JP3929179B2 - Filtration device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention mainly relates to a filtering device used for purifying water or the like in an aquarium tank for aquatic organisms such as goldfish and tropical fish.
[0002]
[Prior art]
As a filtration device arranged for purifying water in an aquarium fish tank, for example, as disclosed in Japanese Patent Publication No. 60-7932, bubbles are generated from bubble generation means provided in a filtration case. An air lift type in which water is sucked into a filtration case and filtered due to the air lift effect has been known.
[0003]
In addition to purifying water, such a filtering device creates a fantastic sight that a large number of fine bubbles are discharged from the device and slowly rise while being dispersed, so that an excellent aesthetic is obtained. In particular, when an aquarium fish tank is used as an indoor interior or the like, it tends to be used favorably.
[0004]
[Problems to be solved by the invention]
However, the conventional air lift type filtration device has a problem that it cannot be efficiently filtered according to the environment in the water tank because the filtration capacity is constant. Furthermore, since the size is also constant, the size of the filtration device cannot be adjusted in consideration of, for example, the balance in the water tank. For this reason, there is a possibility that the aesthetic appearance may be impaired, and if importance is attached to the size balance, it may not be used depending on the type of aquarium, resulting in a problem of poor versatility.
[0005]
This invention solves the above-mentioned problems of the prior art, can adjust the filtration capacity, can improve the filtration efficiency, can be further changed in size according to the water tank, and has a good aesthetics. It aims at providing the filtration apparatus which can also acquire sufficient versatility, ensuring.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, a filtration device of the present invention has a bottom wall and a peripheral side wall provided in a rising shape on the outer peripheral edge of the bottom wall, and extends upward at the center of the bottom wall to gradually reduce the diameter. And one or more intermediate filtration units in which a filter medium is accommodated outside the discharge pipe inside the peripheral side wall, and a discharge port in the center. A lid unit having a water absorption hole on the outer periphery, a bottom wall, and a peripheral side wall provided in a rising shape on the outer peripheral edge of the bottom wall. And a bottom unit provided with a bubble generating means for generating, wherein the intermediate filtration unit is arranged alone or in a laminated form, and the lid unit has a discharge port corresponding to a discharge pipe of the intermediate filtration unit, in front Removably attached to the upper end opening of the intermediate filtration unit, the bottom unit is detachably attached to the lower end of the intermediate filtration unit with its bubble generating means corresponding to the discharge pipe of the intermediate filtration unit, Bubbles generated from the bubble generating means rise up the discharge pipe of the intermediate filtration unit and are discharged from the discharge port of the lid unit, thereby generating a water flow in each unit, and by the water flow, The water sucked from the water suction hole of the lid unit passes through the filter medium and the flow hole in the intermediate filtration unit, is guided into the bottom unit, and further rises in the discharge pipe and is discharged from the discharge port. The gist of the configuration is as follows.
[0007]
The filtration apparatus of the present invention includes one or more intermediate filtration units having a discharge pipe in the center, a lid unit disposed at the upper end of the intermediate filtration unit, and a bottom unit disposed at the lower end of the intermediate filtration unit. Therefore, for example, by increasing the number of stacked intermediate filtration units, the number of discharge pipes in the center of the filtration unit can be increased and the length of the pipe group can be increased. The amount of the filter medium through which water passes can be increased, and the filtration capacity can be increased.
[0008]
Conversely, by reducing the number of intermediate filtration units stacked, the length of the discharge pipe group can be shortened, so that the suction force can be moderately suppressed.
[0009]
Furthermore, since the size of the entire filtration device can be changed by increasing / decreasing the number of intermediate filtration units stacked, the size of the filtration device can be adjusted according to the size of the water tank.
[0010]
On the other hand, in the present invention, a water inlet that can be freely opened and closed is provided on the peripheral side wall of the intermediate filtration unit, and when the water inlet is opened, the water sucked from the water inlet becomes the intermediate filtration unit. It is preferable to adopt a configuration in which the filter medium and the flow hole are guided into the bottom unit and further raised through the discharge pipe and discharged from the discharge port.
[0011]
That is, in this case, the intake amount of water can be increased by opening the suction port, and the intake amount of water can be decreased by closing the suction port. In addition, water can be appropriately purified according to the environment in the aquarium.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
1 to 3 are exploded perspective views showing a filtration device according to an embodiment of the present invention. As shown in these drawings, the filtration device in this embodiment is composed of three types of units (10) (20) (30) each made of a transparent hard synthetic resin molded product, that is, the outer peripheral edge of the bottom wall (15). A plurality of bottomed cylindrical intermediate filtration units (10) provided with a peripheral side wall (11) in a rising shape, a disc-shaped lid unit (20), and a rising shape at the outer peripheral edge of the bottom wall (35) And a bottomed cylindrical bottom unit (30) provided with a peripheral side wall (31).
[0013]
As shown in FIGS. 8 to 12, the intermediate filtration unit (10) is formed such that the lower part of the peripheral side wall (11) is formed in a reduced diameter, and an internal fitting part (12) is provided. The inner fitting part (12) has an outer diameter dimension smaller than the inner diameter dimension of the upper end opening edge of the peripheral side wall (11), and a step part (14) at the upper end of the inner fitting part (12). It is provided, and it is comprised so that another filtration unit (10) can be laminated | stacked. That is, the inner fitting portion (10) of the upper filtration unit (10) until the upper end opening edge of the lower filtration unit (10) comes into contact with and engages with the step (14) of the upper intermediate filtration unit (10). 12) is fitted inside the peripheral side wall (11) of the lower filtration unit (10), so that both the filtration units (10) are aligned with each other in the vertical direction and rotate around the axis. It is configured so that it can be laminated in an allowed state. In the same manner, three or more filtration units (10) can be stacked.
[0014]
A flow path forming recess (12a) is formed at four locations around the inner fitting portion (12) in the filtration unit (10), and the outer surface and the lower end surface of the inner fitting portion (12) are formed by the concave portion (12a). And communicated with each other. Engaging protrusions (12b) and (12b) are integrally formed on the front and rear sides of the inner fitting portion (12) so as to protrude in the outer diameter direction.
[0015]
Further, four cutout suction ports (11a) are formed on the peripheral side wall of the filtration unit (10) corresponding to the flow path forming recess (12a), and corresponding to the engaging protrusions (12b) (12b). Thus, two engagement grooves (13) are formed.
[0016]
As shown in FIG. 13, the engaging groove (13) has an upper end opened and extends downward along the axial direction, and one end side communicates with the lower end of the introducing groove (131). The circumferential grooves (132a) (132b) on one side and the other side extending along the direction communicate with the other ends of the circumferential grooves (132a) (132b) via narrow diameter portions (133a) (133b). It is comprised by the engaging part (134a) (134b) of one side and the other side.
[0017]
As shown in FIGS. 1 and 5, when the intermediate filtration units (10) are stacked, the engagement protrusions (12b) (12b) of the upper filtration unit (10) are engaged with the lower filtration unit (10). The inner fitting portion (12) of the upper filtration unit (10) is fitted into the peripheral side wall of the lower filtration unit (10) so as to be inserted into the mating groove (13). Further, in this fitted state, the upper filtration unit (10) is rotated in the circumferential direction relative to the lower filtration unit (10), and the engagement protrusion (12b) is moved to one side as shown in FIG. 3 and FIG. 6 by moving along the circumferential groove portion (132a) and forcibly passing the narrow-diameter portion (133a) so as to be positioned at the engaging portion (134a) on one side. Furthermore, the four notch suction ports (11a) in the lower filtration unit (10) are respectively adapted to the four flow path forming recesses (12a) in the upper filtration unit (10), and the suction ports (11a) are It is comprised so that it may communicate with the inside of a lower filtration unit (10) via a flow-path formation recessed part (12a).
[0018]
In the filtration unit (10), the notch-shaped suction port (11a) and the flow path forming recess (12a) are not formed in the same cross section. However, in FIGS. In order to facilitate, the notch-shaped suction port (11a) and the flow path forming recess (12a) are formed in one cross section of the filtration unit (10).
[0019]
On the other hand, as shown in FIG. 7, in a state where the filtration units (10) are fitted to each other, the upper filtration unit (10) is rotated with respect to the lower filtration unit (10) in the opposite direction, The engagement protrusion (12b) is moved along the circumferential groove (132b) on the other side, and the narrow diameter portion (133b) is forcibly passed to be positioned at the engagement portion (134b) on the other side. 4 and 7, the lower four notch suction ports (11a) are displaced in the circumferential direction with respect to the upper four flow path forming recesses (12a), and each notch suction is performed. The mouth (11a) is configured to be closed in a watertight state by the outer surface of the inner fitting portion (12).
[0020]
The engaging protrusion (12b) of the upper filtration unit (10) is forcibly passed through the narrow diameter portions (133a) and (133b) in the engagement groove (13) of the lower filtration unit (10). By positioning the engaging portions (134a) and (134b), the engaging protrusions (12b) unintentionally pass through the narrow-diameter portions (133a) and (133b) into the circumferential grooves (132a) and (132b). It can be prevented from being guided, and is configured to prevent rotation and separation between the filtration units. Needless to say, if one of the filtration units (10) is strongly rotated in a state where the engaging protrusion (12b) is positioned at the engaging portion (134a) (134b), the engaging protrusion (12b) becomes narrow. Since it passes along diameter part (133a) (133b) and is guided to circumferential direction groove part (132a) (132b), one filtration unit (10) can be removed from the other filtration unit (10) without difficulty.
[0021]
A discharge pipe (16) whose lower end is opened to the lower side of the bottom wall (15) is integrally formed at the center of the bottom wall (15) in the intermediate filtration unit (10). The discharge pipe (16) extends upward along the axis of the filtration unit (10), and the upper end thereof is disposed above the upper end position of the peripheral side wall (11). Further, the discharge pipe (16) is formed in a taper shape so that the diameter gradually decreases toward the upper side, and the outer diameter dimension of the upper part is set smaller than the inner diameter dimension of the lower part. Thereby, as shown in FIG.3 and FIG.4, when the filtration unit (10) is laminated | stacked up and down, the upper part of the discharge pipe (16) of the lower filtration unit (10) is connected to the upper filtration unit ( 10) is arranged so as to be accommodated in the lower part of the discharge pipe (16), and the respective discharge pipes (16) are arranged in the vertical direction along the axis.
[0022]
A large number of circulation holes (15a) extending in the circumferential direction are formed outside the discharge pipe (16) in the bottom wall (15) of the filtration unit (10).
[0023]
As shown in FIGS. 14 to 18, the lid unit (20) is provided with an inner fitting peripheral side wall (22) so as to rise along the outer peripheral edge portion, and outwardly at the upper end of the peripheral side wall (22). A flange portion (21) is provided in a protruding shape. The inner fitting peripheral side wall (22) has an outer diameter dimension smaller than the inner diameter dimension of the upper end opening of the intermediate filtration unit (10), and the inner fitting peripheral side wall (22) is the intermediate filtration unit. It is comprised so that it can fit in the upper-end opening part of (10).
[0024]
At four locations around the inner fitting peripheral side wall (22) in the lid unit (20), a flow path forming recess (22a) is formed corresponding to the cutout suction port (11a) of the filtration unit (10). The outer surface and the lower end surface of the inner fitting peripheral side wall (22) are communicated with each other by the recess (22a). Engaging protrusions (22b) and (22b) are integrally formed on the front and rear of the inner fitting peripheral side wall (22) corresponding to the engaging groove (13) of the filtration unit (10).
[0025]
In addition, a discharge port (26) is formed at the center of the lid unit (20), and the peripheral portion of the discharge port (26) is integrally formed so as to rise upward, thereby forming a cylindrical knob portion (27). Is formed. A knurled portion (not shown) is provided on the outer peripheral surface of the knob portion (27) for preventing slippage.
[0026]
Furthermore, a large number of suction holes (25a) extending in the circumferential direction are formed outside the discharge port (26) in the lid unit (20).
[0027]
As shown in FIGS. 1 and 5, the lid unit (20) configured as described above has the engagement protrusions (22 b) and (22 b) inserted into the engagement grooves (13) and (13) of the filtration unit (10). As described above, the inner fitting peripheral side wall (22) of the lid unit (20) is fitted into the upper end opening of the filtration unit (10), and the collar (21) of the lid unit (20) is fitted to the filtration unit (10). The lid unit (20) is configured to be fitted in a state in which the upper end opening of the intermediate filtration unit (10) is closed. In this closed state, the upper end of the discharge pipe (16) in the filtration unit (10) is arranged so as to face the discharge port (26) of the lid unit (20).
[0028]
Further, in this closed state, the lid unit (20) is rotated in the circumferential direction relative to the filtration unit (10), and the engagement protrusion (22b) is moved to the circumferential groove (132a) on one side as shown in FIG. ), And forcibly passing the narrow-diameter portion (133a) through the engagement portion (134a) on one side, as shown in FIG. 3 and FIG. ) Fit into the four flow path forming recesses (22a) in the lid unit (20), and the notch suction port (11a) flows into the filtration unit (10). It is comprised so that it may communicate via a path formation recessed part (22a).
[0029]
Further, as shown in FIG. 7, the lid unit (20) is rotated with respect to the filtration unit (10) in the opposite direction to the above, and the engaging protrusion (22b) is formed in the circumferential groove (132b) on the other side. In the state where the narrow-diameter portion (133b) is forcibly passed through and moved to the engaging portion (134b) on the other side, as shown in FIG. 4 and FIG. (11a) is displaced in the circumferential direction with respect to the flow path forming recess (22a), and each notch-shaped suction port (11a) is closed in a watertight state by the outer surface of the inner peripheral wall (22). It is configured as follows.
[0030]
In the lid unit (20), the engagement protrusion (22b) is filtered by forcibly passing the narrow diameter portions (133a) (133b) in the engagement groove (13) of the filtration unit (10). The unit (10) is configured to be prevented from being rotated and retained.
[0031]
As shown in FIGS. 19 to 21, the bottom unit (30) has an upper portion of the peripheral side wall (31) formed in an enlarged diameter to form an outer fitting portion (32). The outer fitting portion (32) is formed so that the inner diameter dimension thereof is larger than the outer diameter dimension of the inner fitting portion (12) of the filtration unit (10). A part (34) is formed.
[0032]
Furthermore, the engagement groove | channel (33) is formed in the front-back position of the surrounding side wall (31) in a bottom unit (30) corresponding to the engagement protrusion (12b) (12b) of the filtration unit (10). As shown in FIG. 22, the engagement groove (33) is connected to the introduction groove part (331) that is open at the upper end and extends downward along the axial direction, and the one end side communicates with the lower end of the introduction groove part (331). The circumferential groove portion (332) extending along the direction and the engaging portion (334) communicating with the other end side of the circumferential groove portion (332) via the narrow diameter portion (333).
[0033]
In the center of the bottom wall (35) of the bottom unit (30), a bubble generating means mounting cylindrical portion (37) is provided, and in this cylindrical portion (37), bubbles generated of a porous body are generated. The lower part of the means (40) is fixed in the fitted state.
[0034]
Further, an air supply tube insertion recess (31a) is formed in the lower part of the peripheral side wall (31) in the bottom unit (30), and an air supply tube insertion recess (in the bottom wall (35) of the bottom unit (30)). An air supply path (38) is formed that communicates the inside of 31a) with the inside of the bubble generating means mounting cylindrical portion (37).
[0035]
The end of the air supply path (38) on the recess (31a) side is configured as a tube insertion pipe (38a) so that the end of the air supply tube can be inserted.
[0036]
The bottom wall (35) of the bottom unit (30) is provided with a plurality of ribs (39) along the circumferential direction corresponding to the outer periphery of the bubble generating means (40).
[0037]
As shown in FIGS. 1 to 4, the bottom unit (30) having the above configuration is configured such that the outer peripheral edge of the bottom wall of the intermediate filtration unit (10) comes into contact with the step (34) of the bottom unit (30). Until the filter unit (10) is attached to the bottom unit (30) by fitting the inner fitting (12) of the filter unit (10) into the upper end opening of the bottom unit (30). It is configured so that the cores can be stacked in a state where the centers coincide with each other in the vertical direction and rotation around the axis is allowed. In this laminated state, the bubble generating means (40) of the bottom unit (30) is accommodated in the lower part of the discharge pipe (16) of the filtration unit (10).
[0038]
Further, in this laminated state, the filtration unit (10) is rotated with respect to the bottom unit (30), and the engagement protrusion (12b) of the filtration unit (30) is moved to the circumferential groove (332) of the bottom unit (30). , And forcibly passing the narrow-diameter portion (333) to be positioned at the engaging portion (334), thereby preventing the unit (10) (30) from being detached and preventing rotation. Can do.
[0039]
The filtration apparatus of this embodiment is comprised by said each unit (10) (20) (30), these are assembled, and it is used for the water purification of an aquarium fish tank, for example.
[0040]
That is, as shown in FIGS. 1 to 4, pebbles (50) and the like are spread outside the bubble generating means (40) in the bottom unit (30), and the discharge pipes (16) in each intermediate filtration unit (10). The filter medium (60) is filled on the outside of the filter unit, and as described above, an appropriate number of intermediate filtration units (10) are stacked on the bottom unit (30), and the uppermost filtration unit (10) is stacked. The lid unit (20) is attached to the upper end opening of
[0041]
The filtration device thus assembled is fixed by inserting one end of an air supply tube into the tube insertion pipe (38a) of the bottom unit (30) and connecting the other end of the tube to an air pump. And place it on the bottom of the water tank.
[0042]
When air is supplied to the bubble generating means (40) by the operation of the air pump, a large number of fine bubbles are generated from the bubble generating means (40), and the bubbles pass through the discharge pipe (16) of each intermediate filtration unit (10). It goes up sequentially, passes through the discharge pipe (16) of the uppermost filtration unit (10), and is discharged from the discharge port (26) of the lid unit (20) into the water tank. Further, together with the bubbles, the water in the discharge pipe (16) rises and is discharged from the discharge port (26). As a result, the pressure in the discharge pipe (16) becomes negative, and the discharge pipe (16) in the lowermost stage is discharged. A suction force is generated on the lower end side.
[0043]
At this time, as shown in FIG. 4 and FIG. 7, in the state where the notch-like suction port (11a) provided in the peripheral side wall (11) of the intermediate filtration unit (10) is closed, After water passes through the suction hole (25a) of the lid unit (20), is guided into the uppermost filtration unit (10), passes through the filter medium (60) and is filtered, the water flows through the bottom wall (15). It passes through the hole (15a) and is sequentially led to the lower filtration unit (10). The water thus passed through the filter medium (60) in each filtration unit (10) is guided into the bottom unit (30) through the flow hole (15a) of the lowermost filtration unit (10). It is sucked in from the lower end of the lowermost discharge pipe (16), rises up each discharge pipe (16), and is discharged from the discharge port (26) of the lid unit (20).
[0044]
On the other hand, as shown in FIGS. 3 and 6, in a state where the notch-like suction port (11a) in the peripheral side wall (11) of the intermediate filtration unit (10) is opened, in parallel with the flow of water, Water in the water tank is taken into each filtration unit (10) from the notch-shaped suction port (11a) of each filtration unit (10), passes through each filtration unit (10) downward, and passes through a filter medium ( 60) and then led into the bottom unit (30) and discharged through the discharge pipe (16).
[0045]
As described above, since the filtration device of the present embodiment is configured to be capable of stacking one or more intermediate filtration units (10), the filtration unit can be increased by increasing the number of laminations of the intermediate filtration units (10). Since the length of the pipe group can be increased by increasing the number of discharge pipes (16) provided in the center of (10), the suction force can be increased and the filter medium (60) through which water passes can be increased. The amount can be increased and the filtration capacity can be increased. Furthermore, the suction force can be moderately suppressed by reducing the number of layers of the filtration units (10). Since the filtration capacity and suction force can be freely adjusted as described above, water can be appropriately purified according to the environment in the water tank, for example, and the filtration efficiency can be improved.
[0046]
Furthermore, since the size of the entire filtration device can be changed by increasing or decreasing the number of stacked intermediate filtration units (10), the size of the filtration device can be adjusted according to the size of the water tank. In addition to being able to maintain a good aesthetic appearance, it can be used without any problems regardless of the size of the aquarium, and is therefore excellent in versatility.
[0047]
Moreover, in this embodiment, since the suction opening (11a) which can be opened and closed is formed in the surrounding side wall (11) of the intermediate | middle filtration unit (10), taking in water by opening a suction opening (11a). The amount of water can be increased and the amount of water taken in can be reduced by closing the suction port (11a). In this respect as well, water is appropriately purified according to the environment in the aquarium. And the filtration efficiency can be further improved. Furthermore, since the intake amount of water can be adjusted by opening and closing the suction port (11a), the flow velocity can also be adjusted.
[0048]
In addition, since the suction port (11a) can be opened and closed for each filtration unit (10), for example, if only the suction ports (11a) of some filtration units (10) are opened, The amount of intake and the flow rate can be finely adjusted, and the filtration efficiency can be further improved.
[0049]
Needless to say, in the present invention, the number of filtration units used is not limited to two, and may be one or three or more.
[0050]
【The invention's effect】
As described above, according to the filtration device of the present invention, the lid unit is provided at the upper end opening of the intermediate filtration unit that is singly or stacked, and the bottom unit is provided at the lower end. By changing the number of layers, the filtration capacity can be adjusted, and the filtration efficiency can be improved. Furthermore, since the size of the filtration device itself can be changed by increasing or decreasing the number of laminated intermediate filtration units, the size of the filtration device can be set according to the size of the water tank, etc. Can be ensured, and can be used without any problem regardless of the size of the aquarium.
[0051]
On the other hand, in the present invention, when a suction port that can be freely opened and closed is provided on the peripheral side wall of the intermediate filtration unit, the amount of water taken in can be adjusted by opening and closing the suction port. According to the above, there is an advantage that water can be purified more appropriately and the filtration efficiency can be further improved.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view showing a filtration device according to an embodiment of the present invention.
FIG. 2 is an exploded cross-sectional view of the filtration device of the embodiment.
FIG. 3 is a cross-sectional view showing the filter device of the embodiment in a state where the side suction port is opened.
FIG. 4 is a cross-sectional view showing the filter device of the embodiment with its side suction port closed.
FIG. 5 is a partially cutaway front view showing the filtration device of the embodiment.
FIG. 6 is a partially cutaway front view showing the filter device of the embodiment with the side suction port opened.
FIG. 7 is a partially cutaway front view showing the filter device of the embodiment with its side suction port closed.
FIG. 8 is a plan view showing an intermediate filtration unit of the filtration device in the embodiment.
FIG. 9 is a bottom view showing the intermediate filtration unit of the embodiment.
FIG. 10 is a front view showing the intermediate filtration unit of the embodiment.
11 is a cross-sectional view taken along the line PP in FIG.
12 is a cross-sectional view taken along line QQ in FIG.
FIG. 13 is an enlarged front view showing the vicinity of the engagement groove in the intermediate filtration unit of the embodiment.
FIG. 14 is a plan view showing a lid unit of the filtration device according to the embodiment.
FIG. 15 is a bottom view showing the lid unit of the embodiment.
FIG. 16 is a front view showing the lid unit of the embodiment.
17 is a cross-sectional view taken along line RR in FIG.
18 is a sectional view taken along line SS of FIG.
FIG. 19 is a plan view showing a bottom unit of the filtration device in the embodiment.
FIG. 20 is a front view showing the bottom unit of the embodiment.
21 is a cross-sectional view taken along line TT in FIG.
FIG. 22 is an enlarged front view showing the vicinity of the engagement groove in the bottom unit of the embodiment.
[Explanation of symbols]
10 ... Intermediate filtration unit
11 ... peripheral side wall
11a ... Notch suction port
15 ... Bottom wall
15a ... circulation hole
16 ... discharge pipe
20 ... Lid unit
25a ... Suction hole
26 ... discharge port
30 ... Bottom unit
31 ... Surrounding side wall
35 ... Bottom wall
40: Bubble generating means
60 ... filter material

Claims (2)

A bottom wall and a peripheral side wall provided in a rising shape at the outer peripheral edge of the bottom wall, and a tapered discharge pipe extending upward and gradually reducing in diameter is provided at the center of the bottom wall, and the bottom wall outer periphery 1 to a plurality of intermediate filtration units in which a flow hole is provided, and a filter medium is accommodated outside the discharge pipe inside the peripheral side wall;
A lid unit having a discharge port in the center and a water absorption hole in the outer periphery;
It has a bottom wall and a peripheral side wall provided in a rising shape on the outer peripheral edge of the bottom wall, and includes a bottom unit provided with bubble generating means for generating bubbles by supplying air at the center of the bottom wall,
The intermediate filtration unit is arranged alone or in a laminated form,
The lid unit is detachably attached to the upper end opening of the intermediate filtration unit, with the discharge port corresponding to the discharge pipe of the intermediate filtration unit,
The bottom unit is detachably attached to the lower end of the intermediate filtration unit, with the bubble generating means corresponding to the discharge pipe of the intermediate filtration unit,
Bubbles generated from the bubble generating means rise up the discharge pipe of the intermediate filtration unit and are discharged from the discharge port of the lid unit, thereby generating a water flow in each unit. The water sucked from the water suction hole of the lid unit passes through the filter medium and the flow hole in the intermediate filtration unit, is guided into the bottom unit, and further rises in the discharge pipe and is discharged from the discharge port. A filtration device configured to be configured as described above. A water suction port that can be freely opened and closed is provided on the peripheral side wall of the intermediate filtration unit. The filtration device according to claim 1, wherein the filtration device is configured to pass through the bottom unit and further rise in the discharge pipe and be discharged from the discharge port.

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