JPH07195094A - Septic device - Google Patents

Abstract

PURPOSE:To efficiently improve proliferation of microorganisms, such as bacteria and to improve the purifying capacity of a purifying device by packing many small balls of uniform sizes specified in radius into a vessel of a septic tank and applying a specific or higher pressure on the inside of the septic tank. CONSTITUTION:This septic device is used for purifying the water 2 of a water tank 1 for breeding, for example, aquarium fishes and is composed of a septic tank vessel body 6 installed atop water tank 1. Bottom sand 3 is packed in addition to the water 2 in the inside of the water tank 1. Further, the septic tank vessel body 6 circulates the water with the water tank 1 via plural pipes 4, 7, 13 by a pump 5 and purifies the water. In such a case, the many small balls 12 of the uniform sizes specified in the radius within the range of 0.5 to 5mm are packed in the septic tank vessel body 6. The pump 5 is so designed as to apply the pressure of at least the range of 30g/cm<2> into the septic tank vessel body 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a purifying device for purifying water in a water tank for holding ornamental fish and a container such as a cage for holding live fish.

[0002]

2. Description of the Related Art Conventionally, an aquarium for keeping ornamental fish is provided with a purifying device for biodegrading (biological filtration) ammonia components and Escherichia coli excreted from the ornamental fish in the aquarium. This purifying device is provided with a purifying tank filled with a large number of ceramic balls whose surfaces are sparsely formed. Ceramic spheres used as a purification medium in this conventional septic tank have a radius of about 5 mm or more (see, for example, JP-A-59-4493). When starting the use of the ornamental fish tank, first, a concentrated solution of bacteria is put into this septic tank so that the bacteria grow on the surface of the ceramic sphere. After the bacteria have successfully grown, when the water in the water tank passes through this purification tank, the bacteria that have grown on the surface of the ceramic spheres oxidize and decompose the ammonia component and the like. Specifically, ammonia is decomposed into nitrite by bacteria, and nitrite is decomposed into nitric acid (harmless) by other kinds of bacteria.

Further, in the conventional purifying device, a pump is provided on the outlet side of the purifying device in order to circulate the water in the water tank. Conventionally, this pump is installed on the outlet side of the purifier, but if a pump is installed on the inlet side of the purifier, it will also send debris in the water to the septic tank, and the septic tank will not be clogged. This is because there is a possibility that it may occur.

[0004]

However, in the conventional purification apparatus using such ceramic spheres,
The efficiency of bacterial growth after adding the bacterial concentrated solution to the septic tank is extremely poor. Therefore, it is not uncommon for the nitrous acid to fill the water tank due to insufficient decomposition of the ammonia component in the water tank. When nitrite fills the aquarium, the user has to drain all the water in the aquarium, clean the aquarium, replace the water with a new one, and start over from the first step of adding the bacterial concentrate to the septic tank. It was

The present invention has been made in view of the above problems of the conventional purifying apparatus, and an object of the present invention is to provide a purifying apparatus capable of remarkably improving the growth efficiency of microorganisms such as bacteria. And

[0006]

A purifying apparatus of the present invention for achieving the above object has a uniform container having a radius of 0.5 to 5 mm in a container which is closed except for a water inlet and a water outlet. It includes a septic tank provided with a large number of small spheres, and a pressurizing means for applying a pressure of at least 30 g / cm 2 or more to the septic tank.

Further, in the purifying apparatus of the present invention, it is desirable that the small spheres are true spheres or almost true spheres.

Further, in the purifying apparatus of the present invention, the septic tank is filled with the small balls, and the pressurizing means comprises:
At least 30 g / cm @ 2 of water in the septic tank
It is desirable to be configured by a pump that applies the above pressure and sends it.

Further, the purifying apparatus of the present invention preferably further comprises a filtering device for filtering the water in the container sent to the septic tank before being sent to the septic tank.

Further, in the purifying apparatus of the present invention, it is desirable that the small spheres are made of a smooth material whose surface is not sparse.

Further, in the purifying apparatus of the present invention, it is desirable that the small balls are made of glass or plastic.

[0012]

As described above, in the purifying device of the present invention,
The small spheres as a purification medium filled in the septic tank are extremely small spheres having a radius of 0.5 to 5 mm. Therefore, an extremely large number of small spheres can be provided even in a septic tank having a fixed capacity. As a result, it is possible to form an extremely large number of gaps between the small balls in one septic tank.
In the present invention, the growth of microorganisms such as bacteria is
Although it is the surface of the small spheres in these gaps, in the present invention, these gaps are formed in an extremely large number as described above, and accordingly, the places where bacteria and the like proliferate are also formed in an extremely large number. Therefore, according to the present invention, bacteria and the like can be propagated extremely efficiently.

Further, since a large number of small spheres having a uniform shape and size are filled in the septic tank, a large number of gaps having a uniform shape and size are regularly provided between these small spheres. Will be placed. Therefore, the water in the water tank can relatively easily pass through the septic tank by passing through the large number of regularly arranged uniform gaps. (On the other hand, when the septic tank with non-uniform shape and size is filled in the septic tank, the small purifying medium gets into the gap between the large purifying media and the gap is almost eliminated. It may not be possible to easily pass through the septic tank).

Further, in the purifying apparatus according to the present invention, the small spheres provided in the septic tank are formed to have the same size. Therefore, a large number of minute gaps formed between these small spheres also have the same shape and size. Further, in the present invention, the septic tank is sealed except for the water outlet and the water inlet. Therefore, the pressure of at least 30 g / cm 2 or more is uniformly applied to the septic tank by the pressurizing means, and as a result, the pressure is evenly applied to the mutually equal gaps. .
Also, the water in the water tank is allowed to pass through each of the gaps,
Since each of these gaps is equal to each other as described above, the water passing state such as the water passing speed can be kept equal to each other. Therefore, in the present invention, an environment suitable for the growth of bacteria and the like can be evenly formed in a large number of gaps. Therefore,
Propagation of bacteria and the like becomes extremely efficient.

Further, in the purifying apparatus of the present invention, since the small spheres are true spheres or substantially true spheres, the shape and size of the gaps between the respective small spheres are formed with high precision and evenly. Like Therefore, an environment suitable for the growth of bacteria and the like can be realized evenly in all the gaps.

Further, in the purifying apparatus of the present invention, the pressurizing means is constituted by a pump for feeding the water in the container into the purifying tank by applying a pressure of at least 30 g / cm 2 or more. Therefore, the pump for circulating the water in the container can be used to simultaneously circulate the water and pressurize the septic tank, thereby improving the efficiency of the entire apparatus. .

Further, the purifying apparatus of the present invention further comprises a filtering device for filtering the water in the container sent to the septic tank before being sent to the septic tank, so that the septic tank may be clogged. Absent.

Further, in the purifying apparatus of the present invention, since the small spheres are made of a smooth material whose surface is not sparse,
It becomes easy to form the small spheres as the purification medium into a true sphere or a substantially true sphere.

Further, in the purifying apparatus of the present invention, since the small spheres are formed of glass or plastic, it is extremely easy to form the small spheres as the purifying medium into a true sphere or a substantially true sphere. And it will be possible at low cost.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to illustrated embodiments. FIG. 1 is a schematic diagram showing a purifying device according to an embodiment of the present invention and an aquarium for ornamental fish equipped with the purifying device, and FIG.
FIG. 3 is a plan view showing the configuration of the purifying device of FIG. 3, and FIG. 3 is a perspective view showing the main body part of the septic tank of the purifying device of FIG. In FIG. 1, reference numeral 1 is a water tank, 2 is water in the water tank 1, 3 is bottom sand spread on the bottom in the water tank 1, 4 is a pipe fed into the bottom sand 3, and 5 is a pipe 4. It is a pump. In the present embodiment, this pump 5 is, for example, a product name “Spare pump SQ05 (lifting force: 60 cm / cm) of Nisso Corporation.
2) ”) is used. Further, in this embodiment, the water tank 1
The water 2 therein is pumped up by the pump 5 through the pipe 4, and in this case, a filter 4a such as cotton is provided at the lower end of the pipe 4 so that the bottom sand 3 does not rise in the pipe 4 together. .

Further, in FIG. 1, FIG. 2 and FIG.
Is the container body of the septic tank connected to the pump 5 via the pipe 7. The septic tank container body 6 is made of, for example, plastic and is actually composed of an opaque member, but in FIG. Next, in FIG. 1, reference numeral 8 indicates a plurality of partition plates (six in total) protruding from the bottom of the main body 6 of the septic tank container (see FIG. 3).
Reference numeral 9 denotes a partition plate which is downwardly projected (a total of 5 pieces) from the lower surface of the intermediate plate 16 attached to the upper part of the septic tank container 6, and 10 denotes a filter provided on the water inlet side of the septic tank container 6. Cotton, 11 is a filtering cotton provided on the outlet side of the septic tank 6, and 12 is a large number of small microspheres in a space surrounded by each of the cotton 10, 11 of the septic tank 6 and the bottom surface and the top surface. Are filled in (in FIG. 2, these small spheres 12 are shown for convenience.
Is not shown). In this embodiment, the small balls 12
Is a glass sphere having a radius of 0.5 to 5 mm, for example, a glass sphere having a radius of 2 mm. Further, in this embodiment, a user or the like can put a concentrated liquid of microorganisms such as bacteria in the septic tank filled with the small balls 12 before using the water tank. In the present embodiment, as will be described later in detail, the bacteria and the like grow extremely efficiently on the surface of the large number of small balls 12.

In FIG. 1, reference numeral 13 is a pipe 13 provided on the outlet side of the septic tank 6, and the purified water from the septic tank 6 is returned from the pipe 13 into the water tank 1. In FIG. 1, reference numeral 14 is a rubber packing, 15 is an upper lid for sealing the inside of the septic tank container 6,
The upper lid 15 includes the septic tank container body 6 and the intermediate plate 1 described above.
It is fixed by screws (not shown) via 6 and the rubber packing 14. Further, in FIG. 3, reference numeral 6a is a pump mounting portion for mounting the pump 5 thereon.

Next, the operation of this embodiment will be described with reference to FIG. In the present embodiment, a large number of small balls 12 are filled in the septic tank body 6, and a concentrated liquid of microorganisms such as bacteria is put in advance. And the water 2 in the aquarium 1
Is pumped upward by the pump 5 through the pipe 4 while being filtered to some extent by passing through the bottom sand 3. At this time, the filter 4a prevents the bottom sand 3 from being pumped up by the pump 5. Pump 5
The water 2 pumped up by is sent to the septic tank container 6 through the pipe 7. At this time, the pump 5 is 30 g /
The water 2 is pushed into the septic tank 6 with a pressure of cm 2 or more, for example, a pressure of 80 g / cm 2. Therefore, this pressure is evenly applied to the entire inside of the septic tank container 6 which is closed as described above. The water 2 pushed by the pump 5 is first filtered by the cotton 10 and sent into the purification layer filled with the small balls 12. As described above, in this embodiment, the water 2 in the water tank 1 is sent to the purification layer in a state of being filtered by the bottom sand 3, the filter 4a, and the cotton 10, so that the purification layer is not likely to be clogged. ing.

Next, the water 2 that has passed through the cotton 10 is sent to the portion filled with the small balls 12 with a predetermined pressure. The pressure from the pump 5 is applied to the purification layer portion filled with the small balls 12, but since the purification layer container 6 is closed by the upper lid 15 as described above, a uniform pressure is applied to the entire purification layer. Addition (Conventionally, a structure in which the purification layer is sealed is known, but such a conventional configuration is to prevent water from spilling from the purification layer when the purification layer is taken out of the tank. (It is not known to provide a closed structure to equalize the pressure inside the purification layer as in the embodiment). Further, in this embodiment, in the portion where the small spheres 12 of the purification layer container 6 are filled, the six partition plates 8 from the bottom of the septic tank container body 6 and the five partition plates from the intermediate plate 16 above. 9 and 9 are projected alternately. Therefore, the water 2 moves in the purification layer from the right side to the left side in the drawing due to the pressure from the pump 5, but the partition plates 8 and 9 cause an approximately S-shape as shown by an arrow in FIG. It is designed to move while repeating the same flow.

In this embodiment, the small spheres 12 provided in the septic tank 6 are, for example, extremely small spheres having a radius of 2 mm. Therefore, a large number of small spheres 12 are provided in the septic tank 6 having a predetermined volume. Can be filled, each small ball 1
Since a large number of gaps (see reference numeral 18 in FIG. 4) between the two exist, the water 2 in the water tank 1 passes through the large number of the gaps 18 to relatively easily pass through the septic tank 6. It is possible (for example, radius 5
If a purifying medium having a relatively large size of mm or more is filled in the purifying tank, water in the water tank may not easily pass through the purifying tank).

The water 2 is made into small balls 12 by the pressure of the pump 5.
The ammonia and nitrite components contained in the water 2 are biodegraded by microorganisms such as bacteria that have grown on the surface of each small sphere 12 in the process of moving through the gap between them. The purified water 2 is further filtered by the cotton 11 and returned to the water tank 1 through the pipe 13. In the present embodiment, the above operation is continuously repeated by the pump 5.

Next, the operation of multiplying microorganisms such as bacteria in the septic tank of this embodiment will be described. In this embodiment, in the septic tank main body 6 in which the concentrated liquid of microorganisms such as bacteria is put, as described above, a large number of small balls 1 are previously prepared.
2 is filled. Since these small spheres 12 are, for example, extremely small true spheres having a radius of 2 mm, an extremely large number of small spheres are provided in this septic tank.
As a result, extremely large gaps 18 are formed between the small balls 12 in the septic tank of this embodiment, as shown in FIG. In the present embodiment, the place where microorganisms such as bacteria grow is the surface 12a (see FIG. 4) of the small spheres 12 in these gaps 18, but in this embodiment, these gaps 18 are as described above. Since it is formed in a very large amount, the place where bacteria and the like proliferate (the above-mentioned small spherical surface 12a) is also formed in an extremely large amount.
Therefore, according to the present invention, bacteria and the like can be propagated extremely efficiently.

Further, in this embodiment, the small spheres 12 provided in the septic tank container 6 are formed to have the same size. Therefore, the large number of minute gaps 18 formed between the small balls 12 also have the same shape and size (see FIG. 4). In this embodiment, the septic tank container 6
Is closed by an upper lid 15 except for the water outlet and the water inlet. Therefore, in the septic tank container 6, the pump 5
Pressure of at least 30 g / cm2 or more, for example 8
0 g / cm2 is evenly added. As a result, this pressure is evenly applied to each of the gaps 18 which are equal to each other. The water 2 in the water tank 1 is allowed to pass through the gaps 18. However, since the gaps 18 are equal to each other as described above, the passage state of the water 2 such as the passage speed of the water 2 is as follows. The inside of this septic tank container 6 is kept uniform throughout.

By the way, the inventor of the present invention has found through many experiments that the bacteria and the like are allowed to survive under a pressure of at least 30 g / cm 2 or more, preferably 50 g / cm 2 or more, without applying the pressure. It was found that the efficiency of proliferation was much higher than that of the condition (the other conditions were the same).

Further, in the experiment of the present inventor, the conventional radius of 5
When a small sphere having a diameter of mm or more is used as a purification medium for the growth of bacteria and the like, and when a small sphere having a radius of 2 mm in this example is used, the radius is 0.5 to 5 mm (preferably 2 to 5 mm).
Comparing with the case of using 3 mm) small spheres as a purification medium, it was discovered that the latter markedly improves the growth efficiency of bacteria and the like. This is related to the fact that the small spheres having a small radius cause the number of gaps formed between the small spheres to be remarkably larger than the case where the small spheres having a large radius are used. That is, it is considered that bacteria and the like propagate on the surface of the small spheres in the gaps, so that the larger the number of the gaps, the higher the efficiency of growth of the bacteria and the like. Therefore, the small spheres as the purification medium have a radius of 0.
It is desirable to use a relatively small one of 5 to 5 mm (preferably 2 to 3 mm). According to the experiments by the present inventor, the desirable radius size of the small sphere 12 is preferably within the range of 0.5 to 5 mm, but the optimum size is related to the size of the aquarium 1. . That is, if the water tank 1 is small, the size of the small balls 12 is preferably relatively small, and if the water tank 1 is large, the size of the small balls 12 may be relatively large.

Further, in the experiment of the present inventor, the sphericity was measured using a conventional commercially available ceramic sphere having a radius of about 2 mm and bacteria and the like, and a glass sphere or a plastic sphere having a radius of 2 mm according to this embodiment. It was discovered that the latter has a markedly improved growth efficiency when the bacteria and the like are grown using a high strain. These experimental results indicate that conventional ceramic spheres are probably difficult to make with high sphericity, resulting in large variations in sphericity. It is related to the fact that it is difficult to make a large number of them, and that there is considerable variation in the size of their radii.

That is, according to the experiments of the present inventor, it is desirable that the minute gaps 18 as shown in FIG. This is because, if the sizes and shapes of the gaps 18 are equal to each other, the pressure applied by the pressurizing means such as the pump 5 can also be applied uniformly to all of the gaps 18. The state of water moving in the purification layer due to the pressure (moving speed of water, etc.) is also equal in all the gaps 18. In this way, the uniform state in each gap 18 means that the environment for breeding bacteria and the like is uniform in all the gaps 18, which is a very desirable state for the growth of bacteria and the like. It is considered to be.

As described above, according to the experiments of the present inventor, in order to create an optimal environment for the growth of bacteria and the like, the minute gaps 18 as described above are formed to have the same size and shape. Can be said to be desirable. And the gap 1
In order to form 8 in a uniform size and shape, small balls 12
Must be as close to a true sphere as possible. Further, the present inventor conducted an experiment of bacterial growth mainly using glass or plastic spheres, and obtained extremely good results. As can be derived from these results, it can be said that it is desirable that the small spheres 12 are formed of a material (glass, plastic, etc.) having a smooth surface rather than a sparse surface such as ceramics. Further, in order to form a large number of small spheres having a high sphericity and mutually equal sizes as described above, it is easy to form a material having a smooth surface instead of ceramics, etc. Forming with a plastic or the like has advantages that the manufacturing is easy and the manufacturing cost is low.

Conventionally, a purification medium for growing bacteria and the like has a larger area for breeding bacteria and the like because the area for breeding bacteria and the like is larger if it is made of ceramic or cement whose surface is sparse. It was said to be good.
For this reason, the purification medium is usually formed by using a material such as ceramic or cement whose surface is sparse (see, for example, JP-A-59-4493). However, the experimental results of the present inventor show that the case where a spherical surface formed by using a material such as glass or plastic having a smooth surface is used as the purification medium (in addition, a predetermined pressure is applied) The efficiency of proliferation is remarkably improved, and the result is completely opposite to the conventional common sense as described above.

When a conventional ceramic sphere or the like is used as a purification medium, the growth efficiency of bacteria and the like is poor. Therefore, if the user newly purchases an aquarium of ornamental fish,
Conventionally, ammonia contained in water in the aquarium and nitrous acid generated by decomposition of ammonia are not easily decomposed by bacteria etc., the aquarium is filled with nitrous acid, the ornamental fish die and the aquarium turns red. It wasn't the least. In this case, conventionally, it has been necessary to replace all the water in the water tank with a new one and start over from the beginning. But,
In the experiment of the present inventor, when the purifying apparatus of the present embodiment is used, even if the water tank is filled with nitrous acid and the inside of the water tank becomes red as described above, the water is not replaced as it is, and the present embodiment is performed. It was found that if the pump of the example was driven and water was continuously circulated while passing through the purification device, nitrite was decomposed into harmless nitric acid in about 2 weeks, and the ornamental fish could be raised. This indicates that the efficiency of the growth of bacteria and the like is extremely high when this example is used.

Further, in the experiment using the purification apparatus of this embodiment, the bacterial growth efficiency was extremely high, and when aerobic bacteria decomposed ammonia or nitrous acid, a large amount of oxygen was taken in and a large amount of carbon dioxide gas was discharged. It became so.
Due to the large amount of carbon dioxide gas discharged, aquatic plants (seagrass) have started to propagate in the aquarium. Conventionally, it has been said that it is extremely difficult to reproduce aquatic plants in a small-sized aquarium for home use because the amount of carbon dioxide gas is small, but it is possible to reproduce aquatic plants by using this example. It can be said that this is one of the excellent effects of this embodiment.
As described above, when the purifying apparatus of the present embodiment is used, since a large amount of carbon dioxide gas is generated in the aquarium due to the growth of bacteria, in order to supply the oxygen necessary for the survival of the ornamental fish into the aquarium, the air is used. It is desirable to use rations together.

In this embodiment, the pump 5 is used to apply a pressure of 30 g / cm 2 or more in the septic tank 6, but the pressurizing means of the present invention is not limited to this. You may comprise by the apparatus etc. which compresses the volume of the whole purification layer. Further, in the present embodiment, the small spheres 12 are filled in the purification layer, but in the present invention, it is not always necessary to fill, and it is possible to provide a large number of small spheres in the purification layer.
The effects as described above can be produced.

[0038]

As described above, in the purification apparatus of the present invention, a large number of small spaces (gap between the respective small balls) suitable for the growth of microorganisms such as bacteria can be formed in the purification layer. Therefore, the efficiency of growth of bacteria and the like can be dramatically increased. In addition, as a result, if the ornamental fish died due to nitrite filling in the ornamental fish tank,
Although it was necessary to replace all the water in the aquarium, when using the purification device of the present invention, by continuing to purify the water filled with nitrous acid after the ornamental fish has died, within a few weeks, Nitrite is completely decomposed by the grown bacteria, etc., and it can be changed into an environment where ornamental fish can grow. Further, when the purification device of the present invention is used, the growth of bacteria and the like is made extremely efficient, so that it is possible to generate a large amount of carbon dioxide gas in the aquarium by the growth of bacteria and the like, and to aquatic plants in a domestic aquarium. It becomes possible to breed.

Further, in the purifying apparatus of the present invention, the small spheres are formed as true spheres or substantially true spheres, so that the shape and size of the gap between the respective small spheres are formed with high precision and evenly. It is possible to increase the efficiency of the growth of bacteria and the like.

Further, in the purifying apparatus of the present invention, the pressurizing means is constituted by a pump for feeding the water in the container into the purifying tank by applying a pressure of at least 30 g / cm 2 or more. Therefore, the pump for circulating the water in the container can be used to simultaneously circulate the water and pressurize the septic tank, thereby improving the efficiency of the entire apparatus. .

Further, in the purifying apparatus of the present invention, further, by providing the filtering apparatus for filtering the water in the container sent to the septic tank before being sent to the septic tank, there is no possibility that the septic tank is clogged. .

Further, in the purifying apparatus of the present invention, the small spheres, which are the purifying medium, can be easily formed into a true sphere or a substantially true sphere by forming the small spheres from a smooth material having a non-dense surface. become.

Further, in the purifying apparatus of the present invention, by forming the small spheres with glass or plastic,
It becomes possible to form the small spheres that serve as the purification medium into a true sphere or a substantially true sphere very easily and at low cost.

[Brief description of drawings]

FIG. 1 is a schematic view showing a purification device according to an embodiment of the present invention and an aquarium for aquarium fish using the purification device.

FIG. 2 is a plan view showing the purification device of FIG.

3 is a perspective view showing a purification layer container body of the purification device in FIG. 1. FIG.

FIG. 4 is a diagram for explaining the operation of the present embodiment.

[Explanation of symbols]

 1 Water Tank 2 Water 3 Bottom Sand 4, 7, 13 Pipe 5 Pump 6 Purification Layer Container Body 8, 9 Partition Plate 10, 11 Cotton 12 Small Ball 12a Small Ball Surface 18 Gap 15 Upper Layer of Purification Layer Container

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[Procedure amendment]

[Submission date] January 6, 1994

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

[Title of Invention] Purification device

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a purifying device for purifying water in a water tank for holding ornamental fish and a container such as a cage for holding live fish.

[0002]

2. Description of the Related Art Conventionally, an aquarium for keeping ornamental fish is provided with a purifying device for biodegrading (biological filtration) ammonia components and Escherichia coli excreted from the ornamental fish in the aquarium. This purifying device is provided with a purifying tank filled with a large number of ceramic balls whose surfaces are sparsely formed. Ceramic spheres used as a purification medium in this conventional septic tank have a radius of about 5 mm or more (see, for example, JP-A-59-4493). When starting the use of the ornamental fish tank, first, a concentrated solution of bacteria is put into this septic tank so that the bacteria grow on the surface of the ceramic sphere. After the bacteria have successfully grown, when the water in the water tank passes through this purification tank, the bacteria that have grown on the surface of the ceramic spheres oxidize and decompose the ammonia component and the like. Specifically, ammonia is decomposed into nitrite by bacteria, and nitrite is decomposed into nitric acid (harmless) by other kinds of bacteria.

Further, in the conventional purifying device, a pump is provided on the outlet side of the purifying device in order to circulate the water in the water tank. Conventionally, this pump is installed on the outlet side of the purifier, but if a pump is installed on the inlet side of the purifier, it will also send debris in the water to the septic tank, and the septic tank will not be clogged. This is because there is a possibility that it may occur.

[0004]

However, in the conventional purification apparatus using such ceramic spheres,
The efficiency of bacterial growth after adding the bacterial concentrated solution to the septic tank is extremely poor. Therefore, it is not uncommon for the nitrous acid to fill the water tank due to insufficient decomposition of the ammonia component in the water tank. When nitrite fills the aquarium, the user has to drain all the water in the aquarium, clean the aquarium, replace the water with a new one, and start over from the first step of adding the bacterial concentrate to the septic tank. It was

The present invention has been made in view of the above problems of the conventional purifying apparatus, and an object of the present invention is to provide a purifying apparatus capable of remarkably improving the growth efficiency of microorganisms such as bacteria. And

[0006]

A purifying apparatus of the present invention for achieving the above object has a uniform container having a radius of 0.5 to 5 mm in a container which is closed except for a water inlet and a water outlet. It includes a septic tank provided with a large number of small spheres, and a pressurizing means for applying a pressure of at least 30 g / cm ² or more to the septic tank.

Further, in the purifying apparatus of the present invention, it is desirable that the small spheres are true spheres or almost true spheres.

Further, in the purifying apparatus of the present invention, the septic tank is filled with the small balls, and the pressurizing means comprises:
At least 30 g / cm ² of water in the container is placed in the septic tank.
It is desirable to be configured by a pump that applies the above pressure and sends it.

Further, the purifying apparatus of the present invention preferably further comprises a filtering device for filtering the water in the container sent to the septic tank before being sent to the septic tank.

Further, in the purifying apparatus of the present invention, it is desirable that the small spheres are made of a smooth material whose surface is not sparse.

Further, in the purifying apparatus of the present invention, it is desirable that the small balls are made of glass or plastic.

[0012]

As described above, in the purifying device of the present invention,
The small spheres as a purification medium filled in the septic tank are extremely small spheres having a radius of 0.5 to 5 mm. Therefore, an extremely large number of small spheres can be provided even in a septic tank having a fixed capacity. As a result, it is possible to form an extremely large number of gaps between the small balls in one septic tank.
In the present invention, the growth of microorganisms such as bacteria is
Although it is the surface of the small spheres in these gaps, in the present invention, these gaps are formed in an extremely large number as described above, and accordingly, the places where bacteria and the like proliferate are also formed in an extremely large number. Therefore, according to the present invention, bacteria and the like can be propagated extremely efficiently.

Further, since a large number of small spheres having a uniform shape and size are filled in the septic tank, a large number of gaps having a uniform shape and size are regularly provided between these small spheres. Will be placed. Therefore, the water in the water tank can relatively easily pass through the septic tank by passing through the large number of regularly arranged uniform gaps. (On the other hand, when the septic tank with non-uniform shape and size is filled in the septic tank, the small purifying medium gets into the gap between the large purifying media and the gap is almost eliminated. It may not be possible to easily pass through the septic tank).

Further, in the purifying apparatus according to the present invention, the small spheres provided in the septic tank are formed to have the same size. Therefore, a large number of minute gaps formed between these small spheres also have the same shape and size. Further, in the present invention, the septic tank is sealed except for the water outlet and the water inlet. Therefore, the pressure of at least 30 g / cm ² is uniformly applied to the septic tank by the pressurizing means, and as a result, the pressure is evenly applied to the mutually equal gaps. . Further, the water in the water tank is allowed to pass through each of the above-mentioned gaps, but since each of these gaps is equal to each other as described above, the water-passing states such as the above-mentioned water passage speeds should be kept equal to each other. become. Therefore, in the present invention, an environment suitable for the growth of bacteria, etc., in an extremely large number of gaps,
They are evenly formed. Therefore, the bacteria and the like can be propagated extremely efficiently.

Further, in the purifying apparatus of the present invention, since the small spheres are true spheres or substantially true spheres, the shape and size of the gaps between the respective small spheres are formed with high precision and evenly. Like Therefore, an environment suitable for the growth of bacteria and the like can be realized evenly in all the gaps.

Further, in the purifying device of the present invention, the pressurizing means is constituted by a pump for feeding the water in the container into the purifying tank by applying a pressure of at least 30 g / cm ² or more. Therefore, the pump for circulating the water in the container can be used to simultaneously circulate the water and pressurize the septic tank, thereby improving the efficiency of the entire apparatus. .

Further, the purifying apparatus of the present invention further comprises a filtering device for filtering the water in the container sent to the septic tank before being sent to the septic tank, so that the septic tank may be clogged. Absent.

Further, in the purifying apparatus of the present invention, since the small spheres are made of a smooth material whose surface is not sparse,
It becomes easy to form the small spheres as the purification medium into a true sphere or a substantially true sphere.

Further, in the purifying apparatus of the present invention, since the small spheres are formed of glass or plastic, it is extremely easy to form the small spheres as the purifying medium into a true sphere or a substantially true sphere. And it will be possible at low cost.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to illustrated embodiments. FIG. 1 is a schematic diagram showing a purifying device according to an embodiment of the present invention and an aquarium for ornamental fish equipped with the purifying device, and FIG.
FIG. 3 is a plan view showing the configuration of the purifying device of FIG. 3, and FIG. 3 is a perspective view showing the main body part of the septic tank of the purifying device of FIG. In FIG. 1, reference numeral 1 is a water tank, 2 is water in the water tank 1, 3 is bottom sand spread on the bottom in the water tank 1, 4 is a pipe fed into the bottom sand 3, and 5 is a pipe 4. It is a pump. In the present embodiment, this pump 5 is, for example, a product name “Spare pump SQ05 (lifting force: 60 cm / c) of Nisso Corporation.
m ² ) ”) is used. In this embodiment, the water 2 in the water tank 1 is pumped up by the pump 5 via the pipe 4, but in this case, the filter 4a made of cotton or the like is used to prevent the bottom sand 3 from rising together in the pipe 4. It is provided at the lower end of 4.

Further, in FIG. 1, FIG. 2 and FIG.
Is the container body of the septic tank connected to the pump 5 via the pipe 7. The septic tank container body 6 is made of, for example, plastic and is actually composed of an opaque member, but in FIG. Next, in FIG. 1, reference numeral 8 indicates a plurality of partition plates (six in total) protruding from the bottom of the main body 6 of the septic tank container (see FIG. 3).
Reference numeral 9 denotes a partition plate which is downwardly projected (a total of 5 pieces) from the lower surface of the intermediate plate 16 attached to the upper part of the septic tank container 6, and 10 denotes a filter provided on the water inlet side of the septic tank container 6. Cotton, 11 is a filtering cotton provided on the outlet side of the septic tank 6, and 12 is a large number of small microspheres in a space surrounded by each of the cotton 10, 11 of the septic tank 6 and the bottom surface and the top surface. Are filled in (in FIG. 2, these small spheres 12 are shown for convenience.
Is not shown). In this embodiment, the small balls 12
Is a glass sphere having a radius of 0.5 to 5 mm, for example, a glass sphere having a radius of 2 mm. Further, in this embodiment, a user or the like can put a concentrated liquid of microorganisms such as bacteria in the septic tank filled with the small balls 12 before using the water tank. In the present embodiment, as will be described later in detail, the bacteria and the like grow extremely efficiently on the surface of the large number of small balls 12.

In FIG. 1, reference numeral 13 is a pipe 13 provided on the outlet side of the septic tank 6, and the purified water from the septic tank 6 is returned from the pipe 13 into the water tank 1. In FIG. 1, reference numeral 14 is a rubber packing, 15 is an upper lid for sealing the inside of the septic tank container 6,
The upper lid 15 includes the septic tank container body 6 and the intermediate plate 1 described above.
It is fixed by screws (not shown) via 6 and the rubber packing 14. Further, in FIG. 3, reference numeral 6a is a pump mounting portion for mounting the pump 5 thereon.

Next, the operation of this embodiment will be described with reference to FIG. In the present embodiment, a large number of small balls 12 are filled in the septic tank body 6, and a concentrated liquid of microorganisms such as bacteria is put in advance. And the water 2 in the aquarium 1
Is pumped upward by the pump 5 through the pipe 4 while being filtered to some extent by passing through the bottom sand 3. At this time, the filter 4a prevents the bottom sand 3 from being pumped up by the pump 5. Pump 5
The water 2 pumped up by is sent to the septic tank container 6 through the pipe 7. At this time, the pump 5 is 30 g /
The water 2 is pushed into the septic tank container 6 with a pressure of cm ² or more, for example, a pressure of 80 g / cm ² . Therefore, this pressure is evenly applied to the entire inside of the septic tank container 6 which is closed as described above. The water 2 pushed by the pump 5 is first filtered by the cotton 10 and sent into the purification layer filled with the small balls 12. As described above, in this embodiment, the water 2 in the water tank 1 is sent to the purification layer in a state of being filtered by the bottom sand 3, the filter 4a, and the cotton 10, so that the purification layer is not likely to be clogged. ing.

Next, the water 2 that has passed through the cotton 10 is sent to the portion filled with the small balls 12 with a predetermined pressure. The pressure from the pump 5 is applied to the purification layer portion filled with the small balls 12, but since the purification layer container 6 is closed by the upper lid 15 as described above, a uniform pressure is applied to the entire purification layer. Addition (Conventionally, a structure in which the purification layer is sealed is known, but such a conventional configuration is to prevent water from spilling from the purification layer when the purification layer is taken out of the tank. (It is not known to provide a closed structure to equalize the pressure inside the purification layer as in the embodiment). Further, in this embodiment, in the portion where the small spheres 12 of the purification layer container 6 are filled, the six partition plates 8 from the bottom of the septic tank container body 6 and the five partition plates from the intermediate plate 16 above. 9 and 9 are projected alternately. Therefore, the water 2 moves in the purification layer from the right side to the left side in the drawing due to the pressure from the pump 5, but the partition plates 8 and 9 cause an approximately S-shape as shown by an arrow in FIG. It is designed to move while repeating the same flow.

In this embodiment, the small spheres 12 provided in the septic tank 6 are, for example, extremely small spheres having a radius of 2 mm. Therefore, a large number of small spheres 12 are provided in the septic tank 6 having a predetermined volume. Can be filled, each small ball 1
Since a large number of gaps (see reference numeral 18 in FIG. 4) between the two exist, the water 2 in the water tank 1 passes through the large number of the gaps 18 to relatively easily pass through the septic tank 6. It is possible (for example, radius 5
If a purifying medium having a relatively large size of mm or more is filled in the purifying tank, water in the water tank may not easily pass through the purifying tank).

The water 2 is made into small balls 12 by the pressure of the pump 5.
The ammonia and nitrite components contained in the water 2 are biodegraded by microorganisms such as bacteria that have grown on the surface of each small sphere 12 in the process of moving through the gap between them. The purified water 2 is further filtered by the cotton 11 and returned to the water tank 1 through the pipe 13. In the present embodiment, the above operation is continuously repeated by the pump 5.

Next, the operation of multiplying microorganisms such as bacteria in the septic tank of this embodiment will be described. In this embodiment, in the septic tank main body 6 in which the concentrated liquid of microorganisms such as bacteria is put, as described above, a large number of small balls 1 are previously prepared.
2 is filled. Since these small spheres 12 are, for example, extremely small true spheres having a radius of 2 mm, an extremely large number of small spheres are provided in this septic tank.
As a result, extremely large gaps 18 are formed between the small balls 12 in the septic tank of this embodiment, as shown in FIG. In the present embodiment, the place where microorganisms such as bacteria grow is the surface 12a (see FIG. 4) of the small spheres 12 in these gaps 18, but in this embodiment, these gaps 18 are as described above. Since it is formed in a very large amount, the place where bacteria and the like proliferate (the above-mentioned small spherical surface 12a) is also formed in an extremely large amount.
Therefore, according to the present invention, bacteria and the like can be propagated extremely efficiently.

Further, in this embodiment, the small spheres 12 provided in the septic tank container 6 are formed to have the same size. Therefore, the large number of minute gaps 18 formed between the small balls 12 also have the same shape and size (see FIG. 4). In this embodiment, the septic tank container 6
Is closed by an upper lid 15 except for the water outlet and the water inlet. Therefore, in the septic tank container 6, the pump 5
To a pressure of at least 30 g / cm ² or more, for example 8
0 g / cm ² is added evenly. As a result, this pressure is evenly applied to each of the gaps 18 which are equal to each other. The water 2 in the water tank 1 is allowed to pass through the gaps 18. However, since the gaps 18 are equal to each other as described above, the passage state of the water 2 such as the passage speed of the water 2 is as follows. The inside of this septic tank container 6 is kept uniform throughout.

By the way, according to many experiments, the present inventor found that bacteria and the like were allowed to survive under a pressure of at least 30 g / cm ² or more, preferably 50 g / cm ² or more. It was found that the efficiency of proliferation was remarkably increased as compared with the condition without addition (the other conditions were the same).

Further, in the experiment of the present inventor, the conventional radius of 5
When a small sphere having a diameter of mm or more is used as a purification medium for the growth of bacteria and the like, and when a small sphere having a radius of 2 mm in this example is used, the radius is 0.5 to 5 mm (preferably 2 to 5 mm).
Comparing with the case of using 3 mm) small spheres as a purification medium, it was discovered that the latter markedly improves the growth efficiency of bacteria and the like. This is related to the fact that the small spheres having a small radius cause the number of gaps formed between the small spheres to be remarkably larger than the case where the small spheres having a large radius are used. That is, it is considered that bacteria and the like propagate on the surface of the small spheres in the gaps, so that the larger the number of the gaps, the higher the efficiency of growth of the bacteria and the like. Therefore, the small spheres as the purification medium have a radius of 0.
It is desirable to use a relatively small one of 5 to 5 mm (preferably 2 to 3 mm). According to the experiments by the present inventor, the desirable radius size of the small sphere 12 is preferably within the range of 0.5 to 5 mm, but the optimum size is related to the size of the aquarium 1. . That is, if the water tank 1 is small, the size of the small balls 12 is preferably relatively small, and if the water tank 1 is large, the size of the small balls 12 may be relatively large.

Further, in the experiment of the present inventor, the sphericity was measured using a conventional commercially available ceramic sphere having a radius of about 2 mm and bacteria and the like, and a glass sphere or a plastic sphere having a radius of 2 mm according to this embodiment. It was discovered that the latter has a markedly improved growth efficiency when the bacteria and the like are grown using a high strain. These experimental results indicate that conventional ceramic spheres are probably difficult to make with high sphericity, resulting in large variations in sphericity. It is related to the fact that it is difficult to make a large number of them, and that there is considerable variation in the size of their radii.

That is, according to the experiments of the present inventor, it is desirable that the minute gaps 18 as shown in FIG. This is because, if the sizes and shapes of the gaps 18 are equal to each other, the pressure applied by the pressurizing means such as the pump 5 can also be applied uniformly to all of the gaps 18. The state of water moving in the purification layer due to the pressure (moving speed of water, etc.) is also equal in all the gaps 18. In this way, the uniform state in each gap 18 means that the environment for breeding bacteria and the like is uniform in all the gaps 18, which is a very desirable state for the growth of bacteria and the like. It is considered to be.

As described above, according to the experiments of the present inventor, in order to create an optimal environment for the growth of bacteria and the like, the minute gaps 18 as described above are formed to have the same size and shape. Can be said to be desirable. And the gap 1
In order to form 8 in a uniform size and shape, small balls 12
Must be as close to a true sphere as possible. Further, the present inventor conducted an experiment of bacterial growth mainly using glass or plastic spheres, and obtained extremely good results. As can be derived from these results, it can be said that it is desirable that the small spheres 12 are formed of a material (glass, plastic, etc.) having a smooth surface rather than a sparse surface such as ceramics. Further, in order to form a large number of small spheres having a high sphericity and mutually equal sizes as described above, it is easy to form a material having a smooth surface instead of ceramics, etc. Forming with a plastic or the like has advantages that the manufacturing is easy and the manufacturing cost is low.

Conventionally, a purification medium for growing bacteria and the like has a larger area for breeding bacteria and the like because the area for breeding bacteria and the like is larger if it is made of ceramic or cement whose surface is sparse. It was said to be good.
For this reason, the purification medium is usually formed by using a material such as ceramic or cement whose surface is sparse (see, for example, JP-A-59-4493). However, the experimental results of the present inventor show that the case where a spherical surface formed by using a material such as glass or plastic having a smooth surface is used as the purification medium (in addition, a predetermined pressure is applied) The efficiency of proliferation is remarkably improved, and the result is completely opposite to the conventional common sense as described above.

When a conventional ceramic sphere or the like is used as a purification medium, the growth efficiency of bacteria and the like is poor. Therefore, if the user newly purchases an aquarium of ornamental fish,
Conventionally, ammonia contained in water in the aquarium and nitrous acid generated by decomposition of ammonia are not easily decomposed by bacteria etc., the aquarium is filled with nitrous acid, the ornamental fish die and the aquarium turns red. It wasn't the least. In this case, conventionally, it has been necessary to replace all the water in the water tank with a new one and start over from the beginning. But,
In the experiment of the present inventor, when the purifying apparatus of the present embodiment is used, even if the water tank is filled with nitrous acid and the inside of the water tank becomes red as described above, the water is not replaced as it is, and the present embodiment is performed. It was found that if the pump of the example was driven and water was continuously circulated while passing through the purification device, nitrite was decomposed into harmless nitric acid in about 2 weeks, and the ornamental fish could be raised. This indicates that the efficiency of the growth of bacteria and the like is extremely high when this example is used.

Further, in the experiment using the purification apparatus of this embodiment, the bacterial growth efficiency was extremely high, and when aerobic bacteria decomposed ammonia or nitrous acid, a large amount of oxygen was taken in and a large amount of carbon dioxide gas was discharged. It became so.
Due to the large amount of carbon dioxide gas discharged, aquatic plants (seagrass) have started to propagate in the aquarium. Conventionally, it has been said that it is extremely difficult to reproduce aquatic plants in a small-sized aquarium for home use because the amount of carbon dioxide gas is small, but it is possible to reproduce aquatic plants by using this example. It can be said that this is one of the excellent effects of this embodiment.
As described above, when the purifying apparatus of the present embodiment is used, since a large amount of carbon dioxide gas is generated in the aquarium due to the growth of bacteria, in order to supply the oxygen necessary for the survival of the ornamental fish into the aquarium, the air is used. It is desirable to use rations together.

In this embodiment, the pump 5 is used to apply a pressure of 30 g / cm ² or more in the septic tank 6, but the pressurizing means of the present invention is not limited to this. For example, a device that compresses the entire volume of the purification layer may be used. Further, in the present embodiment, the small spheres 12 are filled in the purification layer, but in the present invention, it is not always necessary to fill, and it is possible to provide a large number of small spheres in the purification layer.
The effects as described above can be produced.

[0038]

As described above, in the purification apparatus of the present invention, a large number of small spaces (gap between the respective small balls) suitable for the growth of microorganisms such as bacteria can be formed in the purification layer. Therefore, the efficiency of growth of bacteria and the like can be dramatically increased. In addition, as a result, if the ornamental fish died due to nitrite filling in the ornamental fish tank,
Although it was necessary to replace all the water in the aquarium, when using the purification device of the present invention, by continuing to purify the water filled with nitrous acid after the ornamental fish has died, within a few weeks, Nitrite is completely decomposed by the grown bacteria, etc., and it can be changed into an environment where ornamental fish can grow. Further, when the purification device of the present invention is used, the growth of bacteria and the like is made extremely efficient, so that it is possible to generate a large amount of carbon dioxide gas in the aquarium by the growth of bacteria and the like, and to aquatic plants in a domestic aquarium. It becomes possible to breed.

Further, in the purifying apparatus of the present invention, the small spheres are formed as true spheres or substantially true spheres, so that the shape and size of the gap between the respective small spheres are formed with high precision and evenly. It is possible to increase the efficiency of the growth of bacteria and the like.

Further, in the purifying device of the present invention, the pressurizing means is constituted by a pump for feeding the water in the container into the purifying tank by applying a pressure of at least 30 g / cm ² or more. Therefore, the pump for circulating the water in the container can be used to simultaneously circulate the water and pressurize the septic tank, thereby improving the efficiency of the entire apparatus. .

Further, in the purifying apparatus of the present invention, further, by providing the filtering apparatus for filtering the water in the container sent to the septic tank before being sent to the septic tank, there is no possibility that the septic tank is clogged. .

Further, in the purifying apparatus of the present invention, the small spheres, which are the purifying medium, can be easily formed into a true sphere or a substantially true sphere by forming the small spheres from a smooth material having a non-dense surface. become.

Further, in the purifying apparatus of the present invention, by forming the small spheres with glass or plastic,
It becomes possible to form the small spheres that serve as the purification medium into a true sphere or a substantially true sphere very easily and at low cost.

[Brief description of drawings]

FIG. 1 is a schematic view showing a purification device according to an embodiment of the present invention and an aquarium for aquarium fish using the purification device.

FIG. 2 is a plan view showing the purification device of FIG.

3 is a perspective view showing a purification layer container body of the purification device in FIG. 1. FIG.

FIG. 4 is a diagram for explaining the operation of the present embodiment.

[Explanation of symbols] 1 water tank 2 water 3 bottom sand 4,7,13 pipe 5 pump 6 purification layer container body 8,9 partition plate 10,11 cotton 12 small spheres 12a small sphere surface 18 gap 15 upper layer of purification layer container

Claims (6)

[Claims] 1. A purification device for use in a container for ornamental fish or live fish, which has a uniform radius of 0.5 to 5 mm in a container which is sealed except for a water inlet and outlet. A purifying apparatus comprising: a septic tank provided with a large number of small balls and a pressurizing means for applying a pressure of at least 30 g / cm 2 or more in the septic tank. 2. The purifying apparatus according to claim 1, wherein the small sphere is a true sphere or a substantially true sphere. 3. The purifying apparatus according to claim 1 or 2, wherein the septic tank is filled with the small balls, and the pressurizing means fills the septic tank with water in the container of at least 30 g / cm 2 or more. A purifying device, characterized in that it is composed of a pump that applies the pressure of and sends it. 4. The purifying apparatus according to claim 3, further comprising a filtering device that filters water in the container sent to the septic tank before being sent to the septic tank. 5. The purifying device according to claim 1, wherein the small spheres are made of a smooth material whose surface is not sparse. 6. The purifying device according to claim 1, wherein the small balls are made of glass or plastic.