KR102625822B1 - Educational Method and Psychological Healing Method Using Apparatus to Breed Aquarium Fish Which Can Be Connected To Metaverse - Google Patents

Abstract

The present invention is an animal-assisted self-directed learning education method using a modular aquarium fish education kit that can be connected to the metaverse and a psychological healing method through animal communication. By providing a modular aquarium fish education kit and providing rewards by evaluating the user's practice activities and the growth status of the ornamental fish, we promote interest in ornamental fish and explore the functions of each module in the process of self-directed learning. You can connect to the Metaverse, which can improve imagination, creativity, responsibility, sense of accomplishment, confidence, reduce negative emotions, and reduce stress, emotional stability, and relieve psychological tension in the process of animal-assisted psychotherapy where you can communicate and feel intimacy with aquarium fish. This is about an animal-mediated self-directed learning education method using a modular ornamental fish education kit and a psychological healing method through animal communication.

Description

Animal-assisted self-directed learning using a modular aquarium fish education kit that can be connected to the Metaverse {Educational Method and Psychological Healing Method Using Apparatus to Breed Aquarium Fish Which Can Be Connected To Metaverse}

The present invention is an animal-assisted self-directed learning education method using a modular aquarium fish education kit that can be connected to the metaverse and a psychological healing method through animal communication. By providing a modular aquarium fish education kit and providing rewards by evaluating the user's practice activities and the growth status of the ornamental fish, we promote interest in ornamental fish and explore the functions of each module in the process of self-directed learning. You can connect to the Metaverse, which can improve imagination, creativity, responsibility, sense of accomplishment, confidence, reduce negative emotions, and reduce stress, emotional stability, and relieve psychological tension in the process of animal-assisted psychotherapy where you can communicate and feel intimacy with aquarium fish. This is about an animal-mediated self-directed learning education method using a modular ornamental fish education kit and a psychological healing method through animal communication.

An educational kit to develop self-directed learning ability and creativity in growing children and adolescents, including an Arduino education kit that allows you to design and program basic electrical and electronic circuits, and a science box that allows you to build your own mechanical box and explore the principles, are released. It is being sold.

Meanwhile, various types of educational kits have been developed and sold, but the development of an educational kit for ornamental fish that creates an optimal environment for the growth of ornamental fish and allows understanding the life cycle of ornamental fish and the marine ecosystem by rearing ornamental fish. And sales are not taking place.

Specifically, by using the ornamental fish education kit, users can expect the effect of improving imagination, creativity, responsibility, sense of accomplishment, and confidence, and reducing negative emotions through self-directed learning. However, there is still no need to develop or develop such an ornamental fish education kit. Sales are not taking place.

An aquarium can be an independent environment with great diversity consisting of various elements such as stones, water plants, corals, sand, and fish of various sizes, shapes, and colors, and through the work of creating an aquarium with these various elements, Users can improve their imagination and creativity.

In addition, by involving children in managing the aquarium and caring for the fish, children's sense of responsibility can be improved, and by having them ask themselves questions about things they do not know about the aquarium management and fish raising process, children's social skills can be improved and children's sense of responsibility can be improved. It can lead to improved self-confidence through a sense of accomplishment.

Additionally, children can relieve negative emotions such as stress and anxiety by looking at fish in an aquarium. Specifically, children become friends with the fish they raise and care for, and relieve their worries and stress by revealing their own secrets and mistakes to the fish without worrying about their secrets being revealed or being scolded for their mistakes. can do. Additionally, by having children in difficult situations take care of fish, negative emotions such as sadness, frustration, and anger that come from difficult situations can be reduced.

In this way, through self-directed learning using ornamental fish education kits, various effects such as imagination, creativity, responsibility, sense of accomplishment, improvement of confidence, and reduction of negative emotions can be expected, but the development and sale of ornamental fish education kits for this purpose has not been carried out. It is not happening.

Meanwhile, animal-assisted psychological therapy seeks to improve physical and mental health through the use of animals, and ornamental fish can be included as one of the companion animals for animal-assisted psychological healing. Specifically, by feeding aquarium fish and creating an optimal environment during their life cycle, users can feel intimacy and achieve effects such as stress reduction, emotional stability, and psychological tension relief.

Specifically, fish (ornamental fish) have the advantage of being able to be raised in a relatively small space (aquarium) compared to companion animals such as dogs and cats, so the cost of purchasing and maintaining companion animals is relatively low. Additionally, since ornamental fish live in an independent ecosystem within the aquarium, they do not feel loneliness or anxiety even when left alone, making it possible for users to easily raise them.

In addition to these breeding advantages, the effects of raising ornamental fish include stress reduction, stabilization of blood pressure and heart rate, psychological stability and stress reduction (during surgery or treatment), alleviation of symptoms in Alzheimer's patients, and hyperactivity disorder (ADHD). It has the same effect as reduction.

Specifically, previous studies have reported that installing an aquarium in the house can induce a sense of stability, thereby reducing stress and reducing anxiety. In other words, just by looking at an aquarium, people can calm their minds and achieve a soothing effect through the same relaxation effect as when listening to the sound of the ocean, waves, raindrops, or a flowing stream.

Additionally, previous studies have reported that watching fish swimming in an aquarium can have the effect of stabilizing blood pressure and heart rate. Specifically, the study found that just looking at water plants and rocks in an empty aquarium reduced heart rate by 3%, and seeing fish swimming in an aquarium reduced heart rate by 7%. In this way, looking at fish in an aquarium can be expected to stabilize the heart rate of elderly people suffering from high blood pressure and improve their health.

Additionally, previous studies have reported that looking at fish in an aquarium can reduce the anxiety and fear of patients undergoing surgery or treatment, and can help patients feel calm after surgery or treatment. Specifically, it has been reported that fear, tension, and stress due to the sound of a drill grinding teeth at the dentist or pain during dental treatment can be reduced by viewing fish swimming slowly in an aquarium by inducing psychological stability and reducing fear of treatment. .

Additionally, looking at brightly colored fish in an aquarium can help Alzheimer's patients relax and reduce nervous behaviors such as aggressiveness, screaming, wandering around aimlessly, or walking quickly and aimlessly. Specifically, in a previous study, it was reported that patients looking at fish in an aquarium increased the amount of food they ate before by an average of 17% to as much as 21%. Additionally, patients showed improvements in short-term memory and a reduced need for secondary treatments. Likewise, in neuroscience research, it has been reported that looking at fish affects the secretion of neurotransmitters such as serotonin, dopamine, and adrenaline in patients.

Additionally, previous studies have reported that looking at fish in an aquarium improves concentration and reduces hyperactivity in children suffering from attention deficit hyperactivity disorder (ADHD). Specifically, looking at fish can increase the secretion of GABA (gamma aminobutyric acid), lowering excessively secreted adrenaline and inducing a sedative effect.

In this way, effects such as stress reduction, emotional stability, and psychological tension relief can be expected through animal-assisted psychological healing using ornamental fish education kits, but the development and sale of ornamental fish education kits for this purpose has not been carried out.

Furthermore, native fish that are collected or farmed in Korea include the golden mochi, black snail, midge, and white-lined croaker, but they are gradually disappearing due to environmental pollution and ecologically disturbing species such as bass, bluegill, and bullfrog. Interest and education are needed, but the current curriculum does not provide sufficient education on native fish.

As a result, for self-directed learning, animal-assisted psychological healing, and interest in and education about native fish, users can produce and assemble modules that directly control water temperature, dissolved oxygen, etc., allowing them to raise ornamental fish in an optimal breeding environment. There is a need to develop an ornamental fish education kit.

Meanwhile, in providing educational kits to develop self-directed learning ability and creativity, it is necessary to provide evaluation according to the user's practice activities and provide appropriate compensation accordingly in order to improve the learning effect by encouraging the user's continuous interest. .

Domestic registered patent KR 10-1013941 B1, “Educational Virtual Aquarium Using a Display Panel,” discloses an educational virtual aquarium that can provide education and visual aesthetics through a display panel. However, the virtual aquarium for education according to the patent is to raise fish virtually, and in the virtual aquarium for education according to the patent, the user can directly create a module that can control the breeding environment in which the ornamental fish grow, such as the water temperature and dissolved oxygen level of the ornamental fish. I was unable to assemble and practice it. In addition, the patent does not allow users to evaluate the training course for raising ornamental fish and does not provide compensation accordingly, so it cannot exert the effect of improving the learning effect by inducing the user's continuous interest.

Domestic registered patent KR 10-1013941 B1

The present invention is an animal-assisted self-directed learning education method using a modular aquarium fish education kit that can be connected to the metaverse and a psychological healing method through animal communication. By providing a modular aquarium fish education kit and providing rewards by evaluating the user's practice activities and the growth status of the ornamental fish, we promote interest in ornamental fish and explore the functions of each module in the process of self-directed learning. You can connect to the Metaverse, which can improve imagination, creativity, responsibility, sense of accomplishment, confidence, reduce negative emotions, and reduce stress, emotional stability, and relieve psychological tension in the process of animal-assisted psychotherapy where you can communicate and feel intimacy with aquarium fish. The purpose is to provide an animal-assisted self-directed learning education method using a modular ornamental fish education kit and a psychological healing method through animal communication.

In order to solve the above problems, as an education and psychological healing method using a modular ornamental fish education kit that can be connected to the metaverse, the modular ornamental fish education kit and ornamental fish fry provided to the user or purchased by the user are described above. A registration step of registering initial information including one or more information among the identification information of the modular ornamental fish education kit, purchase date and time of the ornamental fish fry, population, fish species, and a first fry image taken of the ornamental fish fry; In the registration step From the registered modular aquarium fish training kit, real-time water temperature information on whether the temperature control device provided in the modular aquarium fish training kit is operating and the current water temperature is received, and the real-time water temperature information is received from the aquarium fish registered in the registration step. An ornamental fish breeding step to determine whether the water temperature is maintained within the appropriate water temperature for the fish species; and receiving, from the user, an adult image of an adult aquarium fish in which the aquarium fish fry registered in the registration step has grown, and determining whether the aquarium fish fry grows based on the adult image and determining the first operation of the temperature control device from the user. A compensation provision step of providing compensation based on whether the integrated water temperature information is maintained within the appropriate water temperature for the species of ornamental fish, based on integrated water temperature information accumulated from the real-time water temperature information up to the time of requesting compensation. Provides education and psychological healing methods using a modular ornamental fish education kit, including;

In one embodiment of the present invention, the modular ornamental fish training kit is provided on one side of the aquarium for rearing ornamental fish, and includes a plurality of prefabricated modules capable of controlling environmental conditions for impurities, dissolved oxygen, and water temperature of the water in which ornamental fish are reared, A main body module including a plurality of module coupling surfaces that can be attached and detached using a magnetic material or an insertion method; and a filtration module fixed to one of the plurality of module coupling surfaces and filtering water through a plurality of filtration materials in the internal accommodation space. A microbial purification module fixed to one of the plurality of module coupling surfaces and purifying water using an anaerobic microbial culture material or an aerobic microbial culture material in the internal receiving space; And a prefabricated module including a temperature control module fixed to one of the plurality of module coupling surfaces and controlling the water temperature in the internal accommodation space by a temperature control device, and connected to a pump provided inside the water tank. As a result, the water inside the water tank can circulate through the filtration module, the microbial purification module, and the temperature control module and be discharged back into the water tank.

In one embodiment of the present invention, the registration step can be experienced by wearing a web page or HMD module, a manual containing one or more information among the assembly method, usage method, and breeding method of the modular ornamental fish education kit. It may include a manual provision step provided on the metaverse.

In one embodiment of the present invention, the compensation providing step includes: a first score calculation step of calculating a first score calculated according to the species of the ornamental fish raised by the user in the ornamental fish breeding step; A second score calculation step of calculating a second score based on the number of fry of the ornamental fish registered in the registration step and the number of adults of the ornamental fish in the adult image; And a third score calculation step of calculating a third score that is added as the integrated water temperature information corresponds to the median value of the appropriate water temperature and subtracted according to the number and period of times the integrated water temperature information exceeds or falls below the appropriate water temperature. ;, and the compensation may be provided in proportion to the sum of the first score, the second score, and the third score.

In one embodiment of the present invention, the compensation providing step is calculated by weighting according to the fish species of the ornamental fish fry on which the adult ornamental fish spawned, based on the second fry image taken of the ornamental fish fry on which the adult ornamental fish spawned. A fourth score calculation step of calculating a fourth score may be provided in proportion to the sum of the first score, the second score, the third score, and the fourth score. there is.

In one embodiment of the present invention, the aquarium fish breeding step may further include an alarm information transmission step of transmitting alarm information to the user when the real-time water temperature information exceeds or falls below the appropriate water temperature.

In one embodiment of the present invention, the aquarium fish breeding step receives sensing information measured by a sensor that measures one or more of pH, salinity, nitrate, phosphate, nitrite, and ammonia provided in the modular aquarium fish education kit, If the sensing information is not suitable for the growth of the ornamental fish, feedback information including alarm information about the situation and ways to improve the situation can be provided to the user through a messenger service using an AI chatbot. there is.

In order to solve the above problems, it is a computing-system that provides education and psychological healing methods using a modular ornamental fish education kit, wherein the computing-system stores instructions for performing the following steps, and the following steps Regarding the modular ornamental fish education kit and ornamental fish fry provided to the user or purchased by the user, the identification information of the modular ornamental fish education kit, the date and time of purchase of the ornamental fish fry, the population, the fish species, and the photo taken of the ornamental fish fry A registration step of registering initial information including one or more information among one fry image; From the modular aquarium fish training kit registered in the registration step, real-time water temperature information about the operation of the temperature control device provided in the modular aquarium fish training kit and the current water temperature is received, and the real-time water temperature information is received in the registration step. An ornamental fish breeding step that determines whether or not the registered ornamental fish species are maintained within the appropriate water temperature; and receiving, from the user, an adult image of an adult aquarium fish in which the aquarium fish fry registered in the registration step has grown, and determining whether the aquarium fish fry grows based on the adult image and determining the first operation of the temperature control device from the user. A compensation provision step of providing compensation based on whether the integrated water temperature information is maintained within the appropriate water temperature for the species of ornamental fish, based on integrated water temperature information accumulated from the real-time water temperature information up to the time of requesting compensation. Provides a computing-system including;

According to one embodiment of the present invention, the prefabricated module can be easily coupled to the main body module using a magnetic material or an insertion method.

According to one embodiment of the present invention, the upper and lower lids of the prefabricated module and the water pipe through which water circulates can be easily coupled using a screw method.

According to one embodiment of the present invention, users can assemble filtration modules to explore the functions of each filter material and improve creativity by applying and changing various filter materials.

According to one embodiment of the present invention, a user can assemble an anaerobic microbial purification module to explore denitrification by anaerobic microorganisms and learn about the effect of nitrate on fish.

According to one embodiment of the present invention, a user can assemble an aerobic microbial purification module to explore the ammonia-nitric acid conversion effect by aerobic microorganisms and learn about the effect of ammonia on fish.

According to one embodiment of the present invention, a user can assemble a temperature control module to set the optimal water temperature for the growth of ornamental fish and learn the effect of water temperature on the fish.

According to one embodiment of the present invention, based on whether the temperature control device is operating, it can be determined whether the user faithfully raised the ornamental fish during the training course of purchasing the fry and raising them to adults.

According to one embodiment of the present invention, the user calculates a score by comprehensively considering the species of ornamental fish, the number of ornamental fish grown from fry to adults, whether an appropriate water temperature is maintained during the training process, and the species of fry of ornamental fish that are spawned, etc., and compensates accordingly. can be provided.

According to one embodiment of the present invention, by providing rewards to users according to practice activities, the self-directed learning effect can be improved by inducing the user's continued interest in ornamental fish.

According to one embodiment of the present invention, by allowing the user to repurchase feed, sea salt, consumables, and other fish species necessary for breeding through compensation, the user can repeat training courses on various fish species to provide information on natural science and environmental engineering. Learning effectiveness can be improved.

According to one embodiment of the present invention, information about the current water temperature of the temperature control device can be received from the server, and alarm information can be sent to the user when the water temperature is outside the appropriate water temperature.

According to one embodiment of the present invention, the user can improve imagination, creativity, responsibility, sense of accomplishment, and confidence, and reduce negative emotions by self-directed learning in the process of feeding ornamental fish and creating a growth environment.

According to one embodiment of the present invention, stress reduction, emotional stability, and psychological tension can be alleviated through animal-assisted psychological healing in which the user feels intimacy and communicates with aquarium fish.

According to one embodiment of the present invention, pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. are measured by a sensor, and the sensing information measured by the sensor is displayed through a display device, allowing the user to check the status of the breeding water. It can be checked and inspected at any time.

According to one embodiment of the present invention, sensing information on pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. is transmitted to the server system, and feedback on inspection and water exchange of breeding water can be provided.

According to one embodiment of the present invention, feedback can be provided to users through messenger services, business trip services, and video services using AI chatbots.

Figure 1 shows a modular ornamental fish education kit according to an embodiment of the present invention.
Figure 2 shows a main body module according to an embodiment of the present invention.
Figure 3 shows types of prefabricated modules according to an embodiment of the present invention.
Figure 4 shows a prefabricated module according to an embodiment of the present invention.
Figure 5 shows a cross-sectional view of a prefabricated module in which the upper module lid and the lower module lid are combined according to an embodiment of the present invention.
Figure 6 shows a cross-sectional view of an inlet where the external water pipe and the first internal water pipe are combined, and an outlet where the external water pipe and the second internal water pipe are combined according to an embodiment of the present invention.
Figure 7 shows a filtration module according to one embodiment of the present invention.
Figure 8 shows an aerobic microbial purification module according to an embodiment of the present invention.
Figure 9 shows an anaerobic microbial purification module according to an embodiment of the present invention.
Figure 10 shows a temperature control module according to an embodiment of the present invention.
Figure 11 shows components for implementing an education and psychological healing method using a modular ornamental fish education kit according to an embodiment of the present invention.
Figure 12 shows the implementation steps of an education and psychological healing method using a modular ornamental fish education kit according to an embodiment of the present invention.
Figure 13 shows a registration step according to an embodiment of the present invention.
Figure 14 shows the manual provision step according to an embodiment of the present invention.
Figure 15 shows the steps of raising ornamental fish according to an embodiment of the present invention.
Figure 16 shows the compensation provision step according to an embodiment of the present invention.
Figure 17 shows a process for calculating compensation according to an embodiment of the present invention.
Figure 18 shows the process of calculating the third score depending on whether the appropriate water temperature is maintained according to an embodiment of the present invention.
Figure 19 shows steps in which feedback information is provided to a user according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Various embodiments and/or aspects are now disclosed with reference to the drawings. In the following description, for purposes of explanation, numerous specific details are set forth to facilitate a general understanding of one or more aspects. However, it will also be appreciated by those skilled in the art that this aspect(s) may be practiced without these specific details. The following description and accompanying drawings set forth in detail certain example aspects of one or more aspects. However, these aspects are illustrative and some of the various methods in the principles of the various aspects may be utilized, and the written description is intended to encompass all such aspects and their equivalents.

Additionally, various aspects and features may be presented by a system that may include multiple devices, components and/or modules, etc. It is also understood that various systems may include additional devices, components and/or modules, etc. and/or may not include all of the devices, components, modules, etc. discussed in connection with the drawings. It must be understood and recognized.

As used herein, “embodiments,” “examples,” “aspects,” “examples,” etc. may not be construed to mean that any aspect or design described is better or advantageous over other aspects or designs. . The terms '~part', 'component', 'module', 'system', 'interface', etc. used below generally refer to computer-related entities, such as hardware, hardware, etc. A combination of and software, it can mean software.

Additionally, the terms “comprise” and/or “comprising” mean that the feature and/or element is present, but exclude the presence or addition of one or more other features, elements and/or groups thereof. It should be understood as not doing so.

Additionally, terms including ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, a first component may be named a second component, and similarly, the second component may also be named a first component without departing from the scope of the present invention. The term and/or includes any of a plurality of related stated items or a combination of a plurality of related stated items.

In addition, in the embodiments of the present invention, unless otherwise defined, all terms used herein, including technical or scientific terms, are generally understood by those skilled in the art to which the present invention pertains. It has the same meaning as Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless clearly defined in the embodiments of the present invention, have an ideal or excessively formal meaning. It is not interpreted as

1. Modular ornamental fish education kit

Prior to the detailed description of the present invention, hereinafter, “2. “1. To implement an animal-mediated self-directed learning education method and psychological healing method through animal communication using a modular ornamental fish education kit that can be connected to the metaverse.” “Modular ornamental fish education kit” is described in detail.

Figure 1 shows a modular ornamental fish education kit according to an embodiment of the present invention.

As shown in Figure 1, the modular ornamental fish education kit is provided on one side of the aquarium 8 for rearing ornamental fish, and is a plurality of prefabricated structures capable of controlling environmental conditions for impurities, dissolved oxygen, and water temperature of the water in which ornamental fish are reared. A main body module (1) in which the module (2) includes a plurality of module coupling surfaces (10) that can be attached and detached using a magnetic material or an insertion method; and a filtration module (3) fixed to one of the plurality of module coupling surfaces (10) and filtering water by a plurality of filtration materials (31) in the internal accommodation space. A microbial purification module (4) fixed to one of the plurality of module coupling surfaces (10) and purifying water using an anaerobic microbial culture medium (410) or an aerobic microbial culture medium (400) in the internal receiving space; And a prefabricated module (2) including a temperature control module (5) fixed to one of the plurality of module coupling surfaces (10) and controlling the water temperature by a temperature control device in the internal accommodation space. , the water inside the water tank (8) circulates through the filtration module (3), the microbial purification module (4), and the temperature control module (5) by the pump (9) provided inside the water tank (8). It can be discharged back into the water tank (8).

The modular ornamental fish education kit (hereinafter referred to as the ornamental fish education kit) of the present invention is a device that adjusts the water in the aquarium (8) where ornamental fish are reared to an optimal environment for the growth of ornamental fish. The user can use the ornamental fish education kit in the aquarium (8). ), so that the environmental conditions of the water tank (8) can be adjusted.

Specifically, in order to grow ornamental fish, it is necessary to set the water temperature, dissolved oxygen, etc. to a range suitable for the growth of ornamental fish, filter out ammonia and impurities generated due to metabolic activity, and create environmental conditions suitable for the growth of ornamental fish. The ornamental fish education kit of the present invention can provide a plurality of prefabricated modules (2) that perform these functions in a form that allows the user to directly assemble and change the design.

Preferably, the user assembles a filtration module (3) that filters impurities in water, a microbial purification module (4) that purifies ammonia and nitrate generated during the metabolic process through microorganisms, and a temperature control module (5) that controls the water temperature. It is provided inside the main body module (1), and the water in the water tank is operated by the pump (9) to circulate through each prefabricated module (2), thereby providing filtration, purification, and water temperature control functions by each prefabricated module (2). You can experience this process.

In addition, the prefabricated module (2), in addition to the filtration module (3), microbial purification module (4), and temperature control module (5), includes a skimmer module that bubbles and discharges dirt and organic matter in seawater, and maintains the amount of dissolved oxygen in the water. It may further include an oxygen generation module that supplies oxygen.

In one embodiment of the present invention, a manual including a description of the assembly method of the ornamental fish education kit and the functions of each of the plurality of prefabricated modules (2) is provided to the user, so that the user can easily assemble the ornamental fish education kit through the manual. By exploring the functions of the self-assembled prefabricated modules (2) and creating an optimal environment for the growth of ornamental fish, the learning effect and user interest in ornamental fish can be improved.

In one embodiment of the present invention, as shown in Figure 1 (a), the ornamental fish education kit includes a main body module (1) that can be opened and closed through a door on one side of the aquarium (8) and the main body module ( It can be implemented in a form where a plurality of prefabricated modules (2) are provided in the internal storage space of 1).

Or, in another embodiment of the present invention, as shown in (b) of Figure 1, the ornamental fish training kit is provided with a drawer-type main body module (1) and the inside of the main body module (1) at the lower side of the water tank (8). It can be implemented in a form where a plurality of prefabricated modules (2) are provided in the storage space.

Alternatively, in another embodiment of the present invention, as shown in Figure 1 (c), the ornamental fish education kit may have a display unit 52 built into the outer surface of the drawer-type main body module 1. In this way, the display unit 52, which displays the current water temperature sensed by the temperature sensor (not shown) or displays the set temperature input by the user, is built into the outer surface of the drawer-type main body module 1, so that the user can You can easily check and inspect the current status of the water tank from the outside without having to open or close the storage space.

In this way, the ornamental fish education kit circulates the water in the aquarium (8) where the ornamental fish are raised through the plurality of prefabricated modules (2) provided inside the main body module (1) through the pump (9) and discharges it back into the aquarium (8). It can be implemented in various forms wherever possible.

In addition, the size, shape, type, number, etc. of the main body module 1 and the prefabricated module 2 may be determined by considering the size of the aquarium 8, the species of ornamental fish, and the number of fish.

In one embodiment of the present invention, an ornamental fish education kit equipped with a filtration module (3), a microbial purification module (4), and a temperature control module (5) is provided to users who breed freshwater ornamental sharks, and users who breed saltwater ornamental sharks For , we can provide an ornamental fish education kit that further includes a skimmer module.

Additionally, in one embodiment of the present invention, the capacity and number of prefabricated modules 2 provided may be determined depending on the size of the water tank 8. Specifically, for users who have a large-capacity water tank (8), an ornamental fish education kit that can combine a filtration module (3) with a large filtration capacity or a plurality of filtration modules (3) can be provided.

Figure 2 shows a main body module 1 according to an embodiment of the present invention.

As described above in FIG. 1, the main body module (1) can be implemented in various forms at a location where the waterway through which the water of the water tank (8) can circulate can be connected, and has a plurality of prefabricated modules (2) in the internal storage space. ) can be combined. In addition, the main body module (1) may include a plurality of module coupling surfaces (10) to which each of the plurality of prefabricated modules (2) can be coupled in the internal storage space.

As described above, the plurality of prefabricated modules (2) may be determined differently in size, shape, type, number, etc., considering the size of the aquarium (8), the species and number of ornamental fish, etc., so the plurality of prefabricated modules (2) ) The module coupling surface 10 to which ) is coupled may also have different shapes and sizes.

For example, as shown in Figures 2 (a) and (b), the main body module 1 may be implemented in a form including a three- or six-hole module coupling surface 10.

Preferably, in (a) of Figure 2, the main body module (1) including three module coupling surfaces (10) is used for a tank (8) in which the size of the tank (8) is small or a small number of ornamental fish are raised. It may be the main body module (1) of the ornamental fish education kit, and in Figure 2 (b), the main body module (1) including six module coupling surfaces (10) is used when the size of the aquarium (8) is large or a large number of It may be the main body module (1) of an ornamental fish education kit for an aquarium (8) where ornamental fish are raised.

Meanwhile, the module coupling surface 10 has the same shape as the lower cross-section of the prefabricated module 2, but may further include a separate coupling member for being coupled to the prefabricated module 2. Specifically, the main body module 1 and the prefabricated module 2 can be coupled and fixed to each other by an attachment method using a magnetic material, an insertion method, or a screw coupling method.

In one embodiment of the present invention, the module coupling surface 10 and the prefabricated module 2 include magnetic surfaces with different polarities as coupling members, and can be coupled and fixed to each other. Specifically, the lower module lid 22, which forms the lower cross-section of the prefabricated module 2, includes a magnetic material surface having the same cross-section as the module coupling surface 10, and a magnetic material surface with a different polarity provided on the module coupling surface 10. It can be interconnected and fixed.

Alternatively, in another embodiment of the present invention, the prefabricated module (2) may be fixed by being coupled to the module coupling surface (10) in a fitting manner. Specifically, the module coupling surface 10 includes a groove formed on the inside, and the prefabricated module 2 and the module coupling surface 10 are mutually coupled and fixed in such a way that the lower end of the prefabricated module 2 is inserted into the groove. You can.

Alternatively, in another embodiment of the present invention, the prefabricated module 2 may be coupled and fixed to the module coupling surface 10 by a screw coupling method. Specifically, the module coupling surface 10 includes a screw thread formed on the inner surface of a groove formed inward, and the prefabricated module 2 includes a screw groove formed on the outer surface of the lower module lid 22 forming the lower part, The prefabricated module (2) and the module coupling surface 10 can be coupled and fixed to each other by screwing the lower end of the prefabricated module (2) into the groove.

In this way, the plurality of prefabricated modules 2 can be interconnected and fixed to or detached from the plurality of module coupling surfaces 10 of the main body module 1 in various ways that are easy to couple and detach.

Figure 3 shows types of prefabricated modules (2) according to an embodiment of the present invention.

As described above, the prefabricated module 2 is provided inside the main body module 1 and can perform various functions such as filtration function, purification function, temperature control function, etc. to control water temperature or improve water quality. Specifically, as shown in Figure 2, the prefabricated module (2) includes a filtration module (3) that performs a filtration function, a microbial purification module (4) that purifies water by reducing the concentration of ammonia and nitrate by microorganisms, and water temperature. It may include a temperature control module (5) that regulates, a skimmer module that removes suspended matter and proteins by generating bubbles, and an oxygen generation module that supplies oxygen to water to control the amount of dissolved oxygen.

Preferably, the water in the water tank (8) is sequentially circulated through the plurality of prefabricated modules (2) provided inside the main body module (1) by the pump (9) inside the water tank (8), so that the water temperature is adjusted or the water quality is improved. It can be improved.

The filtration module (3) is a device that improves water quality through the adsorption of impurities (waterweed residue, excrement, etc.) of a physical filter. It includes a filtration material (31) in which a plurality of filter materials are filled in the internal receiving space, and the water is 'filtered'. Impurities can be filtered out in the process of passing through a plurality of filtration materials 31 composed of or filled with a filtration material, thereby improving water quality.

The microbial purification module (4) is a device that implements a filtration cycle that reduces the concentration of ammonia generated according to the metabolic activities of ornamental fish, or improves water quality by reducing the concentration of nitrate generated by the filtration cycle. Specifically, the microbial purification module 4 is an aerobic microbial purification module 40 that converts ammonia into nitrate by aerobic microorganisms to reduce the concentration of ammonia, and an anaerobic microbial purification module 40 that reduces the concentration of nitrate by decomposing nitrate into nitrogen by anaerobic microorganisms. It may include a microbial purification module (41).

The filtration cycle refers to a circulation structure in which ammonia, which accumulates in the water tank (8) over time, is decomposed by microorganisms such as bacteria and oxidized into less toxic nitrate. Specifically, highly toxic ammonia (NH ₃ ) generated from excrement, carcasses, feed waste, etc. is dissolved into ammonium (NH ₄ ⁺ ), oxidized to nitrite (NO ₂ ^- ) by nitrosomonas, and then nitrated by nitrate bacteria. It can be oxidized and decomposed into less toxic nitrate (NO ₃ ^- ) by nitrobacter.

These filtering bacteria (nitrite bacteria, nitrate bacteria) are aerobic microorganisms, and can reduce the concentration of ammonia by performing the above-mentioned filtration cycle through oxygen.

In other words, the aerobic microorganism purification module 40 may be a device for reducing the concentration of ammonia by cultivating aerobic microorganisms in the internal receiving space.

Meanwhile, the concentration of nitrate generated through a filtration cycle by aerobic microorganisms can be reduced by performing a denitrification action in which nitrate is converted to nitrogen by anaerobic microorganisms. Nitrate can be converted into nitrogen by acting as food for aquatic plants such as aquatic plants and phytoplankton. However, in general, a sufficient amount of denitrification cannot be expected from the aquatic plants growing in the water tank (8) alone, so nitrate is converted to nitrogen by culturing anaerobic microorganisms. Concentration can be reduced.

That is, the anaerobic microorganism purification module 41 may be a device for reducing the concentration of nitrate by cultivating anaerobic microorganisms in the internal receiving space.

On the other hand, since the environments in which anaerobic microorganisms and aerobic microorganisms live are different, it may be desirable to cultivate each microorganism in different prefabricated modules (2), such as the anaerobic microorganism purification module (41) and the aerobic microorganism purification module (40). .

Specifically, since aerobic microorganisms require oxygen, oxygen is supplied to the aerobic microorganism purification module 40 through the bubble generator 7 to ensure that the filtration cycle by aerobic microorganisms is smoothly performed. Conversely, anaerobic microorganisms require oxygen. Therefore, denitrification by anaerobic microorganisms can be performed smoothly in a closed space.

In this way, aerobic microorganisms and anaerobic microorganisms can each be cultured in different environments.

The temperature control module 5 is a device that displays the water temperature in the water tank 8 and adjusts the water temperature according to the set temperature input by the user. Ornamental fish are sensitive to water temperature and are vulnerable to frequent and rapid changes in water temperature, so it is necessary to maintain an appropriate water temperature for ornamental fish to grow.

Specifically, the optimal water temperature for ornamental fish is different for each species. In the case of marine tropical fish and domestic freshwater fish, the water temperature should be set at 15 to 22 degrees because there are many cold-water fish species, and for freshwater tropical fish, the water temperature should be set at 22 to 28 degrees. There is a need.

In other words, the temperature control module (5) displays the current water temperature and heats or cools the water to maintain the water in the water tank (8) at an appropriate water temperature for the growth of ornamental fish, thereby adjusting the water temperature to the set temperature set by the user. It is a device for controlling.

The skimmer module is a device that bubbles and discharges dirt and organic matter in seawater. Specifically, the skimmer module may be an air lift method using air wood or a needle wheel method using an underwater motor, and generates fine bubbles in the skimmer pipe so that dirt and organic matter in the water tank (8) is filtered out through the bubbles and discharged. It could be a device. Preferably, the skimmer module may be provided to remove organic proteins such as excrement and feed floating in the tank 8 where seawater aquarium sharks are reared.

Specifically, the skimmer module utilizes the phenomenon in which organic impurities dissolved in water stick to the surface of air bubbles passing through the water column. This phenomenon occurs in water with high pH and salinity, so it is used in aquariums where saltwater ornamental sharks are reared (8). ), that is, it may be desirable to include it in an ornamental fish education kit provided in the aquarium 8 where seawater is stored.

That is, the skimmer module may also be a device for purifying the water quality of the water tank 8.

The oxygen generation module is a device that supplies oxygen to the water for the breathing activities of aquarium fish. Specifically, in order for ornamental fish to grow, it is desirable to maintain the amount of dissolved oxygen above 7 mg/L, and it is necessary to maintain at least 5 mg/L as the lower safe concentration limit. In this way, an air stone can be provided inside the aquarium (8) to supply oxygen for the aquarium fish to breathe, but in an environment where a large number of aquarium fish are raised or where the amount of dissolved oxygen may decrease due to high temperatures, a sufficient amount of oxygen is required. To supply oxygen, a separate oxygen generator needs to be provided.

As described above, the prefabricated module (2) of the present invention may vary in installed type and number depending on the size of the aquarium (8), species of ornamental fish, number of fish, etc., and the oxygen supply module has a capacity of the aquarium (8). It may be desirable to include it in an ornamental fish education kit provided in the aquarium 8 where a large number of ornamental fish are raised.

In this way, the prefabricated modules 2 are a plurality of devices for controlling the environmental conditions of the water tank 8 where ornamental fish can grow, and specifically adjust the water temperature, filter impurities, or purify water through a filtration cycle. It may be a device for doing so. In addition, all of the prefabricated modules (2) are provided in a form that is easy to assemble, disassemble, install, and detach, so that the user can explore the functions of each module by assembling the prefabricated modules (2) that perform various functions. You can learn.

Figure 4 shows a prefabricated module 2 according to an embodiment of the present invention.

As shown in Figure 4, the prefabricated module (2) can be coupled and fixed to a plurality of module coupling surfaces (10) provided on the main body module (1). As described above, the module coupling surface 10 of the main body module 1 includes a structure in which each of the plurality of prefabricated modules 2 can be coupled by an attachment method using a magnetic material, an insertion method, a screw coupling method, etc.

As an example, Figure 4 shows three prefabricated modules (2) (filtration module (3), microbial purification module (4), and temperature control module (5) in the main body module (1) including the three-piece module coupling surface (10). )) is shown attached and coupled by a magnetic material, each prefabricated module (2) includes an inlet 210 and an outlet 211 through which water can flow in and out, and a plurality of prefabricated modules (2) and the water tank 8 are connected by a plurality of pipes (the first internal water pipe 60, the second internal water pipe 61, and the external water pipe 62), so that the water in the water tank 8 is supplied to a plurality of prefabricated modules ( 2) By circulating, filtration, purification, and temperature control functions can be performed.

Preferably, the water in the water tank (8) is sequentially circulated through the filtration module (3), the aerobic microorganism purification module (40), and the temperature control module (5) by the pump (9) provided inside the water tank (8). , physical filtration, reduction of ammonia concentration by aerobic microorganisms, and water temperature control to the set temperature are performed, and can be discharged back into the water tank (8).

In this way, the prefabricated module 2 is coupled to the main body module 1 provided in a position where it can be connected to the water tank 8, so that the environmental conditions of the water can be adjusted.

Meanwhile, the first internal water pipe 60 is coupled with the inlet 210 in the internal receiving space of the prefabricated module 2, and the second internal water pipe 61 is connected to the outlet 211 in the internal receiving space of the prefabricated module 2. It is combined with, and the external water pipe 62 can be combined with the inlet 210 and the outlet 211 on the outside of the prefabricated module (2).

Specifically, the external water pipe 62 is a water pipe for the water in the water tank 8 to flow into or discharge from the prefabricated module 2, or the water in the internal accommodation space of the prefabricated module 2 flows into or discharges the water from the prefabricated module 2. It may be a water pipe to become a water pipe.

For example, in Figure 4, the external water pipe 62 is combined with the water tank 8 and the inlet 210 of the filtration module 3 to allow water from the water tank 8 to flow into the internal receiving space of the filtration module 3. , It is combined with the outlet 211 of the filtration module (3) and the inlet 210 of the microbial purification module (4), so that water from the internal receiving space of the filtration module (3) flows into the internal receiving space of the microbial purification module (4). It can be discharged or combined with the outlet 211 of the microbial purification module (4) and the inlet 210 of the temperature control module (5) so that the water in the internal receiving space of the microbial purification module (4) flows into the inside of the temperature control module (5). It may be a water pipe that flows in and out of the receiving space, or is combined with the outlet 211 of the temperature control module 5 and the water tank 8 to discharge water from the internal receiving space of the temperature control module 5 into the water tank.

Figure 5 shows a cross-sectional view of the prefabricated module 2 in which the upper module lid 21 and the lower module lid 22 are combined according to an embodiment of the present invention.

As shown in Figure 5, the prefabricated module 2 includes a module tube 20 that includes screw threads formed on the upper and lower outer surfaces and forms an internal receiving space of the prefabricated module 2; It is detachable from the upper surface of the module tube 20, including a screw groove corresponding to the screw thread formed on the upper outer surface of the module tube 20, and an inlet 210 through which water flows into the internal accommodation space, and an internal accommodation. An upper module lid (21) including an outlet (211) through which water in the space is discharged; And it is detachable from the lower surface of the module tube 20, including a screw groove corresponding to the thread formed on the lower outer surface of the module tube 20, and has a surface corresponding to the module coupling surface 10, It may include a lower module lid 22, which can be attached or detached from the module coupling surface 10 using a magnetic material or an insertion method.

In addition, the first internal water pipe 60 has one end that is not coupled to the inlet 210 located at the lower end of the internal receiving space of the prefabricated module 2, so that water flowing in from the outside is discharged from the lower end of the internal receiving space. One end of the second internal water pipe 61 that is not coupled to the outlet 211 is located at the upper end of the internal receiving space of the prefabricated module 2, so that water in the internal receiving space is discharged from the upper end of the internal receiving space. It can be.

The module tube 20 can form the internal receiving space of the prefabricated module 2. Specifically, the module tube 20 is a tube with open upper and lower sides, and the upper and lower sides are closed by the upper module lid 21 and the lower module lid 22 to form the internal receiving space of the prefabricated module 2. .

In addition, the components provided in the internal accommodation space of the module tube 20 may be different depending on the type of the prefabricated module 2, that is, the function performed by the prefabricated module 2. Specifically, when the prefabricated module (2) is a filtration module (3), a plurality of filtration materials (31) and polynagel sponges (32) for filtration that perform a physical filtration function can be accommodated in the internal accommodation space, and purification of aerobic microorganisms is possible. In the case of the module 40, an aerobic microbial culture medium 400 in which aerobic microorganisms that purify water through a filtration cycle are cultured can be accommodated, and in the case of the anaerobic microbial purification module 41, nitrate is converted to nitrogen in the internal accommodation space. The anaerobic microbial culture material 410, in which anaerobic microorganisms that purify water are cultivated, can be accommodated, and in the case of the temperature control module 5, a set temperature is input from the user in the internal receiving space and the water temperature is adjusted to the corresponding temperature. A thermostat can be accommodated.

Meanwhile, the upper and lower outer surfaces of the module tube 20 may include threads through which the upper module lid 21 and the lower module lid 22 can be coupled.

The upper module lid 21 can be attached to and detached from the upper side of the module tube 20 to open and close the module tube 20. Specifically, the upper module lid 21 includes a screw groove corresponding to the thread formed on the upper outer surface of the module tube 20, and can be screwed to the upper side of the module tube 20.

Meanwhile, in one embodiment of the present invention, the upper module lid 21 further includes a rubber packing at the joint with the module tube 20, so that the internal receiving space of the prefabricated module 2 has a watertight structure. By doing so, water in the internal receiving space can be prevented from leaking to the outside.

Meanwhile, the upper module lid 21 may further include an inlet 210 through which water flows in from the outside and an outlet 211 through which water from the internal receiving space is discharged. Specifically, the inlet 210 and the outlet 211 include a corrugated pipe or curved pipe that can be bent into an L shape on the outer surface of the upper module lid 21, and one end of the corrugated pipe or curved pipe is formed as an external space. , the other end can be formed in the internal receiving space of the prefabricated module (2).

Additionally, the inlet 210 and outlet 211 may also be coupled to the upper module lid 21 in a screw manner.

The inlet 210 is a member that allows water to flow into the internal receiving space from the outside of the prefabricated module 2. One end is formed as an external space, the other end is formed as an internal receiving space, and can be bent in an L-shape. May include corrugated or curved pipes. Specifically, one end of the corrugated pipe or curved pipe formed in the external space is connected to the outside, that is, the external water pipe 62, which is connected to the water tank 8 or another prefabricated module 2, and the corrugated pipe or curved pipe formed in the internal receiving space is connected. The other end of the pipe is connected to the first internal water pipe 60 located in the internal receiving space, so that water flowing in from the external water pipe 62 passes through the first internal water pipe 60 to the internal receiving space of the prefabricated module (2). can be discharged as

The outlet 211 has a shape symmetrical to the inlet 210 and is a member capable of discharging water from the internal receiving space of the prefabricated module 2 to the outside. One end is formed as an external space, and the other end is internally received. It is formed as a space and may include a corrugated pipe or a curved pipe that can be bent into an L shape. Specifically, one end of the corrugated pipe or curved pipe formed in the external space is connected to the outside, that is, the external water pipe 62, which is connected to the water tank 8 or another prefabricated module 2, and the corrugated pipe or curved pipe formed in the internal receiving space is connected. The other end of the pipe is connected to the second internal water pipe 61 located in the internal receiving space, so that water in the internal receiving space flowing in from the second internal water pipe 61 can be discharged to the outside through the external water pipe 62. there is.

The lower module lid 22 can be attached to and detached from the lower side of the module tube 20 to open and close the module tube 20. Specifically, the lower module lid 22 includes a screw groove corresponding to the thread formed on the lower outer surface of the module tube 20, and can be screwed to the lower side of the module tube 20.

Meanwhile, in one embodiment of the present invention, the lower module lid 22 further includes a rubber packing at the joint with the module tube 20, so that the internal receiving space of the prefabricated module 2 has a watertight structure. By doing so, water in the internal receiving space can be prevented from leaking to the outside.

In addition, the lower module lid 22 may further include a structure for being coupled to the module coupling surface 10 of the main body module 1. As described above, the module coupling surface 10 of the main body module 1 and the prefabricated module 2 can be coupled and fixed to each other by an attachment method using a magnetic material, an insertion method, a screw coupling method, etc.

In one embodiment of the present invention, when the module coupling surface 10 and the prefabricated module 2 are attached and interconnected by a magnetic material, the lower surface of the lower module lid 22 is formed on the module coupling surface 10. The lower module lid 22, which forms the lower cross-section of the prefabricated module 2, including a magnetic surface having the same shape and size as the magnetic surface but with a different polarity, is attached to the module coupling surface 10 and a magnetic material. can be combined.

Alternatively, in another embodiment of the present invention, when the module coupling surface 10 and the prefabricated module 2 are coupled to each other by insertion, the lower module lid 22 is formed inside the module coupling surface 10. By having a shape and size corresponding to the groove, the lower module lid 22 can be coupled to the module coupling surface 10 in a manner that fits into it.

In this way, the upper module lid 21 and the lower module lid 22 can be screwed to the upper and lower sides of the module tube 20 to form an internal receiving space with a watertight structure, and the upper module lid 21 has an inlet ( 210) and outlet 211, through which water flows in and out, and the lower module lid 22 has a structure that can be interconnected with the module coupling surface 10, so that the prefabricated module 2 can be connected to the module coupling surface. It can be coupled to (10) and fixed.

In addition, the upper module lid 21 and the lower module lid 22 of the prefabricated module 2 can be attached and detached to the module tube 20 using a screw connection method, so that the user can easily assemble or detach it.

In this way, the prefabricated module (2) is attached and detached to the coupling surface of the main body module (1) by magnetic material, fitting, and screwing, and the upper module lid (21) and lower module lid (22) are also screwed together, If the user wants to clean the prefabricated module 2 or replace its internal structure, it can be easily detached and reassembled.

Meanwhile, one end of the first internal water pipe 60, which is coupled to the inlet 210 of the prefabricated module 2 and flows water into the internal receiving space from the outside of the prefabricated module 2, may be located at the lower end of the internal receiving space. And, one end of the second internal water pipe 61, which is coupled to the outlet 211 of the prefabricated module 2 and discharges water to the outside from the internal receiving space of the prefabricated module 2, may be located at the upper end of the internal receiving space. there is.

Specifically, as shown in Figure 5, the first internal water pipe 60 and the second internal water pipe 61 are respectively coupled to the inlet 210 and outlet 211 of the upper module lid 21, and the first internal water pipe 60 The water pipe 60 may have a length such that one end of the first internal water pipe 60 can be located at the lower end of the internal receiving space of the prefabricated module 2, and the second internal water pipe 61 is a second internal water pipe ( One end of 61) may have a length that allows it to be located at the upper end of the internal receiving space of the prefabricated module (2).

As a result, 'water discharged from the outside into the internal receiving space of the prefabricated module (2) through the inlet 210' can be discharged from the end of the first internal water pipe 60 located at the lower end of the internal receiving space, and ' The water in the internal receiving space of the prefabricated module (2) flows in from the end of the second internal water pipe (61) located at the upper end of the internal receiving space and passes through the outlet (211) to the outside (water tank (8) or other prefabricated module ( 2)) can be discharged.

Figure 6 shows an inlet 210 where the external water pipe 62 and the first internal water pipe 60 are combined, and an outlet where the external water pipe 62 and the second internal water pipe 61 are combined according to an embodiment of the present invention ( 211) shows a cross-sectional view.

As shown in FIG. 6, at one end of the inlet 210 located outside the prefabricated module 2, there is an external water pipe 62 through which water flows from the water tank 8 or another prefabricated module 2. It is coupled by this screw coupling method, and the first internal water pipe 60 through which water is discharged into the internal accommodation space is coupled to the other end located on the inner receiving space side of the prefabricated module (2) by screw coupling method, and the prefabricated module (2) is coupled with a screw coupling method. At one end of the outlet 211 located on the inner receiving space side of the module 2, a second internal water pipe 61 through which water flows into the inner receiving space is coupled by a screw coupling method, and the prefabricated module 2 ), an external water pipe 62 through which water is discharged to the water tank 8 or another prefabricated module 2 may be coupled to the other end located on the outside of the water tank 8 using a screw coupling method.

As shown in the right inlet 210 of FIG. 6, the upper module lid 21 is formed on the outside and includes a coupling hole that can be coupled to the inlet 210 as a perforation including a screw thread on the outer surface, and the coupling. The coupling hole of the upper module lid 21 and the inlet 210 may be screwed together by the inlet 210 having a thread groove corresponding to the thread formed on the outer surface of the sphere. That is, in one embodiment of the present invention, the inlet 210 is coupled to the upper module lid 21 by a screw connection method, so that the user can easily attach and detach it.

Meanwhile, the 'outer surface of one end of the inlet 210 formed outside of the prefabricated module 2' includes screw threads, and the outer surface has 'the outer surface of one end of the inlet 210 formed outside of the prefabricated module 2'. The inlet 210 and the external water pipe 62 may be screwed together by the external water pipe 62 including a screw groove corresponding to the thread 'formed in.

In addition, the 'outer surface of one end of the inlet 210 formed as the internal receiving space of the prefabricated module 2' includes a screw thread, and the outer surface 'inlet 210 formed as the internal receiving space of the prefabricated module 2' The inlet 210 and the first internal water pipe 60 may be screwed together by the first internal water pipe 60 including a thread groove corresponding to the 'thread thread' formed on the outer surface of one end of the.

As a result, as shown on the right side of FIG. 6, the upper module lid 21 and the inlet 210, the inlet 210 and the external water pipe 62, and the inlet 210 and the first internal water pipe 60 are all screwed. When combined, water outside the prefabricated module 2 can be discharged into the internal receiving space of the prefabricated module 2 via the external water pipe 62, the inlet 210, and the first internal water pipe 60.

Meanwhile, as described above, the first internal water pipe 60 has a length that can be extended to the lower end of the internal receiving space of the prefabricated module 2, so that water flowing in from the outside flows into the first water conduit at the lower end of the internal receiving space. It can be discharged into the internal receiving space through the internal water pipe 60.

Meanwhile, the outlet 211 may have a shape symmetrical to the inlet 210 described above. Specifically, as shown in the left outlet 211 of FIG. 6, the upper module lid 21 is formed on the outside and has a separate coupling hole that can be coupled to the outlet 211 as a perforation including threads on the outer surface. Including, the coupling port of the upper module lid 21 and the outlet 211 may be screwed together by the outlet 211 having a thread groove corresponding to the thread formed on the outer surface of the coupling port. That is, in one embodiment of the present invention, the outlet 211 is coupled to the upper module lid 21 by a screw connection method, so that the user can easily attach and detach it.

Meanwhile, the 'outer surface of one end of the outlet 211 formed outside of the prefabricated module 2' includes screw threads, and the outer surface has 'the outer surface of one end of the outlet 211 formed outside of the prefabricated module 2'. The outlet 211 and the external water pipe 62 can be screwed together by the external water pipe 62 including a screw groove corresponding to the thread 'formed in.

In addition, the 'outer surface of one end of the outlet 211 formed as the internal receiving space of the prefabricated module 2' includes a screw thread, and the outer surface has an 'outlet 211 formed as the internal receiving space of the prefabricated module 2'. The outlet 211 and the second internal water pipe 61 can be screwed together by the second internal water pipe 61 including a thread groove corresponding to the thread 'formed on the outer surface of one end of the.

As a result, as shown on the left side of FIG. 6, the upper module lid 21 and the outlet 211, the outlet 211 and the external water pipe 62, and the discharge port 211 and the second internal water pipe 61 are all screwed. By combining, the water in the internal receiving space of the prefabricated module (2) can be discharged to the outside of the prefabricated module (2) through the second internal water pipe (61), the discharge port (211), and the external water pipe (62).

Meanwhile, as described above, the second internal water pipe 61 has a length that can be extended to the upper end of the internal receiving space of the prefabricated module 2, so that water in the internal receiving space flows from the upper end of the internal receiving space to the second interior. It can be discharged to the outside through the water pipe 61.

In this way, the prefabricated module 2 having the form described above in FIGS. 5 and 6 can be easily attached and detached from the main body module 1 by attachment, insertion, or screwing using a magnetic material, and the prefabricated module ( 2) Each component (module tube 20, upper module lid 21, lower module lid 22, inlet 210, and outlet 211) also has a screw connection, so it can be easily combined. .

Additionally, as described above, the type of the prefabricated module 2 may be determined depending on the components introduced into the internal accommodation space of the prefabricated module 2. For example, when a filtration material (31) and a polynagel sponge (32) for filtration that perform a physical filtration function are introduced into the prefabricated module (2), the prefabricated module (2) may be a filtration module (3). , when culture material for cultivating aerobic microorganisms or anaerobic microorganisms is introduced into the prefabricated module (2), the prefabricated module (2) may be a microbial purification module (4), and the temperature control function is installed inside the prefabricated module (2). When a temperature control device that performs is introduced, the prefabricated module (2) may be the temperature control module (5).

Meanwhile, as described above, depending on the type of the prefabricated module 2, a separate configuration may be further included in the form of the prefabricated module 2 described above in FIGS. 5 and 6. Specifically, in the case of the aerobic microorganism purification module 40, it may further include a bubble penetration hole 212 through which the bubble ejection pipe 70 that supplies air by the bubble generator 7 for the activity of aerobic microorganisms can penetrate. This can be done, and a more detailed description of this will be provided later.

Figure 7 shows a filtration module 3 according to one embodiment of the present invention.

As shown in FIG. 7, the filtration module 3 has a shape corresponding to the cross section of the module pipe 20 and includes a plurality of through holes through which the first internal water pipe 60 can pass. Filtration material (31); And it has a shape corresponding to the cross section of the module pipe 20, includes a through hole through which the first internal water pipe 60 can pass, and is located between the joint surfaces of the plurality of filtration materials 31. and one or more polynagel sponges (32) for filtration, wherein the plurality of filtration materials (31) are filter materials containing one or more of volcanic stone, elvan stone, silica, activated carbon, and diatomaceous earth, or the plurality of filtration materials (31) Each interior has a form that can be filled with a filtration material including one or more of volcanic stone sand, elvan sand, silica sand, activated carbon sand, and diatomaceous earth sand, and the plurality of filtration materials ( 31) and one or more polynagel sponges for filtration (32) are sequentially assembled to allow water to be filtered by sequentially passing through a plurality of filter media or filtration materials in the internal receiving space of the filtration module (3).

As shown in (a) of Figure 7, the filtration module 3 is a plurality of filtration materials 31 that may be composed of a filtration material or filled with a filtration material and a filtration module located between the plurality of filtration materials 31. It may include a polyna gel sponge (32). Specifically, the cross section of the filtration material 31 and the polynagel sponge 32 for filtration may include a through hole that can be inserted into the first internal water pipe 60. Preferably, the size and shape of the through hole are the same as the cross section of the first internal water pipe 60, so that the through hole of the filtration material 31 and the polynagel sponge 32 for filtration is formed in the first internal water pipe 60. It can be combined in a penetrating form.

The filtration material 31 is composed of a filter material containing one or more of volcanic stone, elvan sand, silica, activated carbon, and diatomaceous earth, or is composed of a filter material containing one or more of volcanic stone sand, elvan sand, silica sand, activated carbon sand, and diatomaceous earth sand. It may be a component that has a form that can be filled inside.

Specifically, the filter media or filtration materials are made of materials with different surface areas, adhesion, etc., so that impurities can be physically filtered while water passes through a plurality of filter media or filtration materials in the internal receiving space of the filtration module 3.

Meanwhile, if the filtration material 31 includes activated carbon or activated carbon sand, a chemical filtration process may be performed. Specifically, activated carbon or activated carbon sand has a large internal surface area of 1000 m ² per gram, so non-polar impurities present at the molecular level in water can be chemically filtered by activated carbon.

As such, according to one embodiment of the present invention, the user can explore and learn the filtration function according to the material of the filter material or filtration material by performing a physical filtration process and a chemical filtration process using various types of filter media or filtration materials. You can.

The polynagel sponge for filtration (32) may be positioned between a plurality of filtration materials (31). Specifically, the polynagel sponge for filtration (32) has a large surface area and can perform a physical filtration function.

Figure 7 (b) shows the shape of the filtration material 31 and the polynagel sponge 32 for filtration. Specifically, the filtration material 31 has a cross section of the module pipe 20, that is, has a shape corresponding to the cross section of the filtration module 3, and has a first through hole 310 through which the first internal water pipe 60 can penetrate. may include. That is, the user inserts the first through hole 310 formed in the filtration material 31 into the first internal water pipe 60 coupled to the upper module lid 21 of the filtration module 3. can be assembled.

Meanwhile, if the filtration material 31 is a filter material containing one or more of volcanic stone, elvan rock, silica, activated carbon, and diatomaceous earth, the filtration material 31 may be a single material filter material having the above-mentioned form.

Alternatively, the filtration material 31 may be in the form of a filtration material containing one or more of volcanic stone sand, elvan sand, silica sand, activated carbon sand, and diatomaceous earth sand filled into a filter net having the above-mentioned form. Specifically, the filtration mesh is made of a material that allows water to pass through but cannot pass through the filtration material, and may further include a separate opening and closing member (not shown) capable of filling the filtration material.

The opening and closing member may be provided on either the top or the side of the filter net at a position where a user can easily fill the filter material, but is not limited to this and may be implemented in various forms.

That is, the filtration material 31 may be in a form that allows the user to fill the interior with filtration material through an opening and closing member (not shown) of the filtration network.

The polynagel sponge 32 for filtration has a cross section of the module pipe 20, that is, a shape corresponding to the cross section of the filtration module 3, and a second through hole 320 through which the first internal water pipe 60 can penetrate. ) may include. That is, the user inserts the second through hole 320 formed in the polynagel sponge 32 for filtration into the first internal water pipe 60 coupled to the upper module lid 21 of the filtration module 3. Polynagel sponge (32) can be assembled.

As a result, the user installs 'filtration material (31) consisting of a filter material containing one or more of volcanic rock, elvan rock, silica, activated carbon, and diatomaceous earth and including a through hole' and 'polynagel sponge for filtration (32)' into the first interior. The filtration module (3) can be formed by inserting it into the water pipe (60).

Alternatively, the user may use 'filtration material (31) consisting of a filter media that can be filled with a filtration material containing one or more of volcanic rock sand, elvan sand, silica sand, activated carbon sand, and diatomaceous earth sand and including through holes' and 'filtration material 31'. The filtration module (3) can be formed by inserting the 'polynagel sponge (32)' into the first internal water conduit pipe (60).

Meanwhile, as described above, one end of the first internal water pipe 60 through which water is discharged is located at the lower end of the prefabricated module (2), and one end of the second internal water pipe 61 into which water flows is located at the lower end of the prefabricated module (2). Since it is located at the upper end, as shown in (a) of FIG. 7, water flowing in from the outside through the first internal water pipe 60 is discharged from the lower end of the filtration module 3, and a plurality of filtration materials 31 and It passes through the polynagel sponge for filtration (32), flows in through the second internal water pipe (61) at the upper end of the filtration module (3), and can be discharged to the outside.

On the other hand, if the filter media and filtration material are used for a long period of time, organic substances, contaminants, etc. may attach, bacteria may attach, and filtration performance may deteriorate, so they need to be replaced periodically. As described above, the prefabricated module of the present invention (2) (Filtration module (3)) has components that can be decoupled by screwing or inserting into a through hole, allowing users to easily replace or clean the filter medium.

In this way, the user can perform filtration in various ways, such as changing the type of filter material constituting the filtration material 31 or the type of filtration material filled, or adjusting the gap between the filtration material 31 and the polynagel sponge 32 for filtration. You can construct module (3) and explore and learn the filtration function and effect of each filter medium and filtration material.

Figure 8 shows an aerobic microbial purification module 40 according to an embodiment of the present invention.

As shown in FIG. 8, the microbial purification module 4 has a bubble through which the bubble ejection pipe 70, through which air generated by the bubble generator 7 is supplied, can penetrate the upper module lid 21. It further includes a through hole 212, and the bubble ejection pipe 70 is provided in the lower internal receiving space of the microbial purification module 4 with one end from which bubbles are ejected facing upward, and the bubble generator 7 ) may include an aerobic microbial purification module 40 that purifies water by supplying the air generated by the aerobic microbial culture medium 400 floating in the internal receiving space.

The aerobic microorganism purification module 40 can purify water as aerobic microorganisms cultured inside perform a filtration cycle that converts ammonia in water into nitrate. Specifically, aerobic microorganisms may include nitrite bacteria, nitrate bacteria, etc.

The aerobic microbial purification module 40 may include an aerobic microbial culture medium 400 in which aerobic microorganisms are cultured. Specifically, the aerobic microbial culture medium 400 is a porous plastic, and on its surface, nitrite bacteria that oxidize ammonia to nitrite by oxygen, and nitrate bacteria that oxidize nitrite to nitrate can be cultured.

Additionally, the aerobic microbial culture material 400 can be suspended by gas aeration in the internal accommodation space of the aerobic microbial purification module 40.

Meanwhile, aerobic microorganisms grow in an environment rich in oxygen (air), so it is necessary to supply air in order to smoothly perform a filtration cycle by aerobic microorganisms.

Therefore, the upper module lid 21 of the aerobic microorganism purification module 40 has a bubble ejection pipe 70 through which bubbles generated by the external bubble generator 7 pass and are ejected into the water in the internal receiving space. It may further include a bubble penetration hole 212. Specifically, a bubble generator (7) capable of generating bubbles may be provided on one side of the aerobic microbial purification module (40), and the air generated from the bubble generator (7) may be supplied through the bubble penetration hole (21) of the upper module lid (21). It can be discharged from the internal receiving space of the aerobic microbial purification module 40 through the bubble ejection pipe 70 penetrating 212).

Preferably, one end of the bubble ejection pipe 70 is connected to the bubble generator 7, and the other end is provided to face upward from the lower end of the internal receiving space of the aerobic microbial purification, so that the aerobic microbial purification is ejected by the bubble ejection pipe 70. The air can be blown out from the lower part of the internal receiving space of the aerobic microbial purification toward the upper side.

More preferably, the bubble penetration hole 212 may have a shape corresponding to the cross-section of the bubble ejection pipe 70.

Meanwhile, the reason why the bubble discharge pipe 70 is provided to face upward from the lower end of the internal receiving space of the aerobic microbial purification may be to prevent water from flowing back through the bubble discharge pipe 70.

Meanwhile, as described above, one end of the first internal water pipe 60 through which water is discharged is located at the lower end of the prefabricated module (2), and one end of the second internal water pipe 61 into which water flows is located at the lower end of the prefabricated module (2). Since it is located at the upper end, as shown in FIG. 8, water flowing in from the outside through the first internal water pipe 60 is discharged from the lower part of the aerobic microbial purification module 40, and the aerobic microbial culture material suspended by gas aeration It may pass through (400), flow in through the second internal water pipe (61) at the upper end of the aerobic microbial purification module (40), and be discharged to the outside.

In this way, the user introduces the aerobic microbial culture material 400, in which aerobic microorganisms are cultured, into the internal receiving space of the aerobic microbial purification module 40, and the air generated by the bubble generator 7 is aerobic through the bubble discharge pipe 70. By supplying water to the internal accommodation space of the microbial purification module 40, it is possible to explore and learn about the process of purifying water by performing a filtration cycle by aerobic microorganisms and the effect of oxygen on aerobic microorganisms.

Figure 9 shows an anaerobic microbial purification module 41 according to an embodiment of the present invention.

As shown in FIG. 9, the microbial purification module 4 has a shape corresponding to the cross section of the module pipe 20 and includes a through hole through which the first internal water pipe 60 can pass, It may include an anaerobic microbial purification module 41 that purifies water using the anaerobic microbial culture material 410 that can be fitted into the first internal water pipe 60.

The anaerobic microorganism purification module 41 can purify water as anaerobic microorganisms cultured inside perform a denitrification action that converts nitrate into nitric acid.

The anaerobic microorganism purification module 41 may include an anaerobic microorganism culture medium 410 in which anaerobic microorganisms are cultured. Specifically, the anaerobic microbial culture material 410 is a polynagel sponge and has a shape corresponding to the cross section of the anaerobic microbial purification module 41, and may include a through hole through which the first internal water pipe 60 can penetrate. .

As shown in FIG. 9, the user can assemble the first internal water conduit pipe 60 by inserting a through hole of the anaerobic microbial culture material 410.

On the other hand, since anaerobic microorganisms grow in an environment without oxygen (air), it may be desirable not to supply oxygen through the bubble generator (7).

That is, aerobic microorganisms and anaerobic microorganisms can be cultured in different environments depending on the presence or absence of oxygen using the aerobic microorganism purification module 40 and the anaerobic microorganism purification module 41.

Meanwhile, as described above, one end of the first internal water pipe 60 through which water is discharged is located at the lower end of the prefabricated module (2), and one end of the second internal water pipe 61 into which water flows is located at the lower end of the prefabricated module (2). Since it is located at the upper end, as shown in FIG. 9, water flowing in from the outside through the first internal water pipe 60 is discharged from the lower part of the anaerobic microbial purification module 41, passes through the anaerobic microbial culture material 410, and , may flow in from the upper part of the anaerobic microorganism purification module 41 through the second internal water pipe 61 and be discharged to the outside.

In this way, the user introduces the anaerobic microorganism culture material 410, in which anaerobic microorganisms are cultured, into the internal receiving space of the anaerobic microorganism purification module 41, and explores and learns the process of water purification through denitrification by anaerobic microorganisms. can do.

Figure 10 shows a temperature control module 5 according to an embodiment of the present invention.

As shown in Figure 10, the temperature control module 5 includes a control unit 51 that receives a set temperature from the user and controls the water temperature to be adjusted to the set temperature; A Peltier element 50 that heats or cools water to adjust the water temperature to the set temperature based on the control command received from the control unit 51, and a display unit 52 that displays information about the current water temperature and the set temperature. The temperature of the water can be adjusted by a temperature control device including.

As shown in Figure 10 (b), the temperature control module 5 includes a temperature control device, and the temperature control device includes a control unit 51, a display unit 52, a Peltier element 50, and a set temperature input unit. (not shown), including a temperature sensor (not shown), can receive a set temperature from the user and heat or cool the water to adjust the water temperature to the set temperature. Additionally, the control unit 51, display unit 52, Peltier element 50, set temperature input unit (not shown), and temperature sensor (not shown) may be connected by wire within the temperature control device.

Specifically, the control unit 51 may receive the set temperature input by the user from the set temperature input unit (not shown) and transmit a control command accordingly to the Peltier element 50.

The display unit 52 may display the current water temperature sensed by a temperature sensor (not shown) or display the set temperature input by the user.

The Peltier element 50 is a temperature control material that uses the Peltier effect in which both ends of a conductive material generates or absorbs heat due to an electric current. It has excellent cooling and heat generation performance, can be used semi-permanently, and allows precise temperature control, as in the present invention. It may be a temperature control material suitable for use in small devices.

The set temperature input unit (not shown) may include an interface through which the user can input the set temperature.

In one embodiment of the present invention, the set temperature input unit (not shown) may be implemented as an interface that allows the user to input a specific set temperature (for example, 25 degrees). In this case, the user can input a specific set temperature through the set temperature input unit (not shown), and the water in the internal accommodation space of the temperature control module 5 is set to the corresponding setting by the control unit 51 and the temperature sensor (not shown). Feedback control can be performed to adjust the temperature.

Or, in another embodiment of the present invention, the set temperature input unit (not shown) allows the user to heat or cool water in stages (for example, heating stages 1, 2, 3, 4, and 5 and cooling stages 1, 2, 3, 4, Step 5) It can be implemented as an interface. Specifically, the interface may be an interface that allows the user to control the thermostat to heat or cool the water by 0.5 degrees, 1 degree, 1.5 degrees, 2 degrees, and 2.5 degrees. In this case, the user can check the current water temperature through the display unit 52 and adjust the water to the corresponding set temperature by heating or cooling the water to the set temperature through the set temperature input unit (not shown).

On the other hand, when the set temperature input unit (not shown) is implemented as an interface that allows the user to heat or cool the water step by step, it allows the user to continuously monitor the water temperature and adjust the temperature, rather than adjusting the water temperature through feedback control. It can induce constant interest from users.

Meanwhile, as shown in Figure 10 (a), the temperature control module 5 does not include a separate upper module lid 21, and the temperature control device forms the top and upper surface of the temperature control module 5. It can be manufactured to do so. Specifically, the temperature control device is integrated with the module pipe 20 of the temperature control module 5, and may be manufactured to include an inlet 210 and an outlet 211 on the upper surface. In this case, the user can clean the inside of the temperature control module (5) by opening the lower module lid (22) of the temperature control module (5).

On the other hand, since the temperature control module 5 also includes a first internal water pipe 60 and a second internal water pipe 61, as shown in (a) of FIG. 10, The inflow water can be adjusted to a set temperature by a temperature control device, flow in through the second internal water pipe 61, and be discharged to the outside.

In this way, the user can explore and learn the effect of water temperature on the growth of ornamental fish by adjusting the water temperature to an appropriate water temperature for the growth of ornamental fish using the temperature control module 5.

Meanwhile, in one embodiment of the present invention, the temperature control device of the temperature control module 5 may further include a communication unit (not shown). Specifically, the temperature control module 5 is an IoT terminal equipped with a communication function capable of connecting to a server and a network. It transmits information such as whether the temperature control device is operating and the set temperature to the server, so that the user can control the temperature according to the given manual. You can check and verify whether the device is being operated.

Meanwhile, in one embodiment of the present invention, the aquarium fish education kit 1000 may further include a plurality of sensors that measure one or more of pH, salinity, nitrate, phosphate, nitrite, and ammonia in the water tank 8. Specifically, the sensors are provided in a water tank (8) connected to the aquarium fish education kit (1000), or in a plurality of prefabricated modules (2) through which water in the water tank (8) circulates, and measure water pH, salinity, nitrate, phosphate, and nitrite. , more than one of ammonia can be measured.

Preferably, the plurality of sensors can sense a plurality of data that needs to be inspected and managed in order to raise ornamental fish.

Additionally, the sensing information measured by the plurality of sensors may be displayed by a separate display device. Specifically, the user can check the sensing information measured by the plurality of sensors to continuously check and manage whether the environmental conditions of the aquarium are maintained in an environment in which ornamental fish can grow.

In this way, users can check sensing information about water pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. and manage water quality to explore and learn about the impact of environmental conditions on the growth of ornamental fish.

In one embodiment of the present invention, the sensing information measured by the plurality of sensors may be displayed by the display unit 52 of the temperature control module 5. Specifically, the display unit 52 of the temperature control module 5 can further display sensing information about water pH, salinity, nitrate, phosphate, nitrite, ammonia, etc., along with the water temperature.

Additionally, sensing information measured by the plurality of sensors may be transmitted to a server. As described above, the server is the entity that checks and verifies whether the user is operating the thermostat according to the given manual. The server provides training to the user according to the given manual through a plurality of sensing information. You can check and verify whether it exists or not.

In one embodiment of the present invention, the sensing information measured by the plurality of sensors may be transmitted to the server by a communication unit (not shown) of the temperature control module 5.

2. Animal-mediated self-directed learning education method using a modular aquarium fish education kit that can be connected to the metaverse and psychological healing method through animal communication

Below, the animal-mediated self-directed learning education method and psychological healing through animal communication using the modular aquarium fish education kit that can be connected to the metaverse, which is carried out using the above-mentioned "1. Modular ornamental fish education kit" The “method” is described in detail.

Meanwhile, the following users are users who perform "2. Animal-mediated self-directed learning education method and psychological healing method through animal communication using a modular aquarium fish education kit that can be connected to the metaverse" and the user terminal owned by the user. It can mean, and the server system is a server that performs "2. Animal-mediated self-directed learning education method and psychological healing method through animal communication using a modular ornamental fish education kit that can be connected to the metaverse" and the server's It can mean an administrator, and the curriculum is "2. Animal-mediated self-directed learning education method using a modular ornamental fish education kit that can be connected to the metaverse and psychological healing method through animal communication" so that users can raise ornamental fish. It can mean a series of processes of learning.

Figure 11 shows components for implementing an education and psychological healing method using the modular ornamental fish education kit 1000 according to an embodiment of the present invention.

As shown in (a) of Figure 11, the invention of the present application is 'Animal-mediated self-directed learning education method and psychological healing method through animal communication using a modular ornamental fish education kit that can be connected to the metaverse' (hereinafter referred to as ornamental fish education) Method) includes an ornamental fish training kit (1000) provided to a user, a user terminal (2000) through which the user can receive a manual for the ornamental fish training kit (1000) or request compensation for training, and the ornamental fish training kit (1000). ) and the user terminal 2000 can communicate wired and wirelessly, and can be performed by the server system 4000, which evaluates the user's training course and provides appropriate compensation accordingly.

The ornamental fish education kit (1000) is a device described above in "1. Modular ornamental fish education kit (1000)", and the ornamental fish education kit (1000) communicates with the server system (4000) to transmit relevant water temperature information, etc. Communication functions may be provided. Specifically, the ornamental fish education kit 1000 is an IoT terminal, and includes a temperature control module 5 capable of transmitting information about whether the temperature control device is operating, current water temperature, and temperature set by the user to the server system 4000. may include. Preferably, the temperature control module 5 includes a temperature control device, and the temperature control device controls the current water temperature measured by the temperature sensor under the control of the control unit and the set temperature input by the user through the set temperature input unit. It may include a communication unit that transmits information, etc. to the server system 4000.

Additionally, sensing information about pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. sensed by a plurality of sensors may also be transmitted to the server system 4000.

In addition, as described above, each component forming the aquarium fish education kit 1000 may have a form that allows the user to easily attach and detach it through screw coupling, magnetic material, etc.

The user terminal 2000 may correspond to various types of computing devices that can communicate with the server system 4000, display information, and receive input from the user. In addition, the user terminal 2000 is installed with a web browser capable of executing an application or a web page for communicating with the server system 4000, and the server system 4000 runs the application or the web page. ) can communicate with.

Specifically, the user executes the application provided by the server system 4000 through the user terminal 2000 or accesses the web page, and obtains the identification information of the ornamental fish education kit 1000, purchase date and time of ornamental fish, population, fish species, and the above. You can start the training course by sending the first fry image taken of the ornamental fish, or it includes information on the overall curriculum, such as how to assemble and use the ornamental fish education kit (1000) and the optimal environmental conditions for the growth of ornamental fish. You can receive a manual, request compensation for completing the course, and end the course.

Preferably, the user terminal 2000 is a computing device including one or more processors and one or more memories, such as a laptop, desktop, laptop, smartphone, PCS (Personal Communication System), GSM (Global System for Mobile communications), PDC (Personal Digital Cellular), PHS (Personal Handyphone System), PDA (Personal Digital Assistant), IMT (International Mobile Telecommunication)-2000, CDMA (Code Division Multiple Access)-2000, W-CDMA (W- Code Division Multiple Access), Wibro (Wireless Broadband Internet) terminal, etc.

The server system 4000 is a server operated by an administrator who is the operator of the ornamental fish education method, and communicates with the ornamental fish education kit 1000 and the user terminal 2000 to register users performing the education process, or You can provide a manual containing information about the overall curriculum, perform an evaluation of the curriculum, and provide compensation based on performance results.

Specifically, the server system 4000 receives the identification information of the ornamental fish education kit 1000, the purchase date and time of the ornamental fish, the number of fish, the species, and the first fry image taken of the ornamental fish from the user terminal 2000, which is about to start the training course. You can receive it and register the user. Alternatively, the server system 4000 periodically receives real-time water temperature information about the current water temperature from the aquarium fish education kit 1000 of the user performing the training course, and allows the user to complete the training course by the manager of the server system 4000. It can be judged whether or not it is being performed faithfully. Alternatively, the server system 4000 receives an image of an adult ornamental fish grown from the user terminal 2000 that completes the training course, and an evaluation according to the user's training course is performed by the manager of the server system 4000, Compensation accordingly may be provided through the user terminal 2000.

Meanwhile, the server system 4000 may further include a separate database capable of storing data necessary to perform the above-described process.

Meanwhile, as shown in (b) of FIG. 11, the components for performing the ornamental fish education method of the present invention may further include an HMD module 3000 for providing a manual to the user on the metaverse.

Specifically, metaverse refers to a technology that allows users to become more immersed and interested in content by interacting between users and a 3D virtual space created by a computer system to make users feel as if they actually exist in the virtual space.

In one embodiment of the present invention, the manual may be provided in a form that allows the user to directly assemble the ornamental fish education kit (1000) and raise ornamental fish in virtual reality, and the user wears the HMD module (3000) and operates the server system. The above manual can be obtained from (4000).

Specifically, the manual provided in virtual reality includes information on the overall training process, such as how to assemble and use the above-mentioned ornamental fish education kit (1000) and the optimal environmental conditions for the growth of ornamental fish, but the manual can be used directly by the user in virtual reality. It can be provided in a form that allows you to assemble an ornamental fish education kit (1000) and raise ornamental fish.

In this way, in one embodiment of the present invention, by providing a manual to the user on the metaverse, it can have the effect of eliciting understanding and interest in the curriculum compared to the case where the manual is provided in the form of text or video.

Meanwhile, in an embodiment of the present invention, when providing a manual on the metaverse through the HMD module 3000, the server system 4000 can also communicate with the HMD module 3000. Specifically, the manual provided on the metaverse can be implemented as a computing program and stored in the database of the server system 4000, and the computing device connected to the HMD module 3000 can access the web page provided by the server system 4000. Alternatively, a manual may be provided from the server system 4000 through an application, a computing program may be executed, and image information based on the manual may be displayed through the HMD module 3000.

Figure 12 shows the implementation steps of an education method using the modular ornamental fish education kit 1000 according to an embodiment of the present invention.

As shown in Figure 12, the education method using the modular ornamental fish education kit 1000 that can be connected to the metaverse is for the modular ornamental fish education kit 1000 and ornamental fish fry provided to the user or purchased by the user. , A registration step of registering initial information including one or more information among the identification information of the modular ornamental fish education kit (1000), purchase date and time of the ornamental fish fry, population, fish species, and the first fry image taken of the ornamental fish fry. ; From the modular aquarium fish training kit (1000) registered in the registration step, real-time water temperature information on whether the temperature control device provided in the modular aquarium fish training kit (1000) is operating and the current water temperature is received, and the real-time An ornamental fish breeding step of determining whether the water temperature information is maintained within the appropriate water temperature for the species of ornamental fish registered in the registration step; and receiving, from the user, an adult image of an adult aquarium fish in which the aquarium fish fry registered in the registration step has grown, and determining whether the aquarium fish fry grows based on the adult image and determining the first operation of the temperature control device from the user. A compensation provision step of providing compensation based on whether the integrated water temperature information is maintained within the appropriate water temperature for the species of ornamental fish, based on integrated water temperature information accumulated from the real-time water temperature information up to the time of requesting compensation. May include ;.

Steps S1 to S4 of FIG. 1 can be performed using the components of FIG. 11 described above.

Step S1 is a registration step, which may correspond to a step in which the user registers initial information about the curriculum to the server system 4000 and starts the curriculum.

Specifically, users can purchase or receive an ornamental fish education kit (1000) and purchase ornamental fish fry for their own breeding. The user accesses the web page provided by the server system 4000 through the user terminal 2000 or runs the application to obtain the identification information of the ornamental fish education kit 1000, the purchase date and time of the ornamental fish, the number of fish, the species, and the ornamental fish. Initial information including the captured first fry image can be transmitted to the server system 4000.

In this way, step S1 is the initial stage of the curriculum and may be a stage in which basic information about the user who wants to start the curriculum is registered in the server system 4000.

Step S2 is a manual provision step, which may correspond to a step in which the server system 4000 provides the user with a manual containing information necessary to perform the curriculum.

Specifically, the user can access a web page provided by the server system 4000 through the user terminal 2000 or run an application to receive a manual from the server system 4000.

Preferably, the manual includes information on how to assemble and use the ornamental fish education kit (1000) and how to raise ornamental fish, and includes various information such as text, images, videos, and virtual reality programs that can be implemented with virtual reality technology. It can be provided in the form

Step S3 is an ornamental fish breeding step, and may correspond to a step in which the user performs a training course to raise ornamental fish.

Specifically, the user can assemble the ornamental fish education kit (1000) by referring to the manual provided from the server system (4000) and breed the ornamental fish purchased and registered in step S1 above in the tank connected to the ornamental fish education kit (1000). there is. More specifically, the user directly constructs a plurality of prefabricated modules (2) (filtration module (3), microbial purification module (4), temperature control module (5), etc.) that constitute the ornamental fish education kit (1000), and each prefabricated You can explore and learn the roles and functions of module (2).

As described above, the ornamental fish education kit (1000) of the present invention is provided in a form that allows users to easily assemble and disassemble the ornamental fish education kit (1000), so users can easily assemble the ornamental fish education kit (1000) at home, school, and other educational institutions. And you can raise ornamental fish.

In addition, the user feeds the fish at the relevant stage, maintains the environmental conditions of the water, including water temperature, at optimal conditions for the growth of ornamental fish, and replaces parts that have reached the end of their life (filling material, microbial culture material, etc.) can be bred.

Meanwhile, in step S3, the server system 4000 may periodically receive real-time water temperature information from the ornamental fish education kit 1000. Specifically, the communication unit of the temperature control device may periodically transmit real-time water temperature information, which is information about the current water temperature, to the server system 4000. The manager of the server system 4000 can determine whether the user is faithfully participating in the training course by determining whether the water temperature is maintained at an appropriate temperature based on the real-time water temperature information.

In this way, in step S3, while the training process is being performed, the user assembles the ornamental fish education kit (1000), continuously maintains the environmental conditions of the water in an optimal state, and rears ornamental fish fry until adults, and the process is performed using the server system (4000) ) may be a step supervised by.

Step S4 is the reward provision step, which may correspond to the step of performing an evaluation according to the performance of the training course and providing the corresponding reward to the user.

Specifically, the user can raise ornamental fish during the training course, grow the ornamental fish fry to adult ornamental fish, and request compensation from the server system 4000 accordingly. The server system 4000 may provide compensation to a user who has requested compensation by calculating a score based on how diligently the user has performed the curriculum and the results of the curriculum.

Specifically, the server system 4000 calculates a score by comprehensively considering the user's species of ornamental fish, the number of ornamental fish grown from fry to adults, whether an appropriate water temperature is maintained during the training process, and the species of ornamental fish that spawned, and provides compensation accordingly. can be provided.

Preferably, the server system 4000 determines whether the appropriate water temperature is maintained during the training process based on the integrated water temperature information accumulated by the real-time water temperature information received from the ornamental fish training kit 1000, and determines whether the user grows the fish from fry to adults. Based on the adult images taken of adult ornamental fish, the number of ornamental fish and species of ornamental fish can be determined, a score can be calculated, and compensation can be provided accordingly.

Meanwhile, the compensation may be provided in the form of points, coupons, virtual currency, etc. for purchasing feed, sea salt, consumables, and ornamental fish required for breeding.

In this way, step S4 may be a step in which a user who has completed the training course is evaluated by comprehensively considering a plurality of factors and compensation is provided accordingly.

Figure 13 shows a registration step according to an embodiment of the present invention.

As shown in Figure 13, at the registration stage corresponding to the initial stage of the training process, the user provides identification information of the ornamental fish education kit (1000), purchase date and time of ornamental fish, population, fish species, and the first fry image taken of the ornamental fish. Initial information including can be transmitted to the server system 4000.

Identification information is unique information given to distinguish each of the plurality of ornamental fish education kits 1000 produced, and the server system 4000 uses the identification information to identify the ornamental fish registered by the user among the plurality of ornamental fish education kits 1000 produced. Real-time water temperature information can be received from the education kit (1000).

The first fry image is image information taken by the user of the ornamental fish fry that will be raised during the training process. Specifically, the user uses the photography function of the user terminal (2000) to photograph the ornamental fish fry that the user has purchased so that the species and number of fish are visible, and transmits the corresponding image, the first fry image, to the server system (4000). can do.

The manager of the server system 4000 determines whether the fish species and population entered by the user match the fish species and population of the first fry image through the first fry image, or determines the fish species and population in the compensation provision step. It can be used to calculate scores based on .

Meanwhile, in one embodiment of the present invention, the registration step may be implemented as included in the ornamental fish breeding step. Specifically, the user assembles the ornamental fish training kit (1000) in the ornamental fish breeding stage, connects it to the aquarium, releases the ornamental fish fry into the tank, and then sends initial information including the first fry image of the ornamental fish fry to the server. It can be transmitted to system 4000. In this way, the registration step is performed at various points before the user begins breeding ornamental fish in earnest, so that the user can transmit initial information to the server system 4000 and start the training process.

Meanwhile, the server system 4000 may store the initial information received from the user terminal 2000 in an internal database.

Figure 14 shows the manual provision step according to an embodiment of the present invention.

As shown in FIG. 14, the registration step is a manual containing one or more information of the assembly method of the modular ornamental fish education kit (1000), the method of use, and the method of raising the ornamental fish, a web page or an HMD module (3000). It may include a manual provision step provided on Metaverse that can be experienced by wearing.

As shown in (a) of Figure 14, the manual provided in the manual provision step includes a plurality of prefabricated modules (2) (filtration module (3), microbial purification module (4), and temperature control of the ornamental fish education kit (1000). A description of the assembly method for the module (5), skimmer module, etc.) may be included. Specifically, the manual may include information on the overall process of assembling the prefabricated module (2), connecting it to the water tank, and operating the water in the water tank by circulating the plurality of prefabricated modules (2).

Alternatively, the manual may include information on overall breeding methods for ornamental fish. Specifically, the manual may include information on the appropriate temperature, appropriate amount of dissolved oxygen, type of food, feeding cycle, feeding method, etc. that should be set according to the species of ornamental fish.

For example, the manual may include information such as "Guppies are raised on silica or small-grained feed at an appropriate temperature of 22 to 28 degrees and slightly alkaline water quality."

Additionally, the manual may include additional information on diseases and treatment methods for each species of ornamental fish.

Alternatively, the manual contains information on the functions and management methods for the multiple prefabricated modules (2) (filtration module (3), microbial purification module (4), temperature control module (5), skimmer module, etc.) of the ornamental fish education kit (1000). Information may be included.

Specifically, the filtration module (3) corresponds to a device that physically filters impurities in water using a plurality of filtration materials (filter media or filtration materials), and in order for the filtration function by the filtration module (3) to be performed smoothly, filtration is performed at regular intervals. The filtration material inside the module (3) needs to be replaced, and the manual may include information on the replacement cycle of the filtration material.

In addition, the filter material or filtration materials may be various materials such as volcanic stone, elvanite, silica, activated carbon, and diatomaceous earth, and the manual includes information on the characteristics of each material, allowing the user to autonomously use the filtration module (3) with multiple materials. By configuring it, users can learn and explore the filtration function of each material.

Meanwhile, the microbial purification module (4) corresponds to a device that purifies water through a filtration cycle by aerobic microorganisms or denitrification by anaerobic microorganisms, and the manual includes information on the purification process by microorganisms, allowing the user to use aquarium fish. You can learn and explore the process by which ammonia, which is harmful to aquarium fish, is purified through a process in which harmful ammonia is oxidized to less toxic nitrate through a filtration cycle and nitrate is converted to nitrogen through denitrification.

Meanwhile, the temperature control module (5) is a device that measures the current water temperature and adjusts the water temperature to the set temperature by means of a temperature control device. The manual includes information on how to use the temperature control device, allowing the user to use the aquarium fish for each aquarium fish. By maintaining the water temperature at different appropriate temperatures, you can learn and explore the effects of water temperature on ornamental fish.

In this way, the manual may include information about the overall curriculum.

Meanwhile, as shown in (b) of FIG. 14, the user can receive a manual from the server system 4000 through the user terminal 2000 or the HMD module 3000.

Specifically, the user can access a web page provided by the server system 4000 through the user terminal 2000 or run an application to receive a manual provided in the form of text, images, videos, etc.

Alternatively, as shown in (c) of FIG. 14, the user can wear the HMD module 3000, execute a computing program provided by the server system 4000, and receive a manual provided on the metaverse. Specifically, by wearing and operating the HMD module (3000) on which virtual reality images are displayed and a controller that can input information about movements, the user can manipulate an avatar representing himself or herself in the metaverse, and use ornamental words in the metaverse. You can indirectly experience the entire curriculum by assembling the education kit (1000) or visually checking the species, shape, and size of the ornamental fish.

Figure 15 shows the steps of raising ornamental fish according to an embodiment of the present invention.

As shown in (a) of FIG. 15, in the ornamental fish breeding stage, the ornamental fish education kit 1000 may periodically transmit real-time water temperature information, which is information about the current water temperature, to the server system 4000 while performing the training course. As described above, the user can assemble the ornamental fish training kit (1000) according to the manual and raise ornamental fish to perform the training course, and the server system (4000) monitors in real time whether the user is faithfully performing the training course. It can be judged based on water temperature information.

Specifically, while performing the training course, the user must operate the thermostat to continuously maintain the water temperature at the appropriate water temperature, which is the optimal temperature for the growth of ornamental fish, and the server system 4000 checks whether the water temperature is maintained at the appropriate temperature. Depending on this, it can be determined whether the user is faithfully carrying out the training course.

Figure 10 shows two embodiments of the temperature control device of the temperature control module 5, which is an example of maintaining the water temperature at the set temperature input from the user through feedback control or through an interface that can heat or cool the water in stages. An example has been presented that allows the user to directly adjust the water temperature to the set temperature.

In one embodiment of the present invention, in order to determine whether the user is faithfully performing the training course based on real-time water temperature information, the user can directly adjust the water temperature to the set temperature through an interface that can heat or cool the water step by step. It may be desirable to implement a temperature control device in a controlled manner.

Specifically, the set temperature input unit of the thermostat is an interface that can heat or cool water in stages (e.g., heating stages 1, 2, 3, 4, and 5 and cooling stages 1, 2, 3, 4, and 5). Implemented, the user can check the current water temperature measured by the temperature sensor and operate it to maintain the water temperature at the appropriate temperature described in the manual.

In this way, when a temperature control device is implemented in such a way that the user directly adjusts the water temperature to the set temperature through an interface that can heat or cool the water in stages, the user must continuously check the water temperature and adjust the water temperature to an appropriate temperature. It is necessary to manipulate the temperature control device to maintain the temperature, thereby encouraging the user's continued interest in the educational process.

In other words, it may mean that users who maintain the water temperature at an appropriate temperature are carrying out the training course faithfully, while users whose water temperature deviates from the appropriate temperature frequently and for a long period of time are carrying out the training course relatively unfaithfully. It can mean.

As a result, the service server can determine whether the user is faithfully performing the training course using only real-time water temperature information.

Figure 15(b) shows real-time water temperature information transmitted from the ornamental fish education kit 1000 to the server system 4000. As shown, the user can maintain the water temperature within an appropriate temperature range for the growth of ornamental fish by operating a temperature control device that includes an interface that can heat or cool water in stages. In other words, the drawing shown may be real-time water temperature information for users who are relatively faithfully participating in the training course, with the water temperature maintained within an appropriate water temperature range.

Meanwhile, the ornamental fish rearing step may further include an alarm information transmission step of transmitting alarm information to the user when the real-time water temperature information exceeds or is less than the appropriate water temperature.

As described above, the server system 4000 can periodically receive real-time water temperature information from the inertial language training kit while performing the training course, and provides information to users whose water temperature is above or below the appropriate water temperature, that is, users who do not faithfully participate in the training course. Alarm information can be transmitted to notify that the current water temperature is not maintained within the appropriate water temperature range. In this way, alarm information may be transmitted to users who do not faithfully participate in the training course for the purpose of calling the user's attention to the training course.

Figure 16 shows the compensation provision step according to an embodiment of the present invention.

As shown in (a) of FIG. 16, in the compensation provision stage, when the user completes the training course and requests compensation from the server system 4000, the server system 4000 receives an adult ornamental fish from the user terminal 2000. Integrated water temperature information can be generated by receiving captured adult images and accumulating real-time water temperature information received from the ornamental fish education kit (1000).

Specifically, if the training course has been completed for more than a certain period of time and the user has reared the ornamental fish fry purchased and registered in the initial registration stage and grown them to adulthood, the user can upload the adult image taken of the corresponding adult ornamental fish to the server system (4000). You can request completion of the training course and compensation based on the training results.

The service server that has received a request from the user for completion of the training course and compensation according to the training results can generate integrated water temperature information based on real-time water temperature information for the user. Specifically, the integrated water temperature information is information that is integrated by accumulating real-time water temperature information from the time the temperature control device first operates in the aquarium fish rearing stage and real-time water temperature information is transmitted to the server system 4000 to the time the user requests compensation. You can.

In other words, the integrated water temperature information may be information that includes information on whether the user maintained the water temperature in the water tank at an appropriate temperature from the start of the training course to the end.

In other words, the integrated water temperature information may be information that includes information about whether the user faithfully participated in the training course from the start to the end of the training course.

Meanwhile, the adult image and the integrated water temperature information accumulated in real-time water temperature information transmitted by the user terminal 2000 to the server system 4000 in the compensation provision stage allow the administrator of the server system 4000 to evaluate the training course for the user. It may be an indicator for this.

Meanwhile, in one embodiment of the present invention, the user may transmit to the service server a second fry image taken of an adult aquarium fish fry that has spawned an adult aquarium fish. Specifically, the second fry image may be an image taken of the ornamental fish fry purchased and registered by the user in the registration stage when the ornamental fish fry grows to adulthood, reproduces, and spawns ornamental fish fry.

Figure 16 (b) shows a screen displayed on the user terminal 2000 in the compensation provision step. As shown, when the user transmits an adult image to the server system 4000, an enlarged image of the adult ornamental fish and an image of all adult ornamental fish are transmitted to the server system 4000 by photographing the entire aquarium. can do.

As described above, the server system 4000 can evaluate the user's training results based on the species, population, etc. of the ornamental fish raised by the user, and for this purpose, the user zooms in to identify the species of the ornamental fish. The entire aquarium can be photographed and transmitted to the server system 4000 so that the number of ornamental fish can be identified.

The administrator of the server system 4000 can determine the species and number of ornamental fish raised by the user based on the adult image received from the user and provide compensation accordingly.

Figure 17 shows a process for calculating compensation according to an embodiment of the present invention.

As shown in Figure 17, the compensation providing step includes a first score calculation step of calculating a first score calculated according to the species of the ornamental fish raised by the user in the ornamental fish breeding step; A second score calculation step of calculating a second score based on the number of fry of the ornamental fish registered in the registration step and the number of adults of the ornamental fish in the adult image; And a third score calculation step of calculating a third score that is added as the integrated water temperature information corresponds to the median value of the appropriate water temperature and subtracted according to the number and period of times the integrated water temperature information exceeds or falls below the appropriate water temperature. ;, and the compensation may be provided in proportion to the sum of the first score, the second score, and the third score.

Alternatively, the compensation providing step calculates a fourth score that is weighted and calculated according to the species of the ornamental fish fry that the adult ornamental fish spawned on, based on the second image of the fry that the adult ornamental fish spawned. and a fourth score calculation step, wherein the compensation may be provided in proportion to a sum of the first score, the second score, the third score, and the fourth score.

As shown in (a) of Figure 17, the first score is calculated based on the species of ornamental fish, the second score is calculated based on the number of ornamental fish, and the third score is calculated based on the integrated water temperature information. Compensation can be provided to users by adding them up.

The server system 4000 can calculate the first score based on the species of ornamental fish raised by the user. Specifically, ornamental fish species that users can breed include guppies, mollies, gourami, cardinal tetras, kribensis, and discus, and the server system (4000) calculates the first score by considering the difficulty of raising each species of ornamental fish. You can. Preferably, the first score can be calculated higher for users who raised discus, which have a higher breeding difficulty, compared to users who raised guppies or mollies, which have low breeding difficulty.

Meanwhile, the manager of the server system 4000 calculates the first score based on the ornamental fish species raised by the user, including information on the ornamental fish species registered by the user in the registration stage and the first fry image taken of the ornamental fish in the fry state. , and based on the adult image taken of the adult ornamental fish in the compensation provision stage after breeding, the species of ornamental fish bred by the user can be determined and the first score can be calculated accordingly.

Specifically, the manager of the server system 4000 determines whether the ornamental fish species registered by the user, the ornamental fish species of the first fry image, and the ornamental fish species of the adult image are all the same, and determines whether the ornamental fish species registered by the user in the initial registration stage is the same. You can determine whether purchased and registered ornamental fish have been bred and compensation has been requested.

That is, in one embodiment of the present invention, it may be desirable for the manager of the server system 4000 to be an expert with specialized knowledge capable of identifying fry and adult ornamental fish for each fish species.

Additionally, the server system 4000 can calculate the second score based on the number of ornamental fish raised by the user. Specifically, the user can transmit information about the number of ornamental fish purchased and registered in the initial registration stage to the server system (4000), and in the compensation provision stage, the adult image that can identify the number of ornamental fish in the tank is sent to the server system (4000). It can be sent to .

In calculating the second score based on the number of ornamental fish raised by the user, the administrator of the server system 4000 calculates the second score based on the number of ornamental fish registered by the user in the registration stage and the number of ornamental fish captured in the adult image in the compensation provision stage. 2 scores can be calculated.

Specifically, the administrator of the server system 4000 compares the number of ornamental fish registered by the user in the registration stage with the number of ornamental fish captured in the adult image, and adds a second score for the user who maintained the number of ornamental fish without killing them during the training process. It can be calculated highly.

Additionally, the server system 4000 can calculate the third score based on integrated water temperature information for the user. As described above, integrated water temperature information is the accumulation and integration of real-time water temperature information from the time the temperature control device first operates in the aquarium fish rearing stage and transmits real-time water temperature information to the server system 4000 to the time the user requests compensation. As information provided, it can ultimately mean whether or not the user faithfully participated in the training course from the start to the end of the training course.

As the user requests compensation from the server system 4000, the server system 4000 provides compensation based on integrated water temperature information for the user and whether the user maintained the water temperature at an appropriate level during the training course. A third score for the user can be calculated.

Specifically, the server system 4000 calculates a third score in which points are added as the integrated water temperature information approaches the median of the appropriate water temperature for the ornamental fish raised by the user, and points are deducted based on the number and period of deviations from the appropriate water temperature. You can.

As a result, the third score may be a score calculated based on how faithfully the user has performed the training course.

The server system 4000 may provide compensation to the user by adding up the first score, second score, and third score. Users can repurchase items needed for the training course, ornamental fish, etc. through rewards provided by the server system 4000. Specifically, users are provided with rewards for completing the training course, and through this, they can learn about various ornamental fish species by raising other species of ornamental fish that are highly difficult to breed.

As shown in (b) of FIG. 17, the server system 4000 can calculate the fourth score based on the ornamental fish species bred by the user and reflect this in calculating compensation for the user. Specifically, when a user breeds ornamental fish and the ornamental fish spawns during the breeding process, the user can transmit a second fry image, which is an image of the spawned ornamental fish fry, to the server system 4000, and the server system 4000 ) can calculate the fourth score based on the second cheer image received from the user.

Preferably, the manager of the server system 4000 can determine the fish species of the ornamental fish fry captured in the second fry image and calculate the fourth score by assigning a high weight to users who have bred ornamental fish with high breeding difficulty. .

As described above, ornamental fish species that users can breed include guppies, mollies, gourami, cardinal tetras, kribensis, discus, and neotetras, and the manager of the server system 4000 can determine the breeding difficulty for each species of ornamental fish. Based on this, the fourth score can be calculated by assigning weights. Specifically, a higher weight is assigned to neotetras with high breeding difficulty than to guppies with low breeding difficulty, so the fourth score for users who breed neotetras can be calculated to be higher compared to users who breed guppies. there is.

Meanwhile, the second image of the ornamental fish fry captured in the compensation provision stage was taken after the period in which the ornamental fish fry purchased and registered by the user in the registration stage grew to adulthood, so the ornamental fish fry captured in the second image was the first. It may be an image taken not of the ornamental fish fry purchased by the user, but of the ornamental fish fry that grew to adulthood and then reproduced and laid eggs.

In this way, users can receive more compensation when they create higher added value by breeding ornamental fish with high breeding difficulty, feel a sense of accomplishment in the process of obtaining higher rewards through promoting the spawning of ornamental fish, and increase the value of ornamental fish. You can understand and learn more broadly about the life cycle.

Figure 18 shows the process of calculating the third score depending on whether the appropriate water temperature is maintained according to an embodiment of the present invention.

Figure 18 (a) shows integrated water temperature information for a user who is given a high third score by maintaining the appropriate water temperature well during the training course, and Figure 18 (b) shows the integrated water temperature information for a user who maintains the appropriate water temperature well while performing the training course. This shows integrated water temperature information for users who failed to maintain the score and were given a low third score.

Specifically, the user in (a) of Figure 18 maintained the water temperature relatively well at the midpoint of the appropriate water temperature until the time of requesting compensation, which means that the user faithfully participated in the training course by continuously operating the temperature control device during the training process. It can mean. In other words, the user can receive more rewards because he or she faithfully participated in the training course.

Meanwhile, the user in Figure 18 (b) was unable to maintain the water temperature within the appropriate water temperature until the time of requesting compensation, and the water temperature frequently increased beyond the appropriate water temperature or decreased below the appropriate water temperature, which occurred frequently. This may mean that the student did not faithfully participate in the educational process. In other words, the user may receive less compensation because he or she did not faithfully participate in the training course.

Figure 19 shows steps in which feedback information is provided to a user according to an embodiment of the present invention.

As shown in Figure 19, the aquarium fish breeding step receives sensing information measured by a sensor that measures one or more of pH, salinity, nitrate, phosphate, nitrite, and ammonia provided in the modular aquarium fish education kit. , If the sensing information is not suitable for the growth of the ornamental fish, feedback information including alarm information about the situation and ways to improve the situation may be provided to the user through a messenger service using an AI chatbot. You can.

As shown in (a) of Figure 19, the server system 4000 receives sensing information about one or more of pH, salinity, nitrate, phosphate, nitrite, and ammonia from the aquarium fish education kit, and sends the information to the corresponding user's user terminal ( 2000) Feedback information according to the sensing information can be provided.

Specifically, sensing information on pH, salinity, nitrate, phosphate, nitrite, ammonia, etc., along with water temperature, can be a standard for determining whether the environmental conditions of the aquarium are maintained as environmental conditions for the growth of ornamental fish. there is.

In other words, the server system 4000 can determine whether the user is faithfully participating in the training course through sensing information about pH, salinity, nitrate, phosphate, nitrite, ammonia, etc., as well as water temperature.

Additionally, the server system 4000 may provide feedback information to the user terminal 2000 based on the sensing information.

Specifically, the server system 4000 sends the sensing information about one or more of pH, salinity, nitrate, phosphate, nitrite, and ammonia to the user terminal 2000 of the corresponding user when the environmental conditions are unsuitable for the growth of ornamental fish. Alarm information can be transmitted.

In other words, the alarm information transmitted to the user through the above-described alarm information transmission step includes one or more of the sensing information for the current water temperature, pH, salinity, nitrate, phosphate, nitrite, and ammonia, which can support the growth of ornamental fish. It may be transmitted if environmental conditions do not maintain it.

Additionally, the server system 4000 may provide additional feedback information to the user terminal 2000. Specifically, feedback information may include coping measures to improve problem situations.

For example, for users who do not maintain ammonia in environmental conditions that allow ornamental fish to grow, feedback information including information on the cause of ammonia elevation and a replacement method for the microbial purification module 40 that purifies ammonia may be provided. .

Additionally, in one embodiment of the present invention, feedback information can be provided through a messenger service using an AI chatbot. Specifically, the user can ask the AI chatbot a question such as “The ammonia concentration is high” through the user terminal (2000), and the AI chatbot can provide feedback information on improvement methods to improve the ammonia concentration.

Additionally, in one embodiment of the present invention, feedback information may be provided through a video service or business trip service. Specifically, if a user cannot solve a problem through a messenger service through an AI chatbot, he or she can request a video service or business trip service.

As a result, according to one embodiment of the present invention, information on water temperature, pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. is transmitted to the server system 4000, and if the environmental conditions are not suitable, it is sent to the user terminal 2000. Alarm information is transmitted so the user can immediately recognize a problem situation in the water tank.

In addition, users can improve problem situations by receiving feedback information that can improve the situation through messenger services, video services, and business trip services through AI chatbots.

As a result, the aquarium fish education kit according to an embodiment of the present invention allows users to learn independently, and improves imagination, creativity, responsibility, sense of accomplishment, and confidence in the process of creatively constructing an aquarium environment and raising aquarium fish. You can do this, and you can relieve your worries and stress in the process of interacting with aquarium fish.

In addition, animal-assisted psychological healing through interaction with aquarium fish can have effects such as stress reduction, emotional stability, and psychological tension relief.

In this way, the ornamental fish education kit of the present invention is provided and utilized by a variety of people, such as children suffering from hyperactivity disorder, elderly people living alone or in poor health, office workers suffering from stress, and students interested in fish or native fish. It can have some effects.

According to one embodiment of the present invention, the prefabricated module can be easily coupled to the main body module using a magnetic material or an insertion method.

According to one embodiment of the present invention, the upper and lower lids of the prefabricated module and the water pipe through which water circulates can be easily coupled using a screw method.

According to one embodiment of the present invention, users can assemble filtration modules to explore the functions of each filter material and improve creativity by applying and changing various filter materials.

According to one embodiment of the present invention, a user can assemble an anaerobic microbial purification module to explore denitrification by anaerobic microorganisms and learn about the effect of nitrate on fish.

According to one embodiment of the present invention, a user can assemble an aerobic microbial purification module to explore the ammonia-nitric acid conversion effect by aerobic microorganisms and learn about the effect of ammonia on fish.

According to one embodiment of the present invention, a user can assemble a temperature control module to set the optimal water temperature for the growth of ornamental fish and learn the effect of water temperature on the fish.

According to one embodiment of the present invention, based on whether the temperature control device is operating, it can be determined whether the user faithfully raised the ornamental fish during the training course of purchasing the fry and raising them to adults.

According to one embodiment of the present invention, the user calculates a score by comprehensively considering the species of ornamental fish, the number of ornamental fish grown from fry to adults, whether an appropriate water temperature is maintained during the training process, and the species of fry of ornamental fish that are spawned, etc., and compensates accordingly. can be provided.

According to one embodiment of the present invention, by providing rewards to users according to practice activities, the self-directed learning effect can be improved by inducing the user's continued interest in ornamental fish.

According to one embodiment of the present invention, by allowing the user to repurchase feed, sea salt, consumables, and other fish species necessary for breeding through compensation, the user can repeat training courses on various fish species to provide information on natural science and environmental engineering. Learning effectiveness can be improved.

According to one embodiment of the present invention, information about the current water temperature of the temperature control device can be received from the server, and alarm information can be sent to the user when the water temperature is outside the appropriate water temperature.

According to one embodiment of the present invention, the user can improve imagination, creativity, responsibility, sense of accomplishment, and confidence, and reduce negative emotions by self-directed learning in the process of feeding ornamental fish and creating a growth environment.

According to one embodiment of the present invention, stress reduction, emotional stability, and psychological tension can be alleviated through animal-assisted psychological healing in which the user feels intimacy and communicates with aquarium fish.

According to one embodiment of the present invention, pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. are measured by a sensor, and the sensing information measured by the sensor is displayed through a display device, allowing the user to check the status of the breeding water. It can be checked and inspected at any time.

According to one embodiment of the present invention, sensing information on pH, salinity, nitrate, phosphate, nitrite, ammonia, etc. is transmitted to the server system, and feedback on inspection and water exchange of breeding water can be provided.

According to one embodiment of the present invention, feedback can be provided to users through messenger services, business trip services, and video services using AI chatbots.

As described above, although the embodiments have been described with limited examples and drawings, various modifications and variations can be made by those skilled in the art from the above description. For example, the described techniques are performed in a different order than the described method, and/or components of the described system, structure, device, circuit, etc. are combined or combined in a different form than the described method, or other components are used. Alternatively, appropriate results may be achieved even if substituted or substituted by an equivalent. Therefore, other implementations, other embodiments, and equivalents of the claims also fall within the scope of the claims described below.

1000: Modular ornamental fish education kit 2000: User terminal
3000: HMD module 4000: Server system
1: Main body module 10: Module coupling surface
2: prefabricated module 20: modular tube
21: upper module lid 210: inlet
211: outlet 212: bubble penetration hole
22: Lower module lid
3: Filtration module 31: Filtration material
310: First through hole 32: Polynagel sponge for filtration
320: Second through hole
4: Microbial purification module 40: Aerobic microbial purification module
400: Aerobic microbial culture material 41: Anaerobic microbial purification module
410: Anaerobic microbial culture material
5: Temperature control module 50: Peltier element
51: control unit 52: display unit
60: 1st internal water pipe 61: 2nd internal water pipe
62: External water pipe

7: Bubble generator 70: Bubble ejection pipe
8: Water tank 9: Pump

Claims (7)

An educational and psychological healing method using a modular aquarium fish education kit that can be connected to the metaverse, implemented by a server system that communicates with the aquarium fish education kit and a user terminal,
By the server system, regarding the modular ornamental fish education kit and ornamental fish fry provided to the user or purchased by the user, identification information of the modular ornamental fish education kit, purchase date and time of the ornamental fish fry, population, fish species, and the ornamental fish fry A registration step of registering initial information including one or more information among the first fry images taken;
By the server system, real-time water temperature information about the operation of the temperature control device provided in the modular aquarium fish training kit and the current water temperature is received from the modular aquarium fish training kit registered in the registration step, and the real-time An ornamental fish breeding step of determining whether the water temperature information is maintained within the appropriate water temperature for the species of ornamental fish registered in the registration step; and
By the server system, an adult image of an adult aquarium fish registered in the registration step is received from the user, and based on the adult image, whether the aquarium fish fry grows or not and the temperature control device is first used. Based on the integrated water temperature information accumulated from the real-time water temperature information from the time of operation to the time when the user requests compensation, compensation is provided based on whether the integrated water temperature information is maintained within the appropriate water temperature for the species of ornamental fish. Including a compensation provision step of providing,
The compensation provision step is,
A first score calculation step of calculating a first score that is calculated higher as the breeding difficulty of the ornamental fish species bred by the user in the ornamental fish breeding step increases;
A second score calculation step of calculating a second score based on the number of fry of the ornamental fish registered in the registration step and the number of adults of the ornamental fish in the adult image; and
A third score calculation step of calculating a third score that is added as the integrated water temperature information corresponds to the median value of the appropriate water temperature and subtracted according to the number and period of times the integrated water temperature information exceeds or falls below the appropriate water temperature; Including,
The compensation is provided in proportion to the sum of the first score, the second score, and the third score, and is a product that can purchase one or more of the feed, sea salt, consumables, and ornamental fish necessary for raising ornamental fish. , Education and psychological healing methods using modular ornamental fish education kits.
In claim 1,
The modular ornamental fish education kit is,
A plurality of prefabricated modules are provided on one side of the tank where ornamental fish are reared and can control environmental conditions for impurities, dissolved oxygen, and water temperature in the water in which ornamental fish are reared, and have a plurality of module coupling surfaces that can be attached and detached using magnetic materials or insertion methods. Including, a main body module; and
A filtration module fixed to one of the plurality of module coupling surfaces and filtering water in an internal accommodation space using a plurality of filtration materials;
A microbial purification module fixed to one of the plurality of module coupling surfaces and purifying water using an anaerobic microbial culture material or an aerobic microbial culture material in the internal receiving space; and
It includes a prefabricated module that is fixed to one of the plurality of module coupling surfaces and includes a temperature control module that controls the water temperature by a temperature control device in the internal accommodation space,
Education and psychological healing using a modular aquarium fish education kit in which the water inside the aquarium circulates through the filtration module, the microbial purification module, and the temperature control module and is discharged back into the aquarium by a pump provided inside the aquarium. method.
In claim 1,
The registration step is,
Through the server system, a manual containing information on one or more of the assembly method, usage method, and breeding method of the modular ornamental fish education kit can be experienced by wearing a web page or HMD module. Education and psychological healing method using the modular ornamental fish education kit provided above, including the manual provision step.
delete In claim 1,
The compensation provision step is,
A fourth score calculation step of calculating a fourth score that is weighted and calculated according to the fish species of the ornamental fish fry on which the adult ornamental fish spawned, based on the second image of the fry on which the adult ornamental fish spawned. Contains more,
The compensation can be provided in proportion to the sum of the first score, the second score, the third score, and the fourth score. An education and psychological healing method using a modular ornamental fish education kit.
In claim 1,
The ornamental fish rearing stage is,
Receives sensing information measured by a sensor that measures one or more of pH, salinity, nitrate, phosphate, nitrite, and ammonia provided in the modular aquarium fish education kit, and detects that the sensing information is not suitable for the growth of the aquarium fish. case,
An education and psychological healing method using a modular ornamental fish education kit that provides the user with alarm information about the situation and feedback information including improvement methods for the situation through a messenger service using an AI chatbot.
As a computing-system that provides education and psychological healing methods using a modular ornamental fish education kit,
The computing-system stores instructions for performing the following steps,
The steps below are:
Regarding the modular ornamental fish education kit and ornamental fish fry provided to the user or purchased by the user, identification information of the modular ornamental fish education kit, purchase date and time of the ornamental fish fry, population, fish species, and the first fry taken of the ornamental fish fry A registration step of registering initial information including one or more information among images;
From the modular aquarium fish training kit registered in the registration step, real-time water temperature information about the operation of the temperature control device provided in the modular aquarium fish training kit and the current water temperature is received, and the real-time water temperature information is received in the registration step. An ornamental fish breeding step that determines whether or not the registered ornamental fish species are maintained within the appropriate water temperature; and
From the user, an adult image of an adult aquarium fish registered in the registration step is received, and based on the adult image, the user determines whether the aquarium fish fry grows or not and from the time of initial operation of the temperature control device. A compensation provision step of providing compensation based on whether the integrated water temperature information is maintained within an appropriate water temperature for the species of ornamental fish, based on integrated water temperature information accumulated from the real-time water temperature information up to the time of requesting compensation; Including,
The compensation provision step is,
A first score calculation step of calculating a first score that is calculated higher as the breeding difficulty of the ornamental fish species bred by the user in the ornamental fish breeding step increases;
A second score calculation step of calculating a second score based on the number of fry of the ornamental fish registered in the registration step and the number of adults of the ornamental fish in the adult image; and
A third score calculation step of calculating a third score that is added as the integrated water temperature information corresponds to the median value of the appropriate water temperature and subtracted according to the number and period of times the integrated water temperature information exceeds or falls below the appropriate water temperature; Including,
The compensation is provided in proportion to the sum of the first score, the second score, and the third score, and is a product that can purchase one or more of the feed, sea salt, consumables, and ornamental fish necessary for raising ornamental fish. ,Computing-Systems.

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