope 52a and the slope 52c. When the first flange 51 and the second flange 53 are joined by the coupling seal member 52, the alignment surface 53b, which is the slope of the conical base of the second flange 53, comes into surface contact with the slope 52a of the coupling seal member 52, and the first The alignment surface 51b, which is the slope of the conical base of the flange 51, is defined so as to make surface contact with the slope 52c of the coupling seal member 52. That is, in a state where the first flange 51 and the second flange 53 are coupled by the coupling seal member 52, the truncated cone shapes of the first flange 51 and the second flange 53 are the alignment surfaces 51b of the first flange 51. The shape of the slope of the truncated cone is such that the slope of the second flange 53 and the slope of the alignment surface 53b of the second flange 53 are narrowed in the directions facing each other. However, the first flange 51 and the second flange 53 may not have a truncated cone shape, but may have a cylindrical shape having no slope. When the first flange 51 and the second flange 53 have a cylindrical shape, the coupling seal member 52 does not arrange the

slopes

52a and 52c on the inner surface, but instead uses the first flange 51 and the second flange 53. The cylindrical shape may be complementary to the cylindrical shape. However, by forming the first flange 51 and the second flange 53 into a truncated cone shape, the coupling seal member 52 makes the

inner slopes

52a and 52c and the first flange 51 and the second flange 53 into a truncated cone shape. Alignment becomes easy. Hereinafter, for convenience, the shape of the first flange 51 is referred to as a "first flange form", and the shape of the second flange 53 is referred to as a "second flange form". The "first flange form" and the "second flange form" refer to the filtration device 1 in which the housings are stacked from the lower side in the order of the pump unit 11, the post-filter liquid reservoir unit 12, and the pre-filter liquid reservoir unit 13. In the applied state, the "first flange form" is a truncated cone shape with a slope that narrows downward in the vertical direction, and the "second flange form" is a truncated cone shape with a slope that narrows upward in the vertical direction. Will be defined. Typically, the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 have a common shape as a flange in the coupling unit 5 arranged in each housing. However, the "first flange form" and the "second flange form" can have a common shape in which the narrowing direction of the truncated cone-shaped slope is different, and the narrowing angle of the truncated cone-shaped slope is different. It may be in shape.

When the coupling seal member 52 couples the first flange 51 and the second flange 53, the coupling seal member 52 is held by at least one of the first flange 51 and the second flange 53, and is not held by the other. It has become. Whether the coupling seal member 52 is held by the first flange 51 or the second flange 53 can be freely determined by selecting which housing is set so that the coupling seal member 52 can be easily separated. Therefore, the coupling seal member 52 is provided on the inner surface of the wall surface having a cylindrical shape, at or near the opening at one end of the cylindrical shape, on the entire circumference of the inner surface of the wall surface or a part thereof, in the radial direction of the cylinder from the inner surface of the wall surface. It has a pressing claw 51c that extends to. On the other hand, the pressing claw is not arranged in the opening on the opposite side to the opening in which the pressing claw 51c is arranged. When the coupling seal member 52 connects the first flange 51 and the second flange 53, at least one of the first flange 51 and the second flange 53 is sandwiched between the tab 52b and the pressing claw 51c, and the coupling seal member 52. The 52 is held by the flange on the side sandwiched by the tab 52b and the pressing claw 51c.

For example, when the coupling seal member 52 is attached to the first flange 51 in the first flange form, the pressing claw 51c is located on the opposite side of the tab 52b with respect to the first flange 51. 2B and 2C are views corresponding to this case. As a result, when the first flange 51 and the second flange 53 are connected by the coupling seal member 52 and are held by the first flange 51, the first flange 51 is held by the tab 52b and the pressing claw 51c. It is sandwiched and the coupling seal member 52 is in a state of being held and coupled to the first flange 51. On the other hand, since the holding claw is not arranged on the side of the second flange 53 of the coupling seal member 52, the coupling seal member 52 is not held by the second flange 53. When the housing having the first flange 51 in the first flange form and the housing having the second flange 53 in the second flange form are joined by the coupling seal member 52, the coupling seal member 52 is the first in the first flange form. The first flange 51 and the second flange 53 are coupled by being fitted into the flange 51 and placed on the second flange 53 in the form of the second flange. At this time, the coupling seal member 52 is fitted into the first flange 51 of the first flange form, and is always held by the tab 52b and the pressing claw 51c on the first flange 51 side of the first flange form, but is coupled. The seal member 52 is placed on the second flange 53 in the form of the second flange and is easily separated from the seal member 52. The coupling seal member 52 is only placed on the second flange 53 in the form of the second flange, but the coupling sealing member 52 is required to completely seal the first flange 51 and the second flange 53 by filtering. The differential pressure generated between the pump unit 11 and the post-filtered liquid reservoir unit 12 and the differential pressure generated between the post-filtered liquid reservoir unit 12 and the pre-filtered liquid reservoir unit 13 during the operation of the degassing pump 112 of the device 1. As a result, the first holding surface 51a and the second holding surface 53a are realized by pressing the tab 52b in close contact with the tab 52b.

On the contrary, the same applies to the case where the first flange 51 and the second flange 53 are connected by the coupling seal member 52 and the coupling sealing member 52 is held by the second flange 53 in the second flange form. In this case, the pressing claw 51c is located on the side opposite to the tab 52b with respect to the second flange 53. As a result, when the first flange 51 and the second flange 53 are joined by the coupling seal member 52, the second flange 53 is sandwiched between the tab 52b and the pressing claw 51c, and the coupling sealing member 52 is the second flange 53. It will be in a state of being held and bonded to. On the other hand, since the holding claw is not arranged on the side of the first flange 51 of the coupling seal member 52, the coupling seal member 52 is not held by the first flange 51. The coupling seal member 52 is fitted into the second flange 53 of the second flange form, and is always held by the tab 52b and the pressing claw 51c on the second flange 53 side of the second flange form, but the coupling seal member 52 Is placed on the first flange 51 in the first flange form and easily separated from the first flange 51. In this case, the relationship between the

slopes

52a and 52c of the coupling seal member 52 and the alignment surface 51b and the first holding surface 51a of the first flange 51 and the positioning surface 53b and the second holding surface 53a of the second flange is , The relationship is opposite to that shown in FIGS. 2B and 2C. That is, the alignment surface 51b, which is the slope of the conical base of the first flange 51, and the alignment surface 53b, which is the slope of the conical base of the second flange 53, have complementary shapes corresponding to the slope 52a and the slope 52c. However, when the first flange 51 and the second flange 53 are joined by the coupling seal member 52, the alignment surface 53b of the second flange 53 comes into surface contact with the slope 52c of the coupling sealing member 52. , The alignment surface 51b of the first flange 51 is defined so as to make surface contact with the slope 52a of the coupling seal member 52. At this time, the coupling seal member 52 is only placed on the first flange 51 in the form of the first flange, but the coupling sealing member 52 does not completely seal the first flange 51 and the second flange 53. , It occurs between the pump unit 11 and the post-filter liquid reservoir unit 12 when the degassing pump 112 of the filtration device 1 operates, as in the case where the coupling seal member 52 is held by the first flange 51 in the first flange form. Realized by pressing the first holding surface 51a and the second holding surface 53a in close contact with the tab 52b due to the differential pressure and the differential pressure generated between the post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13. Will be done.

As described above, the coupling unit 5 including the first flange 51, the coupling seal member 52, and the second flange is configured so that the pre-filtration liquid reservoir unit 13 is located above the post-filtration liquid reservoir unit 12 and is coupled. It is possible, and the post-filtration liquid reservoir unit 12 can be configured to be located and coupled above the pump unit 11. The pump unit 11 and the post-filtration liquid reservoir unit 12 are combined, and the post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13 are combined to form the filtration device 1. Up to this point, the coupling unit 5 has been described. Hereinafter, the overall relationship of the filtration device 1 to which the coupling unit 5 is applied to the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 will be described. To do. The filtration device 1 includes a pump unit 11, a post-filtration liquid reservoir unit 12, a pre-filtration liquid reservoir unit 13, and a coupling unit 5.

The pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 can be stacked in the vertical direction in the order of the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 from the bottom. It is a columnar body having the same cross section. The cross-sections of the respective housings of the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 are typical and preferably circular in cross-section, in which case the pump unit 11 and The post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13 are concentric cylinders, respectively, and when these are stacked in the vertical direction, the overall form of the filtration device 1 is also columnar. In this specification, this will be described as an example. Here, the center of these cylindrical shapes in a state where the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 are stacked in this order in the vertical direction is defined as the central axis CL of the filtration device 1. The direction in which the central axis CL extends is the depth direction of the post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13. The housings of the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 may have a polygonal shape typified by a quadrangle. When these are stacked in the vertical direction, they form a polygonal prism shape. In this case, the shapes of the first flange 51, the coupling seal member 52, and the second flange 53 of the coupling unit 5 are the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13, respectively. It becomes the cross-sectional shape of the housing. The overall shape of the filtration device 1 is determined by the shape of the cross section of each of the housings of the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13.

The pump unit 11 has a circular outer shape having a predetermined radius in cross section, and is composed of a cylindrical pump unit housing 111 having a hollow inside. Inside the pump unit housing 111, a degassing pump 112 for degassing such as a vacuum pump is built. A protrusion 113 formed so as to rise from the upper surface of the pump unit housing 111 is provided on the upper side of the pump unit housing 111, and an intake port 113a communicating with the intake line of the degassing pump 112 is provided on the top of the protrusion 113. The degassing pump 112 sucks in air from the intake port 113a and discharges it to the external environment. A wall surface 21a rises cylindrically from the upper surface of the pump unit housing 111 on the outer circumference of the pump unit housing 111, and a space having a certain volume is formed on the upper surface of the pump unit housing 111 by the wall surface 21a. Since the upper surface of the pump unit housing 111 has a protrusion 113 formed so as to be raised, for example, in a substantially central portion, the space is formed around the root of the protrusion 113, and the space is the pump unit. It functions as a trap 114 as a liquid pool having the upper surface of the housing 111 as the bottom. That is, the liquid component such as mist-like fine droplets contained in the gas guided to the exhaust chamber 121b is drawn into the intake port 113a and collides with the protrusion 113 to be liquefied. The liquid that has flowed out of the protrusion 113 as a liquid flows into the trap 114, which is a liquid pool, to prevent the liquid component from entering the degassing pump 112 for degassing. In the application of the coupling unit 5 in the pump unit 11, the second flange form is arranged in the pump unit 11. That is, a flange 1153, which is a second flange form, is provided at the end of the wall surface 111a of the pump unit housing 111. Since the flange 1153 has a second flange form, its shape is as described above, and is omitted here.

Typically, the cross section of the post-filter liquid reservoir unit housing 121 of the post-filter liquid reservoir unit 12 is a circle having the same cross section as the diameter of the cross section of the pump unit housing 111 of the pump unit 11. In the post-filtered liquid reservoir unit housing 121, which has a central axis, has a tubular outer shape so that the central axes coincide with each other when the cross sections are combined, and the inside is hollow. It is formed. A typical example is a cylindrical shape, but the cross section does not necessarily have to be cylindrical, and the cross section of the pump unit housing 111 of the pump unit 11 matches the cross section of the post-filtered liquid reservoir unit housing 121 of the post-filtered liquid reservoir unit 12. As long as it is, it may be a square or a rectangular cylinder. The post-filtration liquid reservoir unit housing 121 has openings at both ends, and a flange 1253, which is a second flange form, is provided at one end on the side connected to the pre-filtration liquid reservoir unit 13, and the opposite end. A flange 1251 which is a first flange form is provided at an end portion on the side connected to the pump unit 11. Since the flange 1251 and the flange 1253 have the first flange form and the second flange form, respectively, their shapes are as described above, and are omitted here. The post-filtration liquid reservoir unit 12 and the pump unit housing 111 are fixed by the coupling unit 5 so that the post-filtration liquid reservoir unit 12 is located above the pump unit housing 111. That is, the flange 1251 (first flange form) of the liquid reservoir unit 12 after filtration and the flange 1153 (second flange form) of the pump unit 11 are coupled by the coupling seal member 52. The shape of the coupling seal member 52 is as described above. In the combined state, the flange 1251 (first flange form) of the liquid reservoir unit 12 after filtration and the flange 1153 (second flange form) of the pump unit 11 sandwich the tab 52b between them. In particular, when the degassing pump 112 operates to degas the inside of the post-filter liquid reservoir unit housing 121, the flange 1251 (first flange form) of the post-filter liquid reservoir unit 12 and the pump unit 11 due to the differential pressure. The flange 1153 (second flange form) is in close contact with the tab 52b and presses the tab 52b, so that the flange 1251 (first flange form) of the liquid reservoir unit 12 after filtration and the flange 1153 (second flange form) of the pump unit 11 are pressed. ) Is tightly coupled. In this case, the coupling unit 5 corresponds to the flange 1251 (first flange form) of the liquid reservoir unit 12 after filtration, the flange 1153 (second flange form) of the pump unit 11, and the coupling seal member 52.

Further, when the inside of the liquid reservoir unit housing 121 after filtration is not degassed by the degassing pump 112, the flange 1153 (second flange form) of the pump unit 11 of the coupling seal member 52 is the holding claw 52d of the coupling sealing member. Since it is sandwiched between the and tab 52b, it is always held on the flange 1153 (second flange form) side of the pump unit 11, and the flange 1251 (first) of the liquid reservoir unit 12 after filtration is placed on the tab 52b of the coupling seal member 52. Only the flange form) is placed, and the coupling seal member 52 is not held by the liquid reservoir unit 12 after filtration. When the flange 1251 (first flange form) of the liquid reservoir unit 12 after filtration and the flange 1153 (second flange form) of the pump unit 11 are separated, the coupling seal member 52 is the flange 1153 (second flange form) of the pump unit 11. ) Side, and the flange 1251 (first flange form) of the liquid reservoir unit 12 after filtration is easily separated from the coupling seal member 52. However, in this embodiment, the coupling seal member 52 has been described as remaining on the flange 1153 (second flange form) side of the pump unit 11, but as described above, the coupling seal member 52 is filtered and the liquid reservoir unit 12 is used. It is also possible to choose to remain on the flange 1251 (first flange form) of.

In the post-filtration liquid reservoir unit 12, an isolation member 122 is arranged in a hollow portion inside the liquid reservoir unit 12. The isolation member 122 connects the entire circumference of the inner surface of the liquid reservoir unit 12 after filtration to the storage chamber 121a for storing the liquid, and the exhaust chamber 121b communicating with the intake port 113a of the pump unit housing 111. It is defined at the bottom of the liquid reservoir unit 12 after filtration. In the exhaust chamber 121b, an opening is formed on the side opposite to the isolation member 122 so that the upper surface side of the pump unit 11 is exposed in the exhaust chamber 121b. The storage chamber 121a and the exhaust chamber 121b do not communicate with each other. The isolation member 122 may be perpendicular to the cylindrical central axis of the post-filtration liquid reservoir unit 12, or may be tilted as shown in FIG. When the post-filtration liquid reservoir unit 12 and the pump unit 11 are hermetically connected by the coupling seal member 52, the isolation member 122, the pump unit housing 111 (the upper surface of the pump unit housing 111 (trap 114)), and the post-filtration liquid reservoir unit The exhaust chamber 121b is formed as a space surrounded by the inner surface of the liquid reservoir unit housing 121 after filtration and the inner surface of the pump unit housing 111 having a volume for exhaust.

Typically, the pre-filtration liquid reservoir unit 13 has a cross section of the pre-filtration liquid reservoir unit housing 131, which is the housing thereof, having the same diameter as the cross section of the post-filtration liquid reservoir unit housing 121 of the post-filtration liquid reservoir unit 12. Filtration that has a circular shape, each housing has a central axis, has a tubular outer shape so that the central axes match when the cross sections are combined, and the inside is hollow. It is formed by the pre-liquid reservoir unit housing 131. Although a cylindrical shape is a typical example, the cross section does not necessarily have to be a cylindrical shape, and the cross section of the pre-filtration liquid reservoir unit housing 131 coincides with the cross section of the post-filtration liquid reservoir unit housing 121 of the post-filtration liquid reservoir unit 12. As long as it is a square or a rectangular cylinder, it may be used. The bottom 131a of the pre-filtration liquid reservoir unit housing 131 has a filter member 134 that filters the liquid before filtration, and a discharge port 132 that discharges the filtered liquid that has passed through the filter member 134 to the liquid reservoir unit 12 after filtration. ing. The end of the pre-filtration liquid reservoir unit 13 on the side where the discharge port 132 is located faces the end of the post-filtration liquid reservoir unit housing 121. The opening at the end of the pre-filtration liquid reservoir unit housing 131 on the side where the filter member 134 of the pre-filtration liquid reservoir unit 13 is arranged has a flange 1351 which is a first flange form. Since the flange 1351 has the first flange form, its shape is as described above and is omitted here. A flange 1253 in the form of a second flange is provided at the end of the post-filtration liquid reservoir unit housing 121 of the post-filtration liquid reservoir unit 12 corresponding to this, that is, at the end on the side of the storage chamber 121a. Since the flange 1253 is also in the form of the second flange, its shape is as described above and is omitted here. What is the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit housing 131 of the pre-filtration liquid reservoir unit 13 and the flange 1253 (second flange form) of the post-filtration liquid reservoir unit housing 121 of the post-filtration liquid reservoir unit 12? , At least the outer diameter dimensions are the same, and they have a common shape. Since the first flange form is common, looking at the flange alone, the flange 1351 of the pre-filter liquid reservoir unit housing 131 (first flange form) and the flange 1251 of the post-filter liquid reservoir unit housing 121 (first flange form). ), And the flange 1253 (second flange form) of the liquid reservoir unit housing 121 after filtration and the flange 1153 (second flange form) of the pump unit housing 111 have the same shape. The post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13 are fixed by the coupling unit 5 so that the pre-filtration liquid reservoir unit 13 is located above the post-filtration liquid reservoir unit 12. That is, the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit housing 131 and the flange 1253 (second flange form) of the post-filtration liquid reservoir unit 12 are coupled by the coupling seal member 52. The shape of the coupling seal member 52 is also as described above. In the combined state, the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit housing 131 and the flange 1253 (second flange form) of the post-filtration liquid reservoir unit 12 sandwich the tab 52b between them. In particular, when the degassing pump 112 operates to degas the inside of the post-filtration liquid reservoir unit 12, the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit housing 131 and the post-filtration liquid due to the differential pressure The flange 1253 (second flange form) of the reservoir unit 12 is in close contact with the tab 52b and presses the tab 52b, so that the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit housing 131 and the post-filtration liquid reservoir unit 12 Flange 1253 (second flange form) is hermetically coupled. When the inside of the liquid reservoir unit 12 after filtration is not degassed by the degassing pump 112, the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit 13 presses the coupling seal member 52. Since it is sandwiched between the claw 52d and the tab 52b, it is always held on the flange 1351 (first flange form) side of the pre-filtration liquid reservoir unit 13. On the other hand, since the coupling seal member 52 is only placed on the flange 1253 (second flange form) of the post-filter liquid reservoir unit 12 and is not held, the flange 1351 (second flange form) of the pre-filter liquid reservoir unit housing 131 is not held. When the flange 1253 (second flange form) of the post-filter liquid reservoir unit 12 is separated from the post-filter liquid reservoir unit 12), the post-filter liquid reservoir unit 12 is combined with the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit 13. Easily separated from the flange 1253 (second flange form) of. In this case, the coupling unit 5 corresponds to the flange 1351 (first flange form) of the pre-filtration liquid reservoir unit 13, the flange 1253 (second flange form) of the post-filtration liquid reservoir unit 12, and the coupling seal member 52. ..

In the storage chamber 121a defined by the isolation member 122 of the post-filtration liquid reservoir unit 12, the inner surface of the post-filtration liquid reservoir unit 12 and the bottom 131a of the pre-filtration liquid reservoir unit 13, the liquid after filtration is stored inside. It is possible. The discharge port 132 for discharging the filtered liquid to the post-filtered liquid reservoir unit 12 protrudes from the bottom 131 a of the pre-filtered liquid reservoir unit 13 so as to be located in the filtered liquid storage chamber 121a inside the post-filtered liquid reservoir unit 12. ing. The discharge port 132 is provided with a discharge valve 133 that reduces the pressure of the post-filter liquid reservoir unit 12 and discharges the filtered post-filter liquid when the pressure becomes equal to or lower than a predetermined pressure. Hereinafter, a state in which the pre-filtration liquid reservoir unit 13 is hermetically connected to the post-filtration liquid reservoir unit 12 and a state in which the post-filtration liquid reservoir unit 12 and the pump unit 11 are hermetically connected will be described.

The post-filtration liquid reservoir unit 12 penetrates the wall surface of the storage chamber 121a through the storage chamber degassing port 12a, which is a communication hole penetrating from the storage chamber 121a to the outside, and through the wall surface of the exhaust chamber 121b from the exhaust chamber 121b to the outside. It has an exhaust port 12b, which is a communication hole. The storage chamber degassing port 12a is arranged near the end of the post-filtration liquid reservoir unit 12 on the side closer to the pre-filtration liquid reservoir unit 13, and the exhaust port 12b is on the side farther from the pre-filtration liquid reservoir unit 13 (on the pump unit 11). (Near side) is arranged on the end side of the post-filtration liquid reservoir unit 12. By connecting the storage chamber degassing port 12a and the exhaust port 12b by an exhaust pipe line 7, the air in the storage chamber 121a reaching the degassing pump 112 from the storage chamber 121a via the exhaust chamber 121b is exhausted. The route to be used is defined. In this state, when the degassing pump 112 operates, the exhaust chamber 121b is first decompressed from the intake port 113a, and when the storage chamber 121a of the liquid reservoir unit 12 after filtration is subsequently decompressed via the exhaust pipe line 7, the atmosphere is reduced. The pre-filtered liquid of the pre-filtered liquid reservoir unit 13 that is opened is drawn by a differential pressure toward the depressurized post-filtered liquid reservoir unit 12, passes through the filter member 134, and is filtered to form the post-filtered liquid reservoir unit 12. It leads to the storage chamber 121a.

For example, the post-filtration liquid reservoir unit 12 has a handle 6, and the exhaust pipe line 7 is bored inside the handle 6. The handle 6 is attached to the post-filtration liquid reservoir unit 12 so that the user can easily hold and carry the post-filtration liquid reservoir unit 12. The exhaust pipe line 7 is set so that the storage chamber 121a and the exhaust pipe line 7 communicate with each other and the exhaust line 7 and the exhaust port 12b match. As a result, the inside of the liquid reservoir unit 12 after filtration is depressurized by the degassing pump 112, and the storage chamber 121a and the exhaust chamber 121b communicate with each other via the exhaust pipe line 7, and the air in the storage chamber 121a is communicated by the degassing pump 112. Is exhausted (degassed).

Also, in operation, in order to prevent contamination, the liquid in the pre-filtration liquid reservoir unit 13 is managed so that the liquid after filtration is below the discharge port 132. For example, a form is conceivable in which the degassing pump 112 is automatically stopped when the liquid after filtration reaches the discharge port 132. On this premise, by arranging the storage chamber degassing port 12a in which the exhaust pipe line 7 and the storage chamber 121a communicate with each other above the discharge port 132, it is possible to prevent the filtered liquid from entering the storage chamber degassing port 12a. be able to. Further, in order to collect as much filtered liquid as possible while preventing the liquid after filtration from entering the storage chamber degassing port 12a, the storage chamber degassing port 12a is vertically along the central axis of the filtration device 1. It is desirable to install it on the upper side of the direction. In principle, it is necessary to prevent the filtered liquid from entering the storage chamber degassing port 12a by arranging the storage chamber degassing port 12a in which the exhaust pipe line 7 and the storage chamber 121a communicate with each other above the discharge port 132. However, for example, it is conceivable that the filtrate is mixed in the exhaust pipe line 7. Since the filtrate enters the exhaust pipe line 7 in the form of fine droplets or mist, it may enter the exhaust chamber 121b. Therefore, as described above, in the exhaust chamber 121b, the protrusion 113 and the trap 114 can prevent the liquid component from entering the degassing pump 112.

Subsequently, with reference to FIGS. 6 to 8, the point that the configuration can be easily changed by the coupling unit 5 of the assembly type decompression type filtration device 1 of the present invention will be described. Up to this point, a typical example in which the pump unit 11, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13 each constitute an assembly type decompression type filtration device 1 has been described. This is the minimum configuration for configuring the assembly type decompression filtration device 1. However, among them, it is possible to configure the assembly type decompression type filtration device 1 by using a plurality of pre-filtration liquid reservoir units 13. As an example, FIG. 6 is a diagram showing a state in which an assembly type decompression type filtration device 1 is configured by two pre-filtration liquid reservoir units 13. Since the pre-filtration liquid reservoir unit 13 has the same shape, a plurality of the above-mentioned coupling units 5 may be prepared and the pre-filtration liquid reservoir units 13 may be bonded to each other by the above-mentioned coupling unit 5. Each coupling unit 5 includes a flange 1351 in the first flange form, a flange 1353 in the second flange form, and a coupling seal member 52. First, the coupling seal member 52 can bond the pre-filtration liquid reservoir units 13 to each other and also the pre-filtration liquid reservoir unit 13 and the post-filtration liquid reservoir unit 12 in exactly the same manner as described above. .. Thereby, for example, it is possible to realize multi-layer filtration with filter members having different mesh roughness.

Further, it is possible to configure the assembly type decompression type filtration device 1 with a plurality of post-filtration liquid reservoir units 12 and one pre-filtration liquid reservoir unit 13 on one pump unit 11. As an example, FIG. 7 is a diagram showing a state in which an assembly type decompression type filtration device 1 is configured by two post-filtration liquid reservoir units 12 on a pump unit 11. That is, since the two post-filtration liquid reservoir units 12 have the same shape, a plurality of the above-mentioned coupling units 5 may be prepared and the post-filtration liquid reservoir units 12 may be bonded to each other by the above-mentioned coupling unit 5. Each coupling unit 5 includes a flange 1251 in the form of a first flange, a flange 1253 in the form of a second flange, and a coupling seal member 52.

As shown in FIG. 6 showing an example in which two pre-filtration liquid reservoir units 13 are stacked and FIG. 7 in which two post-filtration liquid reservoir units 12 are stacked, two or more pre-filtration liquid reservoir units 13 and two It is also possible to stack the liquid reservoir units 12 after filtration as described above. This is shown in FIG. 8 (a) corresponds to FIG. 3, FIG. 8 (b) corresponds to FIG. 6, and FIG. 8 (e) corresponds to FIG. 7. As described above, an example in which three pre-filtration liquid reservoir units 13 are further stacked is shown in FIG. 8 (c), and an example in which three post-filtration liquid reservoir units 12 are stacked is shown in FIG. 8 (f). Further, as shown in FIG. 8D, a plurality of pre-filtration liquid reservoir units 13 are facilitated, and a plurality of pre-filtration liquid reservoir units 13 are arranged by arranging the coupling unit 5 between the pre-filtration liquid reservoir units 13. It can be combined and configured. Similarly, as shown in FIG. 8 (g), a plurality of post-filtration liquid reservoir units 12 are facilitated, and a plurality of post-filtration liquid reservoir units are arranged by arranging the coupling unit 5 between the post-filtration liquid reservoir units 12. It is possible to combine and configure the twelve.

Further, by configuring the coupling unit 5 to be applied to each of the pump unit 11 constituting the assembly type decompression type filtration device 1, the post-filtration liquid reservoir unit 12, and the pre-filtration liquid reservoir unit 13, after filtration. The liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13 are combined by the coupling unit 5, and this is used as one unit (the unit of the post-filtration liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13), which is a plurality of units. It is also possible to combine each of them with the coupling unit 5. That is, for example, as shown in FIGS. 8 (h) and 8 (i), the post-filtration liquid reservoir unit 12 is superposed on the pump unit 11, the pre-filtration liquid reservoir unit 13 is superposed on the pump unit 11, and further Assembled decompression type by alternately stacking a plurality of post-filtration liquid reservoir units 12 and pre-filtration liquid reservoir units 13 so as to stack the post-filtration liquid reservoir unit 12 on top and the pre-filtration liquid reservoir unit 13 on top of it. It is also possible to configure the filtration device 1. Then, the liquid reservoir unit 12 after filtration and the liquid reservoir unit 13 before filtration are connected by a coupling unit 5.

Further, filtration as if FIGS. 8 (b) to (d), FIGS. 8 (e) to (g), and FIGS. 8 (h) and 8 (i) were mixed and combined (not shown). It is also possible to take the form in which the post-liquid reservoir unit 12 and the pre-filtration liquid reservoir unit 13 are irregularly stacked. As described above, as can be understood from FIGS. 8 (a) to 8 (i), the plurality of post-filtration liquid reservoir units 12 and the plurality of pre-filtration liquid reservoir units 13 are freely overlapped and coupled by the coupling unit 5. It becomes possible to do.

This application claims priority from Japanese Patent Application No. 2019-213049 filed on November 26, 2019, and the contents are cited as part of this application.

1 Assembled decompression type filtration device 11 Pump unit 12 Post-filtration liquid reservoir unit 13 Pre-filtration liquid reservoir unit 5

Coupling unit

51, 1251,1351 Flange (first flange form)
52

Coupling seal member

53,1153,1253 Flange (second flange form)
111 Pump unit housing 112 Degassing pump 113 Protrusion 113a Intake port 121 After filtration Liquid reservoir unit housing 122 Isolation member

121a Storage chamber

121b Exhaust chamber 6 Handle 7 Exhaust pipeline 131 Pre-filtration liquid reservoir unit housing 132 Discharge port 133 Discharge valve 134 Filter Element

Claims

A cylindrical pump unit housing that is hollow and extends so as to have a central axis, and a degassing pump is arranged inside the pump unit housing, and has an intake hole for the degassing pump on one end side of the pump unit housing. With the pump unit
A filter member is arranged at one end, an opening is provided at the other end, and a tubular pre-filtration liquid reservoir unit housing extending so as to have a hollow inside and a central axis is provided. A pre-filtration liquid reservoir unit that can be injected from the end and store the pre-filtration liquid inside the inside,
It has a tubular post-filtered liquid reservoir unit housing having openings at both ends and extending so that the inside is hollow and has a central axis, and the inside of the post-filtered liquid reservoir unit housing is divided into a storage chamber and an exhaust chamber. A post-filtration liquid reservoir unit having an isolation member that can store the post-filtered liquid obtained by filtering the pre-filtered liquid in the storage chamber, the pump unit housing, and the post-filtered liquid reservoir unit. An assembly-type decompression filtration device including a first coupling unit for coupling the housing and a second coupling unit for coupling the post-filtration liquid reservoir unit housing and the pre-filtration liquid reservoir unit housing.
The assembled decompression filtration device according to claim 1.
The first coupling unit is
The end of the post-filtered liquid reservoir unit housing on the exhaust chamber side is a flange in the form of a first flange extending in a direction perpendicular to the central axis of the post-filtered liquid reservoir unit housing, and the one end of the pump unit is said. A flange in the form of a second flange extending in a direction perpendicular to the central axis of the pump unit housing,
It comprises a first coupling seal member having a cylindrical wall surface and a tab extending in the radial direction of the cylinder over the entire inner surface of the wall surface at substantially the center of the inner surface of the wall surface.
The second coupling unit is
One end of the pre-filtration liquid reservoir unit housing is a flange in the form of a first flange extending in a direction perpendicular to the central axis of the pre-filtration liquid reservoir unit housing.
The end of the post-filtered liquid reservoir unit housing on the side of the storage chamber has a flange in the form of a second flange extending in a direction perpendicular to the central axis of the post-filtered liquid reservoir unit housing.
It comprises a second coupling seal member having a cylindrical wall surface and a tab extending in the radial direction of the cylinder over the entire inner surface of the wall surface at substantially the center of the inner surface of the wall surface.
The first flange form is a truncated cone shape having a slope that narrows downward in the vertical direction, and the second flange form is a truncated cone shape having a slope that narrows upward in the vertical direction.
The first so that the tab of the first coupling seal member and the tab of the second coupling seal member are sandwiched between the flange of the first flange form and the flange of the second flange form. The coupling unit performs the coupling between the pump unit housing and the pre-filtration liquid reservoir unit housing, and the second coupling unit connects the post-filtration liquid reservoir unit housing and the pre-filtration liquid reservoir unit housing. Type decompression type filtration device.
The assembled decompression filtration device according to claim 2.
The first coupling seal member and the other seal member each have an opening at one end of the cylinder or a holding claw extending in the radial direction from the inner surface of the wall surface in the vicinity of the opening. Prepare,
The flange of the first flange form of the pump unit is sandwiched between the tab of the first coupling seal member and the holding claw, and the flange of the second flange form of the post-filtered liquid reservoir unit is said. The coupling between the post-filtration liquid reservoir unit and the pump unit is made by placing the first coupling seal member on the tab.
The flange of the pre-filtration liquid reservoir unit in the form of the first flange is sandwiched between the tab of the second coupling seal member and the holding claw, and the tab of the second coupling seal member is the post-filtration liquid. An assembly-type decompression type filtration device in which the pre-filtration liquid reservoir unit and the post-filtration liquid reservoir unit are coupled by being placed on the flange of the second flange form of the reservoir unit.
The assembled decompression filtration device according to claim 2.
The assembled decompression type filtration device has an exhaust pipeline that connects the storage chamber and the exhaust chamber.
In a state where the pre-filtration liquid reservoir unit, the post-filtration liquid reservoir unit, and the pump unit are connected by the first coupling seal member and the second coupling seal member.
By operating the degassing pump of the pump unit, the inside of the storage chamber is degassed through the exhaust chamber by degassing the exhaust chamber of the post-filtration liquid reservoir unit from the intake hole. Assembled decompression type filtration device.
The assembled decompression filtration device according to claim 3.
The assembled decompression type filtration device has an exhaust pipeline that connects the storage chamber and the exhaust chamber.
In a state where the pre-filtration liquid reservoir unit, the post-filtration liquid reservoir unit, and the pump unit are connected by the first coupling seal member and the second coupling seal member.
By operating the degassing pump of the pump unit, the inside of the storage chamber is degassed through the exhaust chamber by degassing the exhaust chamber of the post-filtration liquid reservoir unit from the intake hole. Assembled decompression type filtration device.
The assembled decompression filtration device according to claim 4.
The exhaust pipeline is an assembly-type decompression type filtration device that is bored inside a handle attached to the post-filter liquid reservoir unit so that the post-filter liquid reservoir unit can be held.
The assembled decompression filtration device according to claim 5.
The exhaust pipeline is an assembly-type decompression type filtration device that is bored inside a handle attached to the post-filter liquid reservoir unit so that the post-filter liquid reservoir unit can be held.
The assembled decompression filtration device according to claim 6.
Each of the first coupling seal member and the second coupling seal member is degassed in the storage chamber by the degassing pump, so that the flange in the form of the first flange and the second flange are respectively. An assembly-type decompression filtration device in which the coupling is a closed coupling when the flange of the form is pressed against the tab in close contact with the tab.
The assembled decompression filtration device according to claim 7.
Each of the first coupling seal member and the second coupling seal member is degassed in the storage chamber by the degassing pump, so that the flange in the form of the first flange and the second flange are respectively. An assembly-type decompression filtration device in which the coupling is a closed coupling when the flange of the form is pressed against the tab in close contact with the tab.
The assembled decompression filtration device according to any one of claims 2 to 9.
Each of the first joint seal member and the second joint seal member is provided on the inner surface of the first joint seal member and the second joint seal member from the root of the tab. An assembly-type decompression type filtration device having a slope having a complementary shape that matches the flange of the first flange form and the flange of the second flange form.
A cylindrical pump unit housing that is hollow and extends so as to have a central axis, and a degassing pump is arranged inside the pump unit housing, and has an intake hole for the degassing pump on one end side of the pump unit housing. With the pump unit
A filter member is arranged at one end, an opening is provided at the other end, and a tubular pre-filtration liquid reservoir unit housing extending so as to have a hollow inside and a central axis is provided. A plurality of pre-filtration liquid reservoir units capable of injecting from the end and storing the pre-filtration liquid inside the inside,
It has a tubular post-filtered liquid reservoir unit housing with openings at both ends and a hollow interior extending so as to have a central axis, and the inside of the post-filtered liquid reservoir unit housing is divided into a storage chamber and an exhaust chamber. A plurality of post-filter liquid reservoir units having a post-filtration liquid reservoir unit capable of storing the post-filter liquid obtained by filtering the pre-filter liquid in the storage chamber, and a plurality of post-filter liquid reservoir units.
An assembly-type decompression filtration device including a plurality of coupling seal members for connecting the plurality of pre-filtration liquid reservoir unit housings and the plurality of post-filtration liquid reservoir unit housings.
Each of the plurality of post-filtered liquid reservoir unit housings has a central axis of each of the plurality of post-filtered liquid reservoir unit housings at the end of each of the plurality of post-filtered liquid reservoir unit housings on the side of the exhaust chamber. A flange in the form of a first flange extending in the vertical direction and a flange at the end of each of the plurality of post-filtered liquid reservoir unit housings on the side of the storage chamber in a direction perpendicular to the central axis of the post-filtered liquid reservoir unit housing. Equipped with a flange in the form of a second flange that extends
Each of the plurality of pre-filtration liquid reservoir unit housings has a first flange form extending to the one end of each of the plurality of pre-filtration liquid reservoir unit housings in a direction perpendicular to the central axis of the pre-filtration liquid reservoir unit housing. And a flange in the form of a second flange extending in a direction perpendicular to the central axis of the pre-filtration liquid reservoir unit housing at the end opposite to the one end.
One end of the pump unit is provided with a flange in the form of a second flange extending in a direction perpendicular to the central axis of the pump unit housing.
The first flange form is a truncated cone shape having a slope that narrows downward in the vertical direction, and the second flange form is a truncated cone shape having a slope that narrows upward in the vertical direction.
Each of the plurality of coupling seal members has a wall surface having a cylindrical shape and a tab extending in the radial direction of the cylinder over the entire inner surface of the wall surface at substantially the center of the inner surface of the wall surface. It can be arranged on the flange of the second flange form so as to be sandwiched between the flange of the first flange form and the flange of the second flange form, and at that time, the flange of the first flange form is placed. It can be fitted to the flange in the form of a first flange so as to wrap around the pump unit housing, each of the plurality of pre-filtration liquid reservoir unit housings, and the plurality of post-filtration liquid reservoir unit housings. Assembled decompression type filtration device that can be combined with each.
The assembled decompression filtration device according to claim 11.
The assembled decompression type filtration device has an exhaust pipeline that connects the storage chamber and the exhaust chamber.
In a state where the plurality of pre-filtration liquid reservoir units, the plurality of post-filtration liquid reservoir units, and the pump unit are connected by the plurality of coupling seal members.
By operating the degassing pump of the pump unit, the inside of the storage chamber is degassed through the exhaust chamber by degassing the exhaust chamber of the post-filtration liquid reservoir unit from the intake hole. Assembled decompression filtration device.
The assembled decompression filtration device according to claim 12.
Each of the plurality of coupling seal members is degassed in the storage chamber by the degassing pump, so that the flange of the first flange form and the flange of the second flange form are brought into close contact with the tab. Assembled decompression type filtration device in which the bond becomes a closed bond by pressing.
The assembled decompression filtration device according to claim 13.
Each of the plurality of coupling seal members is an assembly type decompression type having an inner surface having a slope having a complementary shape matching the flange of the first flange form or the flange of the second flange form from the base of the tab. Filtration device.
The assembled decompression filtration device according to any one of claims 12 to 14.
The exhaust pipeline is an assembly-type decompression type filtration device that is bored inside a handle attached to the post-filter liquid reservoir unit so that the post-filter liquid reservoir unit can be held.