KR102135455B1 - System having a beehive based on internet of things - Google Patents

Abstract

In the present invention, in a smart beehive management system and method utilizing image sensing technology, in particular, by efficiently monitoring visual information and temperature and humidity inside a beehive equipped with a temperature and humidity sensor and an image sensor, it is possible to easily manage bees inside the beehive. It relates to a smart beehive management system and method using the image sensing technology, characterized in that the configuration,
A remote system that remotely controls the breeding of bees by accessing an internet site for breeding bees; A breeding system for breeding bees in response to a control command of the remote system; And a wired/wireless communication network that provides Internet access between the remote system and the breeding system, wherein the breeding system comprises: a video and audio transmission device for acquiring and transmitting an image and voice indicating a bee state of the breeding site; A feeding and water supply device for feeding food and water to the breeding creature; A control unit for controlling the overall operation of each component according to the control command of the remote system; And a web server that receives the control command of the remote system and transmits it to the control unit, and transmits the video and audio of the video and audio transmission device to the remote system in real time.

Description

Smart beehive management system using image sensing technology{SYSTEM HAVING A BEEHIVE BASED ON INTERNET OF THINGS}

The present invention relates to a smart beehive management system utilizing image sensing technology, and is configured to facilitate management of bees inside a hive by efficiently monitoring visual information and temperature and humidity inside a hive equipped with a temperature and humidity sensor and an image sensor. It relates to a smart beehive management system using the image sensing technology, characterized in that.

In general, honey is obtained by supplying wooden houses, etc., and bees to obtain honey by artificially pursuing humans in order to pursue an economically efficient way of living. Earning income

In more detail, the bee is provided with a plurality of honeycombs in a plate shape detachably in a rectangular shape, which is molded into a housing shape and opened and closed by a lid, and has a doorway for bees to enter and exit at the bottom of the front of the beehive. They are breeding them.

Therefore, as the bees enter and exit through the doorway of the beehive, they find flowers within a suitable radius, collect the wheat in the flower as food, store it in a beehive in the beehive, and artificially collect it to obtain the desired honey.

Honey has been used since ancient times for nutrition, tonicity, soothing, detoxification, fatigue recovery, gastrointestinal disorders, coughing, dry skin, eczema, constipation, nervous breakdown, hangover, etc. It is also good for beauty and health, rich in vitamin B, especially B6. Is contained. In addition, honey is widely used as a mating agent in oriental medicine by relieving the bitter taste of Chinese medicine.

It is common for honey having various effects as described above to be obtained through beekeeping. However, there is a cumbersome aspect of collecting honey through beekeeping because it must be done manually by a worker using a mill. In addition, the worker has a disadvantage in that it is necessary to check from time to time how much honey is filled in the hive in order to determine when to collect honey.

Republic of Korea Utility Model No. 20-0429355 (Registration Date: 20061016) "Honey collection device"

The object of the present invention, devised in view of the above points, is to accurately monitor the temperature and humidity inside the hive equipped with a temperature and humidity sensor and an image sensor to accurately identify the characteristics of the bee according to the temperature and humidity inside the hive and analyze the image of the bee. The present invention is to provide a method of monitoring a bee hive equipped with a temperature and humidity sensor and an image sensor that can increase the amount of honey obtained by optimizing for the breeding of bees.

As a means to achieve the above object,

The present invention is a device for raising bees in a hive of a breeding ground, and simultaneously controlling a breeding bee at a remote location through wired/wireless communication, comprising: a remote system for remotely controlling the breeding of bees by accessing an Internet site for breeding the bees; A breeding system for breeding bees in response to a control command of the remote system; A wired/wireless communication network that provides Internet access between the remote system and the breeding system; Dust measuring means installed on the inside end of the breeding bee hive to measure dust, and to output an alarm signal if it is above a standard; It is electrically connected to the dust measuring means and comprises an alarm signal output unit for outputting an alarm signal to the outside according to the control signal of the dust measuring means; The breeding system includes: a video and audio transmission device for acquiring and transmitting an image and audio indicating a bee state of the breeding site; A feeding and water supply device for supplying food and water to the breeding bees; A control unit for controlling the overall operation of each component according to the control command of the remote system; A web server that receives a control command of the remote system and delivers it to the control unit, and transmits the video and audio of the video and audio transmission device to the remote system in real time; The dust measuring means, the infrared transmitting means (A) for emitting infrared rays, is positioned to face the infrared transmitting means, receives the light emitted from the infrared transmitting means and determines the dust inflow according to the degree of the received amount Infrared receiving means (B) for the purpose, and if the output voltage of the infrared receiving means (B) is less than the set value, the dust measuring control unit (C) for controlling so that the input voltage of the infrared transmitting means (A) increases Including; The infrared transmitting means (A), a plurality of concave lenses are mounted and concave lens group to limit the output of infrared rays; An infrared transmitting element that outputs infrared light near the concave lens group; It is installed on one side of the concave lens group so that the concave lens group flows so that the infrared output is controlled. However, if the ambient temperature is higher than the reference set temperature according to the change in temperature, the concave lens group flows to the left to lower the depression angle than the reference set angle. By controlling the infrared light to pass through the lens, the infrared output is controlled to be high. If the ambient temperature is lower than the reference set temperature, the concave lens group flows to the right to allow infrared light to pass through the lens with a higher depression angle than the reference set angle. A shape memory spring that controls to be lowered; It is located on the right end of the shape memory spring comprises a fixing portion for supporting the movement of the shape memory spring; The infrared transmission means (A), the housing for receiving the shape memory spring and the fixing portion; It is installed on the inside of the housing, but is installed on one side of the shape memory spring, forcibly expands the shape memory spring through heat generation to move the concave lens group to the left, whereby infrared rays pass through the lens having a lower depression angle than the reference setting angle. Heating means to induce the infrared output to be forcibly increased; It is installed on the inside of the housing, but installed on the other side of the shape memory spring, transfers cooling heat, forcibly contracts the shape memory spring to move the concave lens group to the right, and accordingly infrared rays with a lens having a higher depression angle than the reference setting angle. A thermoelectric element that causes the infrared output to be forcedly lowered by passing it through; The heating means is electrically connected to the thermoelectric element, and when there is more dust than the reference set dust, the heating means is operated to control the infrared output to increase, and when there is less dust than the reference set dust, the thermoelectric element is operated to lower the infrared output. It comprises a transmission control unit for controlling the control; The fixing part is temporarily installed in the housing 5 while being pushed in the vertical direction by the elastic spring, which is installed inside the case to provide elastic force in both vertical directions and is provided at the end of the elastic spring. It comprises a sliding ball (4b); The breeding system includes a temperature and humidity sensor and an LED light control unit; The remote system is characterized in that it controls the LED light control unit based on the temperature and humidity of the beehive by the temperature and humidity sensor and a control operation standard according to a change in season.

delete

delete

delete

As described above, the present invention accurately monitors the temperature and humidity inside a beehive equipped with a temperature and humidity sensor and an image sensor, accurately grasps the characteristics of the bee according to the temperature and humidity inside the beehive, analyzes the image of the bee, and optimizes honey for honeybees. There is an effect that can increase the acquisition amount of.

1 is an overall conceptual view of the present invention.
Figure 2 is an exemplary bee ecological risk detection using the present invention.
3 is an exemplary view of smart beehive ecological environment control using the present invention.
Figure 4 is an embodiment of a hardware configuration using the present invention.
5 is a diagram showing an entire system using the present invention.
6 is a block diagram of an embodiment of the present invention.
7 is a block diagram of the dust measuring means and alarm signal output unit of the present invention.
8 is a conceptual diagram of infrared transmitting means and infrared receiving means constituting the dust measuring means of the present invention.
9 is a conceptual diagram for measuring dust using the infrared transmitting means and the infrared receiving means of the present invention.
10 is a first embodiment of the dust measuring means having a shape memory spring in the present invention.
11 is a second embodiment of the present invention having a heating means, a thermoelectric element and a shape memory spring.
12 is an embodiment of the fixing part in the present invention.
13 is a concave lens configuration applied to the present invention.

Hereinafter, an operation principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the descriptions described below are for preferred implementation methods among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

In addition, in the following description of the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition should be made based on the overall contents of the present invention.

In addition, a preferred embodiment of the present invention to be carried out below is already provided in each system functional configuration to effectively describe the technical components constituting the present invention, or a system function commonly provided in the technical field to which the present invention pertains. The configuration is omitted as much as possible, and the functional configuration that should be additionally provided for the present invention will be mainly described.

If a person having ordinary knowledge in the technical field to which the present invention pertains, it will be possible to easily understand the function of a component that has been used in the prior art among the omitted functional configurations not shown below, and also the omitted configuration as described above. The relationship between the elements and the components added for the invention will also be clearly understood.

In addition, the following examples will be used by appropriately modifying the terms so that those of ordinary skill in the art to which the present invention pertains can clearly understand in order to efficiently describe the core technical features of the present invention. It is never limited.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for effectively explaining the technical spirit of the advanced invention to those skilled in the art to which the present invention pertains. It's just.

1 is an overall conceptual view of the present invention.

Figure 2 is an exemplary bee ecological risk detection using the present invention.

3 is an exemplary view of smart beehive ecological environment control using the present invention.

Figure 4 is an embodiment of a hardware configuration using the present invention.

5 is a diagram showing an entire system using the present invention.

6 is a block diagram of an embodiment of the present invention.

7 is a block diagram of the dust measuring means and alarm signal output unit of the present invention.

8 is a conceptual diagram of infrared transmitting means and infrared receiving means constituting the dust measuring means of the present invention.

9 is a conceptual diagram for measuring dust using the infrared transmitting means and the infrared receiving means of the present invention.

10 is a first embodiment of the dust measuring means having a shape memory spring in the present invention.

11 is a second embodiment of the present invention having a heating means and a thermoelectric element and a shape memory spring.

12 is an embodiment of the fixing part in the present invention.

13 is a concave lens configuration diagram applied to the present invention,

The present invention is basically equipped with a variety of sensors in the hive, the sensor comprises a temperature and humidity sensor and an image sensor, receives the signals from the sensors and transmits them to the monitoring device.

Then, the worker or the observer can grasp the state of the bee through the monitoring device and take necessary measures.

The remote breeding system shown in FIG. 6 is installed at a remote site and is composed of a remote system 10 for controlling the breeding of bees, and a breeding system 20 for breeding organisms under the control of the remote system 10. The remote land system 10 and the breeding ground system 20 are connected through a wired/wireless communication network 30. The remote system 10 is implemented with a computer, a mobile communication terminal, a PDA, and the like capable of accessing wired/wireless communication. The breeding system 20 is connected through a wired/wireless communication network 30 through a web server 21 for accessing the remote control device 11 and a wired/wireless communication network 30 for transmitting video and audio photographing the breeding site to a remote site. do.

The remote system 10 according to an embodiment of the present invention includes a remote system 10 such as a computer, a mobile communication terminal, a PDA, and a web server 21, video and audio transmission devices connected via a wired/wireless communication network 30 ( 22), a control unit 23 and a feeding unit.

The remote system 10 is connected to the web server 21 through the wired/wireless communication network 30, and the video and audio transmission device 22 of the breeding ground can check the status of living creatures in real time through the remote web browser. Control commands to transmit video and audio can be transmitted.

The wired/wireless communication network 30 connects the remote system and the breeding system.

The web server 21 can support additional functions such as a mobile phone interface of a video and audio transmission device 22 such as a network camera, PDA support, dynamic IP support, short message transmission service SMS service, e-mail service, and the like. It is a multi-purpose server capable of wired/wireless wired/wireless communication multimedia services. In addition, a network web server function configured to allow multiple network cameras to be connected is possible.

The video and audio transmission device 22 may be a TCP/IP-based wired/wireless network camera, which can be viewed on a remote system 10 as well as a PC, a mobile phone, a PDA, and can control the camera and various home appliances. . With built-in network function, it can be operated alone without the need for additional equipment. It is also capable of home automation equipment, security equipment, and surveillance equipment.

A method and system for providing wired/wireless communication phone service for multimedia communication in a high-speed wireless wired/wireless communication network relates to a wired/wireless communication phone system and method for multimedia communication in a high-speed wireless wired/wireless communication network. Using this, the wireless wired/wireless communication network supports user mobility environment in a point-to-point using a wired/wireless communication phone on a PDA equipped with a CDMA transmission/reception module or wireless LAN card in a tree-wired LAN network, and supports the user mobility environment anytime, anywhere. Regardless of the location, you can talk while looking at the other person's face.

The user registered as a member accesses a breeding animal site on the Internet and the user or member accesses it, and clicks the breeding screen. At this time, the server of the remote system has a procedure of confirming that it is new to the user or member who clicked the screen. At this time, in the case of non-members, the terms of the paid site are presented, the user account and password (ID/PASSWORD) are given, and in the case of members, they log in through a prescribed authentication procedure (step 100).

The web browser of the remote control device 10 transmits a control command to the video and audio transmission device 22. When a member clicks the button to observe the bee on their wired or wireless communication, a video screen window and a breeding window to check and control the bee's status are displayed on the web browser (step 101).

Control of the video and audio transmission device by receiving a video and audio transmission device control command from a remote site via the wired/wireless communication network 30 from the web server 21 of the breeding ground (step 102).

The video and audio transmission device 22 of the breeding ground receives the control command of the remote site transmitted from the web server 21, encodes the video and audio containing the state of the creature of the breeding ground, and transmits it to the web server 21. Step 103)

The encoded video and audio of the breeding ground is received from the web server 21 and streamed and transmitted to the remote system 10 via the wired/wireless communication network 30 in real time. (Step 104)

The remote system 10 decodes the video and audio encoded by the web server 21, which is transmitted through the video and audio transmission device 22 of the breeding field, and the web browser displays the video and audio on the web browser of the remote system 10. , Check on the receiving terminal including mobile phone or PDA. (Step 105)

After the 100th step, the remote system 10 transmits a control command for controlling the food supply device and the water supply device (step 106).

The control command transmitted from the remote system 10 is received by the web server 21 through the wired/wireless communication network 30. (Step 107)

The control unit 23 using the microcomputer controller automatically opens and closes the food supply device and the water supply device 25 according to the control signal through the web server 21. (Step 108)

On the other hand, the present invention further installs a dust measuring means 1000 at one end of the hive, and when it is determined that the measurement result of the dust measuring means 1000 has more dust than a standard, an alarm signal is output through the alarm signal output unit 2000. By outputting, the fine dust inside the hive is greater than the standard value, so that the dust is properly removed or induced to move the hive so that the hive is not contaminated.

The dust measuring means 1000 of the present invention is an infrared transmitting means (A) for emitting infrared rays, and is positioned to face the infrared transmitting means and receives light emitted from the infrared transmitting means, depending on the amount of the received amount. Infrared receiving means (B) for determining dust inflow, and dust measurement control unit for controlling so that the input voltage of the infrared transmitting means (A) increases when the output voltage of the infrared receiving means (B) is less than a set value. (C).

Then, the infrared transmission means (A) receives an infrared transmission control signal from the dust measurement control unit (C) to determine the infrared transmission amount and outputs the changed infrared transmission amount.

That is, when the result value of the infrared receiving means (B) is transmitted to the dust measurement control unit (C), the dust measurement control unit (C) predicts the amount of dust generated based on the data of the infrared receiving means (B), and according to the dust generation amount The control signal is output to the infrared transmission means (A) to control the amount of infrared transmission to induce the output.

That is, the dust measurement control unit reads the light amount data output from the infrared receiving means, and on the basis of this, automatically controls the light amount of the infrared light emitting means so that the sensitivity control is automatically kept constant, so that dust detection is optimal even in the dust-caused condition. This was done by maintaining sensitivity.

In other words, the dust measurement control unit C determines that the degree of contamination is high when the received light quantity of the infrared receiving means B is weak, and outputs a control signal to increase the light quantity of the infrared transmitting means A for more precise dust measurement. And, if the received light amount of the infrared receiving means (C) is too strong, there is no contamination or a precise measurement is difficult, so a control signal is output to lower the light amount of the infrared transmitting means (A). That is, it is necessary to keep the amount of infrared transmission light in an appropriate state. Only then is the amount of infrared light measured by the infrared receiving means accurate, so that the amount of dust generated can be predicted more accurately. Therefore, the dust amount data measured by the dust measurement control unit of the present invention can output a highly reliable dust measurement result.

The present invention is a concave lens group (1) that is equipped with a plurality of concave lenses to limit the output of infrared rays;

An infrared transmitting element (2) for outputting infrared light near the concave lens group;

It is installed on one side of the concave lens group so that the concave lens group flows so that the infrared output is controlled. However, if the ambient temperature is high according to the change in temperature, the concave lens group flows to the left to allow infrared rays to pass through the lens with a lower depression angle A shape memory spring (3) for controlling the output to be high and controlling the infrared output to be lowered by allowing the concave lens group to flow to the right when the ambient temperature is low to pass infrared rays to the lens with a high depression angle;

It comprises a fixing portion (4) located at the right end of the shape memory spring to support the movement of the shape memory spring.

And, a housing (5) for receiving the spring and the fixing portion;

It is installed on the inside of the housing, but is installed on one side of the shape memory spring, forcibly expands the shape memory spring through heat generation to move the concave lens group to the left, thereby allowing infrared rays to pass through the lens with a low depression angle. A heating means (6) for inducing the force to be high;

It is installed on the inside of the housing but is installed on the other side of the shape memory spring 3 to transfer cooling heat to forcibly contract the shape memory spring 3 to move the concave lens group to the right, and accordingly the lens has a high depression angle. And a thermoelectric element (7) to induce infrared rays to pass through to force the infrared light to pass through;

A transmission control unit that is electrically connected to the heating means and the thermoelectric element, controls to increase the infrared output by operating the heating means when there is a lot of dust, and controls to lower the infrared output by operating the thermoelectric element when there is little dust (8) It comprises.

Then, a plurality of holes (5a, 5b 5c) are formed at the rim of the housing where the fixing part (4) is located, and a magnet (9) for setting the position of the fixing part (4) is inserted and coupled to the hole. Is done.

That is, the fixing part 4 is made of metal, and the magnet 9 is inserted into the hole to temporarily fix the fixing part. Accordingly, in a region with low temperature, the magnet is placed in the center hole 5b or the left hole 5a, and in a region with high temperature, the magnet 9 is placed in the center hole 5b or the right side 5c. do.

Then, the position of the first transmitting element 2 is located in the center of the concave lens group 1, and then it is appropriately expanded and contracted according to the temperature change so that the concentration of dust can be accurately determined.

In addition, the fixing part 4 of the present invention can be configured to be coupled by one touch, a ball spring 4a installed inside the case of the fixed part, and a sliding ball 4b installed at the end of the ball spring It is configured to install, and is configured to be coupled while clicking on the housing (5).

That is, a hole is formed at a predetermined interval in the housing 5 in advance, and the sliding ball 5b is temporarily coupled to the hole while moving the fixing part, and at this time, the sliding ball unfolds from side to side by the action of the bullet spring 4a. This is to keep the fixed state.

Accordingly, it is possible to allow the user to freely adjust the position of the fixing part.

The present invention is configured such that the output of the transmitting element 2 is automatically adjusted according to a change in temperature. Since the shape memory spring 3 is set as a basic temperature, when the temperature increases, the shape memory spring increases and the transmitting element increases. The light is reduced and output, and when the temperature decreases, the shape memory spring 3 decreases and the light of the transmitting element 2 is lowered to output.

That is, since the dust is distributed in the gas, the movement becomes active when the temperature rises, so it is possible to check a more precise dust concentration than when the output of the transmitting element 2 is lowered, and when the temperature decreases, the movement becomes dull. More accurate dust concentration can be checked when the output of 2) is increased.

Accordingly, the present invention is to make it possible to more accurately grasp the dust concentration by flowing the concave lens group 1 by reflecting the temperature change.

Looking at the actual operation, first, the light of the transmitting element is output through the third concave lens 1c, which is basically installed at the center of the concave lens group 1.

Then, when the ambient temperature rises, the shape memory spring expands and is located on the right side of the third concave lens 1c, and at the same time, the second concave lens 1b having a depression angle lower than that of the third concave lens 1c comes to the position of the transmitting element. Accordingly, the light output of the transmitting element 2 is lowered and output. In addition, when the ambient temperature decreases, the shape memory spring 3 contracts and is located on the left side of the third concave lens 1c, and at the same time, the fourth concave lens 1d having a depression angle higher than that of the third concave lens 1c is transmitted. It comes to the position of the element (2), thereby increasing the light output of the transmitting element (2) to output.

As described above, according to the present invention, the shape memory spring 3 automatically expands and contracts in response to the ambient temperature, thereby facilitating a change in the amount of light according to the movement of the dust, so that a more precise dust concentration can be grasped, and a more accurate alarm output. This is done.

On the other hand, according to the present invention, the transmission control unit 8 is configured to forcibly determine the most accurate dust concentration by forcibly moving the concave lens group 1 according to the dust concentration. By adjusting, it was possible to grasp the exact concentration of dust.

That is, in the present invention, when the dust measurement control unit C outputs a control signal to facilitate the change in the amount of light in the infrared transmission means, the transmission control unit 8 recognizes this and drives the heating means 6 and the thermoelectric element 7 Therefore, the most appropriate infrared transmission was made.

First, the infrared light is output through the third concave lens 1c, which is basically installed at the center of the concave lens group 1, and when the infrared light needs to be reduced and output, the transmission control unit 8 generates heat (6). ) To generate heat to expand the shape memory spring, and accordingly, the transmitting element 2 is fixed, so that the concave lens group 1 moves, but the second concave is installed on the right side of the third concave lens 1c. As the lens 1b moves to the position of the transmitting element 2, the output light of the transmitting element is output through the second concave lens.

In addition, when the infrared light needs to be further reduced and output, the transmission control unit 8 activates the heating means 6 to generate more heat, so that the shape memory spring 3 expands more, and accordingly the concave lens group 1 ) Is moved but heated so that the first concave lens 1a is moved to the position of the transmitting element 2, and accordingly, the light of the transmitting element 2 is output through the first concave lens 1a.

In addition, when the infrared light needs to be increased and output, the transmission control unit 8 drives the thermoelectric element 7 to generate cooling heat so that the shape memory spring 3 contracts and the concave lens group 1 moves accordingly. 3 The fourth concave lens 1d on which the left side of the concave lens 1c is installed is located on the transmitting element, and accordingly, the light of the transmitting element 2 is output through the fourth concave lens 1d.

In addition, when the infrared light needs to be further increased and output, the transmission control unit 8 drives the thermoelectric element 7 to generate more cooling heat so that the shape memory spring 3 contracts more and concave lens group 1 accordingly. ) Is moved, but the fifth concave lens 1e is moved to the position of the transmitting element 2, so that the light of the transmitting element 2 outputs light through the fifth concave lens 1e.

In addition, the concave lens group is designed to vary the degree of output of infrared light according to the depression angle of the center, and the third concave lens 1c is basically installed at the center of the working rod and forms a depression angle of 25 degrees.

Further, the second concave lens 1b is used when the infrared light needs to be reduced and output, and is installed on the right side of the third concave lens 1c to form a depression angle of 15 degrees.

In addition, the first concave lens 1a is used when more infrared light needs to be output, and is installed on the right side of the second concave lens 1b to form a depression angle of 5 degrees.

Further, the fourth concave lens 1d is used when the infrared light needs to be further increased and output, and is installed on the left side of the third concave lens 1c to form a depression angle of 35 degrees.

Further, the fifth concave lens 1e is used when the infrared light needs to be increased and output more, and is installed on the left side of the fourth concave lens 1d to form a depression angle of 45 degrees.

10: Remote system
11: Remote control device
20: breeding ground system
21: Web server
30: wired and wireless communication network

Claims (4)

A device for raising a bee in a breeding bee hive, and simultaneously controlling the breeding bee at a remote place through wired/wireless communication,
A remote system that remotely controls the breeding of bees by accessing an internet site for breeding the bees;
A breeding system for breeding bees in response to a control command of the remote system;
A wired/wireless communication network that provides Internet access between the remote system and the breeding system;
Dust measuring means installed on the inside end of the breeding bee hive to measure dust, and to output an alarm signal if it is above a standard;
It is electrically connected to the dust measuring means and comprises an alarm signal output unit for outputting an alarm signal to the outside according to the control signal of the dust measuring means;

The breeding system,
An image and audio transmission device for acquiring and transmitting an image and audio indicating a bee state of the breeding ground;
A feeding and water supply device for supplying food and water to the breeding bees;
A control unit for controlling the overall operation of each component according to the control command of the remote system;
A web server that receives a control command of the remote system and transmits it to the control unit, and transmits the video and audio of the video and audio transmission device to the remote system in real time;

The dust measuring means,
Infrared transmitting means (A) for emitting infrared rays, and infrared receiving means for facing the infrared transmitting means and receiving light emitted from the infrared transmitting means to determine dust inflow according to the degree of the received amount (B) and, if the output voltage of the infrared receiving means (B) is less than a set value, the infrared transmission means (A) comprises a dust measuring control unit (C) for controlling to increase the input voltage;
The infrared transmitting means (A),
A concave lens group mounted with a plurality of concave lenses to limit infrared output;
An infrared transmitting element that outputs infrared light near the concave lens group;
It is installed on one side of the concave lens group so that the concave lens group flows so that the infrared output is controlled. However, if the ambient temperature is higher than the reference set temperature according to the change in temperature, the concave lens group flows to the left to lower the depression angle than the reference set angle. By controlling the infrared light to pass through the lens, the infrared output is controlled to be high. If the ambient temperature is lower than the reference set temperature, the concave lens group flows to the right to allow infrared light to pass through the lens with a higher depression angle than the reference set angle. A shape memory spring that controls to be lowered;
It is located on the right end of the shape memory spring comprises a fixing portion for supporting the movement of the shape memory spring;

The infrared transmission means (A), the housing for receiving the shape memory spring and the fixing portion;
It is installed on the inside of the housing, but is installed on one side of the shape memory spring, forcibly expands the shape memory spring through heat generation to move the concave lens group to the left, whereby infrared rays pass through the lens having a lower depression angle than the reference setting angle. Heating means to induce the infrared output to be forcibly increased;
It is installed on the inside of the housing, but installed on the other side of the shape memory spring, transfers cooling heat, forcibly contracts the shape memory spring to move the concave lens group to the right, and accordingly infrared rays with a lens having a higher depression angle than the reference setting angle. A thermoelectric element that causes the infrared output to be forcedly lowered by passing it through;
The heating means is electrically connected to the thermoelectric element, and when there is more dust than the reference set dust, the heating means is operated to control the infrared output to increase, and when there is less dust than the reference set dust, the thermoelectric element is operated to lower the infrared output. It comprises a transmission control unit for controlling the control;

The fixing part,
A ball spring (4a) is installed inside the case to provide the elastic force in both the vertical direction, and the sliding ball is installed at the end of the elastic spring and is temporarily fixed to the housing (5) while being pushed in the vertical direction by the elastic spring ( 4b);

The breeding system includes a temperature and humidity sensor and an LED light control unit;
The remote system is a smart beehive management system using an image sensing technology, characterized in that the LED light control unit is controlled based on the temperature and humidity of the beehive by the temperature and humidity sensor and a control operation standard according to seasonal changes.
delete delete delete

Images