DE202022102081U1 - Mobile application controlled, small and inexpensive device for monitoring Spirulina growth and health - Google Patents

Abstract

A small and inexpensive device (10) controlled by a mobile application for monitoring the growth and health of spirulina, the device (10) comprising:
a sensor unit (1) used to detect the health-related parameters of Spirulina growth, the sensor unit (1) comprising:
a chemical sensor (11) used to record the chemical properties of the medium,
a temperature sensor (12) that detects the temperature of the water, and
a visual sensor (13) used to capture the visual images of spirulina growth;
a communication unit (2) for transmitting processed information to an associated mobile computing unit (21), whereby the user can monitor growth and health parameters using a mobile application; and
a processor (3) used to process information received from the sensor unit (1) using a predefined algorithm to determine health and growth parameters of the spirulina, the processor (3) being used to communicate with the mobile Computing unit (21) to communicate via the mobile application and to send the processed information to the mobile computing device for display and for receiving instructions from the mobile computing unit (21) via the mobile application.

Description

FIELD OF THE INVENTION

The present invention relates to the field of growth and health monitoring of spirulina.

The present invention relates to the field of spirulina growth and health monitoring driven by mobile applications.

In particular, the present invention relates to a mobile, application-controlled, small and inexpensive device for monitoring the growth and health of spirulina.

BACKGROUND OF THE INVENTION

The subject matter discussed in the background section should not be assumed to constitute prior art merely by virtue of its mention in the background section. Likewise, it should not be assumed that any problem mentioned in the background section or associated with the subject matter of the background section has already been recognized in the prior art. The subject matter of the background section merely presents various approaches, which in themselves may also be inventions.

CN206282165 - INTELLIGENT DIGITAL MONITORING BREEDING DEVICE OF SPIRULINA: The utility model refers to intelligent digital monitoring breeding device of Spirulina, run the terminal including the monitoring host, wireless network terminal and control, control is the terminal and is carried out through wireless network Pass terminal connection monitoring host. The utility model discloses an intelligent production digital monitoring breeding device can accurately record and breed pond solution parameters, effectively reducing the amount of nitrogen in spirulina production, potassium, phosphate fertilizer, improve the quality and output of spirulina, effectively reduce spirulina production costs , realized the information-based of the spirulina industry and intelligent level, improve the locality and internal spirulina industrial scientific and technological content and industrial level, promote China's spirulina and has great significance in the international market competitiveness.

CN106010956 - SPIRULINA SEED/SEEDLING MULTISTAGE CULTIVATION DEVICE The invention discloses a spirulina seed/seedling multistage cultivation device comprising a box body and a liquid inlet pipe. The device is characterized in that the liquid inlet pipe is provided with a plurality of liquid inlet branch pipes; the liquid inlet branch pipes are connected to the side surface of the box body and extend into the inside of the box body after penetrating the side wall of the box body; the upper surface of the box body is provided with a vent pipe; both sides of the inner wall of the box body are provided with a plurality of I-shaped slideways; the I-shaped slideways are connected to a plurality of cultivation trays; each liquid inlet branch pipe is positioned above the cultivation tray, respectively; and a sensor is arranged inside the box body. Both sides of the inner wall of the box body are provided with a plurality of lighting lamps, which are placed above the culture trays, respectively. Each liquid inlet branch pipe is provided with a switching valve. The inside of the box body next to the vent pipe is equipped with a fan. The multi-stage spirulina seed/seedling cultivation device is convenient for cultivation and operation, effectively monitors the spirulina growth environment, is convenient for adjusting the spirulina growth environment, and has the advantages of improving spirulina cultivation quality, increasing spirulina income and the like.

CN106010957 - SPIRULINA CULTURE DEVICE: The invention discloses a spirulina culture device which comprises a housing and is characterized in that a plurality of aeration pipes are arranged on the top of the housing, a plurality of liquid replenishing pipes are arranged on the side surface of the housing and a plurality of culture discs are placed on the front surface of the housing; T-shaped grooves are arranged on two sides of each culture disc, and T-shaped slideways corresponding to the T-shaped grooves are arranged on the inner wall of the casing; Sensor chips are arranged on the inner and outer edges of the T-shaped groove on one side, and connection chips corresponding to the sensor chips are arranged on the T-shaped slideways; a touch display is arranged on the side surface of the housing; and a control board is arranged at the bottom inside the case and connected to the touch display and the connection chips. The spirulina culture device has the advantages of being suitable for cultivating spirulina, being suitable for monitoring the growing environment of spirulina, being easy to use and install, providing accurate data and the like.

CN102559487 - TEMPERATURE SELF-ADJUSTING CONTROL DEVICE FOR SPIRULINA CULTIVATION POND: The invention provides a temperature self-adjusting control device for a Spirulina culture pond. The device comprises a PLC (programmable logic controller), a film rolling motor, a temperature sensor and a monitoring computer, and is characterized in that the temperature sensor is arranged in the spirulina culture pond for measuring the liquid temperature, and a temperature signal is supplied to the PLC; the control signal of the film rolling motor is fed to an output point of a PLC module to control the starting and stopping of the film rolling motor; and the monitoring computer is used as a high-level computer of a control system to realize the real-time monitoring and control of the equipment on site. The device can adaptively regulate the lifting of the foil rolling machine according to the fluctuations in water temperature, which helps improve the yield and quality of spirulina.

CN212681868 - FILTER AND IMPURITY REMOVING DEVICE IN SPIRULINA EXTRACTION PRODUCTION: The utility model provides a filter and impurity removal device in spirulina extraction production, which relates to the technical field of spirulina extraction production, and a bottom plate, a vertical bar fixed to the top of the bottom plate, an impurity removal frame fixedly connected to the upper end of the vertical rod, and a motor box fixedly connected to one side of the outer surface of the impurity removal frame. A motor is fixed to one side of the inner surface of the motor box, an agitator blade is fixed to an output shaft of the motor, an agitator is arranged on the outer wall of the agitator blade, a speed measuring device is arranged at the bottom of the inner surface of the impurity removing frame, a box lid is attached to the Arranged at the top of the impurity removal frame, and a pull ring is arranged at the top of the box lid. The problems that when using an existing filter and impurity removal device for spirulina extraction production, the flow rate of cleaning water cannot be monitored to a certain extent, that spirulina is prone to damage due to the fact that the flow rate is too large, meanwhile, the liquid obtained after impurity removal cannot be treated well and long-term use is not facilitated are solved.

CN106027662 - SPIRULINA CULTURE, PURIFICATION AND FILTERING SYSTEM: The invention relates to a system for the cultivation, purification and filtration of spirulina. The system includes a main control host and a server. The main control host is connected to the server. The server is connected to a cultivation monitor, a purification monitor, a finished product monitor, a sample control device, a communication device, and a transmission device. The communication device is connected to a remote control terminal for information communication. The transmission device is connected to a transmission terminal. The cultivation monitoring device is connected to a cultivation box, a temperature and humidity sensor, and a cultivation liquid mixing device. The device for monitoring the purification is connected to a device for filtering sediments and a device for removing heavy metals. The finished product monitoring device is connected to the sediment filter device and the heavy metal removing device. The system has the advantages that the spirulina cultivation process can be conveniently monitored; the content and heavy metal content in the spirulina product can be ascertained conveniently; the workers on site can be conveniently controlled via the transmitter; and the data regulation of the associated devices can be conveniently remotely controlled via a remote control terminal.

CN106010952 - SPIRULINA SOLUTION PORTABLE DETECTION DEVICE: The invention discloses a portable detection device for spirulina solution, comprising a housing. The invention is characterized in that the top of the case is provided with a top cover; the bottom of the housing is provided with an internally threaded port; the top of the case is provided with a battery clip; a printed circuit board is arranged under the battery terminal; a contact connector is arranged under the circuit board; the bottom of the contact connector corresponds to the female thread terminal hole; a battery is installed inside the battery clamp; the circuit board is connected to the battery terminal and the contact connector, respectively; the bottom of the contact connector is connected to a test probe; and the top of the outer wall of the test probe is externally threaded to correspond to the internally threaded port. The portable spirulina solution detection device is convenient to carry and use, can be used for convenient real-time monitoring of spirulina growth environment data, has the Long life advantages and the like, and is convenient for replacement of the test probe.

CN209741160 - SPIRULINA CULTURE POND: The utility model discloses a spirulina culture pond. The device consists of a left reflux chute, a middle connection chute and a right water injection and drainage chute, which are made of glass fiber reinforced plastic, the left reflux chute, the middle connection chute and the right water injection and drainage chute each comprising a side wall and a bottom plate, wherein a drain hole formed in at least one of the sidewalls and the bottom panel, a baffle disposed on the bottom panel, and the apparatus further comprising a filter plug disposed on the drain hole. The spirulina culture pond disclosed by the utility model can meet various requirements of harvesting and draining excess culture solution. In some embodiments, the device also has the function of automatically draining excess culture solution, and manual monitoring and manual operation are no longer required. In some embodiments, the auto-drain device also has an alarm reminder function during auto-drain.

IN201841046909 - BIOME ORGANIC AIR PURIFIER-USING ARTHROSPIRA PLATENSIS FOR AIR PURIFICATION: Air pollution increases the amount of CO2 in the atmosphere, which as a greenhouse gas, internally increases the greenhouse effect. CO2 emissions, their consequences, global warming, etc. are a worldwide phenomenon. The same affects indoor air quality. An air purifier only removes dust and fine dust. Hence the project of prototyping a compact photobioreactor using spirulina. In this project we intend to switch the function of a photobioreactor from biomass production to C02 absorption. This can be achieved by controlling the nutrient addition, aeration and photoperiod of the same. The marketability of the product can be increased by giving it an aesthetic look, making it a display or decorative item. Another benefit is the biomass (edible spirulina algae) that is a by-product of this process and has high nutritional value that can be used as a dietary supplement. Algae photobioreactors are one of the most promising and environmentally friendly technologies for the efficient capture of carbon dioxide in air purification. Spirulina Open and closed cultivation already exists and is mainly aimed at the production of biomass as a food supplement. Bioreactor technology is also currently used for cultivation of biomass indoors or in R&D laboratories to optimize various culture conditions and parameters. We combine these two technologies and change their function towards air purification by harnessing their CO2 sequestration property. Using spirulina culture and bioreactor technology for air purification is the patentability we are striving for. Studies show that Spirulina has 39% to 46% higher carbon dioxide sequestration efficiency than other chemically-assisted technologies. The construction consists of a glass tube containing spirulina in its growing medium. An air pump is used to suck in the air. An air diffuser is installed inside the tube, which supplies the air needed for algae growth. The device is equipped with a biomass monitor, temperature control and pH control for effective maintenance. A real-time C02 monitor helps us to evaluate the efficiency of the device.

CN113564031 - SPIRULINA CULTURE DEVICE FOR EFFICIENT USE OF CARBON DIOXIDE: The invention discloses a spirulina culture device capable of efficiently using carbon dioxide. The spirulina culture device includes a culture box, an electric drive structure and a connector, wherein a connection plate is fixed to one end of the incubator, a rotary hole is formed in the side surface of the connection plate, a rotary shaft is fixed to the side surface of one end of the cover plate and the rotating shaft is rotatably connected to the rotating hole; The upper ends and the lower ends of the hydraulic rods are rotatably connected to the side surface of the cover plate and the side surface of the incubator by respective round rods, an illumination lamp is arranged on the inner side surface of the cover plate, a gas concentration sensor is arranged on a side of the illumination lamp, and the illumination lamp and the gas concentration sensor are fixed to the cover plate. A temperature sensor can detect the temperature of a water body, the gas concentration sensor can detect the concentration of carbon dioxide, the illumination lamp can simulate lighting, a heater can heat the water body in the incubator, a PH sensor can monitor the PH value of the water body, and functionality of the device is improved.

Groupings of alternative elements or embodiments of the invention disclosed herein are not intended to be limiting. Each group member may be referenced and claimed individually or in any combination with other members of the group or other elements contained herein. One or more members of a group may be included in or removed from a group for reasons of convenience and/or patentability. Where such inclusion or deletion occurs, the specification is deemed to contain the group as amended, thereby satisfying the written description of all Markus groups used in the appended claims.

As used in the present specification and the following claims, the meaning of "a", "an" and "the" includes the plural unless the context clearly dictates otherwise. As used in the present specification, the meaning of "in" also includes "in" and "am" unless the context clearly dictates otherwise.

The enumeration of value ranges serves only as a short name for each individual value that falls within the range. Unless otherwise noted here, each individual value is included in the specification as if it were individually listed here. All of the methods described herein can be performed in any suitable order, unless otherwise indicated herein or the context clearly dictates otherwise.

The use of examples or exemplary language (e.g., "such as") with respect to particular embodiments is intended solely to better illustrate the invention and should not be construed as limiting the scope of the otherwise claimed invention. No language in the specification is intended as an indication of a unclaimed element essential to the practice of the invention.

The information disclosed in this Background section is only for enhancement of understanding of the background of the invention and therefore it may contain information that does not form the prior art and that is already known in this country to a person skilled in the art.

SUMMARY

Before describing the present systems and methods, it should be noted that this application is not limited to the systems and methods described, as there may be several possible embodiments that are not expressly illustrated in the present disclosure. It is also to be understood that the terminology used in the specification is for the purpose of describing particular versions or embodiments only and is not intended to limit the scope of the present application.

The present invention mainly heals and solves the technical problems existing in the prior art. In response to these problems, the present invention discloses a monitoring device for a mobile application.

One aspect of the present invention is to provide a small and inexpensive device for monitoring spirulina growth and health controlled by a mobile application, the device comprising: a sensor unit used to measure health-related parameters of spirulina growth to detect, wherein the sensor unit comprises: a chemical sensor used to detect the chemical properties of the medium, a temperature sensor used to detect a temperature of the water, and a visual sensor used to capture the visual images of Spirulina growth; a communication unit used to transmit processed information to an associated mobile computing unit, wherein the user can monitor growth and health parameters using a mobile application; and a processor used to process the information received from the sensor unit using a predefined algorithm to determine the health and growth parameters of the spirulina, the processor being used to communicate with the mobile computing unit via the mobile application communicate and send the processed information to the mobile computing device for viewing and receiving instructions from the mobile computing device via the mobile application.

SHORT DESCRIPTION OF THE FIGURE

In order to clarify various aspects of an embodiment of the present invention, a more detailed description of the invention will be given by reference to a specific embodiment illustrated in the attached figure. It is understood that this figure represents only one illustrated embodiment of the invention and therefore should not be considered as limiting the scope of the invention. The invention will be described and illustrated with additional specificity and detail through the use of the accompanying figure.

• 1 ein Blockdiagramm eines kleinen und kostengünstigen Geräts zur Überwachung des Wachstums und der Gesundheit von Spirulina zeigt, dass über eine mobile Anwendung gesteuert wird (10).

In order that the advantages of the present invention may be readily understood, the following a detailed description of the invention will be discussed in connection with the attached figure, which should not, however, be construed as limiting the scope of the invention to the attached figure, wherein:

• 1 a block diagram of a small and inexpensive device for monitoring spirulina growth and health is shown controlled via a mobile application (10).

DETAILED DESCRIPTION

The present invention relates to a mobile, application-controlled, small and inexpensive device for monitoring the growth and health of spirulina.

1 shows a detailed block diagram of a mobile application controlled, small and inexpensive device for monitoring spirulina growth and health (10).

Although the present disclosure was made with the aim of describing a mobile, application-controlled, small and inexpensive device for monitoring the growth and health of spirulina, it should be appreciated that the same was only done to illustrate the invention in an exemplary manner to illustrate and any other purpose or function for which the explained structures or configurations could be used and is within the scope of the present disclosure.

In this disclosure, a small, inexpensive device (10) for monitoring spirulina growth and health, controlled by a mobile application, is presented.

Controlled by a mobile application, the small and inexpensive device (10) for monitoring spirulina growth and health comprises a sensor unit (1), a communication unit (2) and a processor (3).

The sensor unit (1) is used to record the health-related parameters of Spirulina growth.

The sensor unit (1) comprises a chemical sensor (11), a temperature sensor (12) and an optical sensor (13).

The chemical sensor (11) is used to record the chemical properties of the medium.

The temperature sensor (12) is used to detect the water temperature.

The visual sensor (13) is used to capture the visual images of Spirulina growth.

The communication unit (2) is used to transmit processed information to an associated mobile computing unit (21).

The user can monitor the growth and health parameters through a mobile application.

The processor (3) processes the information received from the sensor unit (1) using a predefined algorithm to determine the health and growth parameters of the spirulina.

The processor (3) is used to communicate with the mobile computing device (21) via the mobile application and sends the processed information to the mobile computing device for display and receives instructions from the mobile computing device (21) via the mobile application.

The processor (3) is a microcontroller.

The communication unit (2) is connected to the mobile computing unit (21) via wireless communication.

The processor (3) is an image processing module that processes the information received from the visual sensor (13).

The processor (3) compares the physical parameters of growth and color with a pre-stored database.

The figure and the preceding description show examples of embodiments. Those skilled in the art will understand that one or more of the elements described may well be combined into a single functional element. Alternatively, certain elements can be broken down into multiple functional elements. Elements from one embodiment may be added to another embodiment. For example, the order of the processes described herein may be changed and is not limited to the manner described herein. In addition, the actions of a block diagram do not need to be performed in the order shown, and not all actions need to be performed. Also, those actions that are not dependent on other actions can be performed in parallel with the other actions. The scope of the execution form men is by no means limited by these specific examples.

Although embodiments of the invention have been described in language specific to structural features and/or methods, the appended claims are not necessarily limited to the specific features or methods described. Rather, the specific features and methods are disclosed as examples of embodiments of the invention.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• CN206282165 [0005]
• CN106010956 [0006]
• CN106010957 [0007]
• CN102559487 [0008]
• CN 212681868 [0009]
• CN106027662 [0010]
• CN106010952 [0011]
• CN209741160 [0012]
• IN 201841046909 [0013]
• CN 113564031 [0014]

Claims (5)

A small and inexpensive device (10) controlled by a mobile application for monitoring the growth and health of spirulina, the device (10) comprising: a sensor unit (1) used to detect the health-related parameters of Spirulina growth, the sensor unit (1) comprising: a chemical sensor (11) used to record the chemical properties of the medium, a temperature sensor (12) that detects the temperature of the water, and a visual sensor (13) used to capture the visual images of spirulina growth; a communication unit (2) for transmitting processed information to an associated mobile computing unit (21), whereby the user can monitor growth and health parameters using a mobile application; and a processor (3) used to process information received from the sensor unit (1) using a predefined algorithm to determine health and growth parameters of the spirulina, the processor (3) being used to communicate with the mobile Computing unit (21) to communicate via the mobile application and to send the processed information to the mobile computing device for display and for receiving instructions from the mobile computing unit (21) via the mobile application. Small and inexpensive device (10) for monitoring Spirulina growth and health controlled by a mobile application claim 1 , wherein the processor (3) is a microcontroller. Small and inexpensive device (10) for monitoring Spirulina growth and health controlled by a mobile application claim 1 , wherein the communication unit (2) is connected to the mobile computing unit (21) by wireless communication. Small and inexpensive device (10) for monitoring Spirulina growth and health controlled by a mobile application claim 1 wherein the processor (3) uses an image processing module to process the information received from the visual sensor (13). Small and inexpensive device (10) for monitoring Spirulina growth and health controlled by a mobile application claim 1 , wherein the processor (3) compares the physical parameters of growth and color through a pre-stored database.

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