KR101958743B1 - Massive bug breeding system - Google Patents

Abstract

Disclosed is an insect breeding system for remotely controlling the temperature and humidity from the outside including an insect breeding apparatus, a control server, and a terminal having an effective temperature and humidity control apparatus. According to the present invention, the insect breeding apparatus is a mass insect breeding system including one or more insect breeding apparatuses, a main server, and a manager terminal. Each of the one or more insect breeding apparatuses includes an insect breeding space and a breeding apparatus control unit. The main server includes: a server communication module; a breeding apparatus setting DB in which the temperature and humidity range of each of one or more insect breeding apparatuses is stored to be able to be individually renewed; an insect setting DB in which the temperature and humidity range for breeding of each insect is stored to be able to be individually renewed; and a manager control unit. The manager terminal includes a login unit and a control interface unit.

Description

{MASSIVE BUG BREEDING SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insect rearing system, and more particularly to an insect rearing system including an insect rearing apparatus having an effective temperature and humidity control apparatus, a control server and a terminal, ≪ / RTI >

Insect breeding has been common so far for some people to breed pet insects as a hobby. However, in recent years, it has been recognized that insects can become important medicinal and food materials in themselves, and that they can become a subject to produce various chemical substances.

However, despite the increase in the value of insect resources as described above, devices and methods for breeding insects in large quantities have not been developed yet, and in reality, even taking out larvae is becoming a very difficult task.

The most important thing in massive breeding system of insects is temperature and humidity. In case of bad ventilation, oxygen is decreased, carbon dioxide and ammonia gas concentration are increased, dust and humidity are increased, feed intake is decreased and respiratory diseases are frequent , Which is a major factor in decreasing the growth rate and egg production rate and increasing the mortality rate.

Most of the ventilation and temperature control systems used in domestic insect farming houses are independent control systems. In reality, many farmers can not buy and operate high-priced imported integrated system except for some corporate farms. There is a limit, and there is a tendency to purchase and use an individual company's controller separately depending on circumstances, and there is a problem that efficient farm management can not be performed due to the individual operation and function control of different ventilation fans and temperature control systems.

Small control system in Korea mainly uses shielded data cable or inside data cable which is vulnerable to lightning, so if system is stopped due to lightning (induction), when there is a system error due to power outage, Only measures are being taken.

If the ventilation fan is operated by inverter or phase control, the efficiency is lowered, the ventilation amount can not be operated at the maximum air volume of the ventilation fan, the operation time of the ventilation fan (air circulation amount) can not be confirmed, Change in temperature, change in temperature, change in temperature, change in temperature during the night, and change in temperature during the night.

In addition, the control of the controller of the hot air in winter and the controller of the ventilation fan are controlled differently so that a large amount of fuel is consumed due to the temperature deviation, and the burden on the heating cost is increased.

The insect mass system for solving the problem of mass rearing of such insects is mainly developed at the enterprise or university level. Prior Art Prior Art Patent No. 10-1677274 discloses a temperature and ventilation control system and control method of an insect hatchery. The above-mentioned patent discloses an insect hatchery temperature control system and a control method for efficiently controlling and managing insects such as a single type ventilation fan control system, a hot air fan control system, and the like in a variety of factors such as area, season, breeding ground size, ventilation fan, To a ventilation control system and a control method thereof.

The above-mentioned patent provides a central control type device in cooperation with the ventilation fan control device and the hot air fan control device, and can be partially similar to the present invention. However, the way in which the central control device controls each of the other devices is already popular Since the ventilation fan control device or the hot air fan control device operates in a completely different manner from the present invention, the patent is judged to be a completely different invention from the present invention.

Other Patent No. 10-1499059 discloses an insect breeding device, an insect breeding method using the same, and an insect mass feeding system. The insect breeding device includes a main heating unit and an auxiliary heating unit for controlling the temperature of water to be supplied. Unit and so on. The above-mentioned registered patent including such configurations is considered to be an invention completely different from the present invention in its configuration and operation manner of the respective configurations.

Another patent 10-0524413 relates to a device for feeding adult flies, a system for mass rearing of parasites including the same, and is characterized in that it includes a flies that can raise flies and breed adult flies, The present invention relates to a method for controlling flies using the parasitic nemesis capable of efficiently treating organic wastes such as livestock wastes and the like, including a separation chamber, and also capable of breeding the domestic parasitic nemesis in a simple manner. Such a registered patent also includes a food feeder, a water feeder, a filler, and the like, and it is judged that the present invention is a completely different invention from its configuration and operation.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide an insect massaging system capable of effectively controlling the temperature and humidity in a nursery and providing an insect capable of controlling a large number of insect- The purpose of this system is to provide a massive breeding system.

In order to achieve the above object, the present invention provides an insect mass feeding system comprising: at least one insect incubator; Main server; And an administrator terminal, wherein said at least one insect breeder is an insect breeding ground; And a maker control unit, wherein the main server comprises: a server communication module; A breeding season setting DB in which temperature and humidity ranges of each of the at least one insect breeding machine are individually and updatably stored; And an insect setting DB in which temperature and humidity ranges for each insect are individually and renewably stored; And an administrator control unit, wherein the manager terminal comprises: a login unit; And an insect mass feeding system including a control interface.

The insect custody unit may include a temperature / humidity sensor unit; And a temperature and humidity control device.

The control unit may include a temperature / humidity controller; An automatic / manual switching section; Nursery display; And a incubator communication module.

The temperature and humidity control device may include one or more temperature and humidity controllers capable of changing an internal air temperature. And at least one air circulation unit capable of circulating the air whose temperature has changed through the temperature and humidity controller.

The air circulation unit may include an air circulation passage that is a passage through which the temperature-changed air can be transferred by the temperature / humidity controller. At least one outlet formed in a side surface of the air circulation passage for allowing air that has flowed inside the air circulation passage to be ejected into the inside of the insect cow; And at least one air shielding film provided on an inner surface of the air circulation passage.

It is preferable that the above-mentioned air circulation passage is installed on the outer partition wall of the insect custody, and is formed in a 'C' shape surrounding the left, right and rear sides except the door of the insect custody place.

Preferably, the discharge ports are formed at predetermined intervals, and the air shielding film is disposed in front of each of the discharge ports and fixedly installed.

The air circulation passage is formed in a triangular prism shape having an inner space, and the outlet has a pair of upper outlet and lower outlet, each of which is provided on the upper surface and the lower surface of the air circulation passage formed in the form of the triangular column, .

The temperature and humidity controller may include a thermoelectric element to change an internal air temperature; An inlet heat sink attached to one side of the thermoelectric element; An inlet fan mounted on the inlet heat sink and capable of changing a flow of air; An auxiliary heat sink attached to the other side of the thermoelectric element; And an auxiliary fan mounted on the auxiliary heat sink and capable of changing a flow of air.

Preferably, the inlet heat sink is formed larger than the auxiliary heat sink, and the inlet fan has a larger ventilation capacity than the auxiliary fan.

In the above, it is preferable to fill the heat insulating material between the protruded portion of the draw-in fan and the inner partition wall of the temperature / humidity regulator.

According to the present invention, various insects can be mass-cultivated in a large variety, and administrators can conveniently classify them and control the breeding environment.

1 is a structural view of an insect massaging system of the present invention.
FIG. 2 is a flow chart of the operation of the insect massaging system of the present invention. FIG.
Fig. 3 is a cross-sectional structural view of the insect breeding machine of the present invention. Fig.
4 is a structural view of the temperature and humidity controller of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be described in more detail with reference to the accompanying drawings. The following description is intended to assist in the understanding and understanding of the present invention, but is not to be construed as limiting the invention thereto. Those skilled in the art will appreciate that various modifications and changes may be made within the spirit of the invention as set forth in the following claims.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a structural diagram showing the connection and operation relationship of each component in the insect mass feeding system of the present invention. FIG. Hereinafter, the configuration and operation of the insect massaging system of the present invention will be described with reference to FIG.

Prior to the description, the dotted lines in FIG. 1 indicate that the components are communicably connected to each other wirelessly or in a wired manner so that they can transmit and receive data or signals with each other.

As shown in FIG. 1, the insect massaging system of the present invention includes at least one insect incubator 10, a main server 20, and an administrator terminal 30.

Specifically, the insect-growing machine 10 includes at least one apparatus and a space for insect breeding. Hereinafter, the constituent elements included in one insect incubator 10 will be described as an example.

The insect incubator 10 includes an insect custodian 11 that is a custodian that actually feeds insects and a nursery control unit 12 that controls temperature and humidity in the insect custodian 11.

The insect custodial cabin 11 includes a temperature and humidity sensor 110 including at least one sensor capable of sensing the temperature and humidity inside the custodial room as a custodian for breeding insects, And a temperature and humidity control device 111 for controlling the temperature and humidity inside the cage space of the cage 11.

The incubator control unit 12 includes a temperature and humidity control unit 120 for controlling the temperature and humidity control unit 111 to control the temperature and humidity of the insides of the insect's nursery 11, An automatic / manual switching unit 121 for determining whether to automatically adjust the temperature and humidity inside the incubator 11, an output unit for allowing an administrator to visually check the temperature and humidity inside the insect custody elevator 11, And a set of input devices for controlling the temperature and humidity of the inside of the insect custodial cabin 11 by the administrator manually set by the automatic / manual switching unit 121, and And a raising machine communication module 123 for allowing the insect carters 10 and the main server 20 to be connected to each other by wire or wireless communication.

The main server 20 is connected to the terminals 30 of the communication modules and the administrators of the insect breeders 10 in a wired or wireless manner so that they can transmit and receive data with each other , A server communication module (21) for controlling the insect breeding machine (10), a server communication module (21) for insect breeding machines (10) An insect setting DB 23 which is a database for individually storing temperature and humidity information suitable for breeding, and databases 22 and 23 in the main server 20, And an administrator control unit 24 including login information, human information, and authority information of at least one administrator.

The administrator terminal 30 includes a login unit 31 for allowing the administrator of the administrator terminal 30 to obtain his / her control authority by allowing him / her to input his or her ID, identification number, password, etc. so as to access the main server 20 An output unit for visually checking the status of the main server 20, and a control interface 32 including an input unit for controlling and operating the output unit.

Preferably, the administrator terminal 30 uses a smart phone, a tablet PC, a notebook, or the like, which is generally and generally portable, and the login unit 31 and the control interface 32 communicate with the administrator terminal 30 or a web page provided by the main server 20 so that the manager terminal 30 and the main server 20 can be wirelessly communicatively connected to each other. .

2 is an operational flowchart of the insect mass feeding system of the present invention. Hereinafter, the overall operation of the insect massaging system of the present invention will be described with reference to FIGS. 1 and 2. FIG.

First, the insect mass rearing system of the present invention is based on the automatic mode operation through the automatic mode operation step (S1). In the automatic mode operating step S1, the insect-making machine 10 automatically performs temperature and humidity control based on its own set value stored in the maker setting DB 22 in the main server 20 .

Here, the maker setting DB 22 may modify its own set value by referring to the insect setting DB 23 for controlling the insect carer 10. For example, when the type of insects desired to be breed is changed in the insect breeder 10, the manager can notify the breeding period setting DB 22 of the breeding breeder through the terminal 30 of his own, The incubator setting DB 22 stores the temperature and humidity range suitable for the insect by referring to the insect setting DB 23 and adjusts the internal temperature and humidity of the insect incubator 10 accordingly.

At this time, the administrator does not directly control the insect incubator 10 but connects to the main server 20 via his or her own terminal 30 and corrects the values of the insect setting DB 23 or the breeder setting DB 22 So that the insect incubator 10 can be controlled only indirectly.

During the automatic mode operation step S1 as described above, the automatic / manual switching unit 121 in the saver control unit 12 determines whether the operation state of the insect creature feeder 10 is automatic or the feeder is in real time Check. If there is no additional input, the automatic mode operation step S1 is continued.

If the manager manually issues a command to the automatic / manual switching unit 121 through the display unit 122 or the administrator terminal 30 to manually change the mode of the insect-maker 10 that was automatically operated , The automatic / manual switching unit 121 switches the mode manually and performs a manual mode switching step S2 for receiving the set value.

At this time, in the passive mode switching step S2, the administrator can directly input a set value such as a temperature and a humidity range to the insect-maker 10 through the maker display 122 or his own terminal 30. [

The automatic / manual switching unit 121 receives the set value from the manager in accordance with the step S2. The automatic / manual switching unit 121 sets the temperature and humidity in the insect custodian 11 of the insect- A manual mode operation step S3 is performed. Also, while performing the step (S3), the automatic / manual switching unit 121 continuously checks the mode change.

If there is no additional input in step S3, the step S3 is continuously executed to operate the insect creature 10, and if the manager again automatically changes the mode from manual to automatic, Manual switching unit 121 is connected to the main server 20 and inputs a mode change signal through its own terminal 30 to the corresponding insect incubator setting unit 22 (S4) for requesting temperature and humidity range set values input to the DB and updating the temperature and humidity set values of the insect incubator (10) stored in the database And the automatic mode operation step S1 for automatically operating the temperature and humidity of the insect custodial 11 according to the set value.

FIG. 3 is a cross-sectional view of the insect-growing machine 10 of the present invention, and FIG. 4 is a structural diagram of a temperature / humidity controller 1110, which is one of the components of the temperature / Hereinafter, referring to FIG. 2, specific components and operations of the ventilation system for controlling the temperature and humidity in the insect-making machine 10 according to the present invention and a method for controlling the internal temperature and humidity of the insect- .

Prior to the explanation, the dotted arrows in FIG. 3 and FIG. 4 indicate abnormal temperature air (E-A) higher or lower than the temperature required in the insect creature 10, and arrows indicate the flow. The solid line arrows denote the normal temperature air OA in which the abnormal temperature air EA is cooled or heated by the temperature and humidity controller 1110 and changed to a temperature suitable for the internal operation of the insect creator 10, Which means the flow direction.

3, the air circulation unit 1120 is installed in the insect custody 11. The air circulation unit 1120 is installed in the insect custody 11, An air circulation passage 1121 connected to the regulator 1110 and serving as a passage for transferring the normal temperature air OA changed by the temperature and humidity controller 1110, One or more outlets 1123 for allowing the normal temperature air OA flowing in the air circulation passage 1121 to be ejected into the insect incubator 10 again, And at least one air shielding membrane 1122 installed to assist in the discharge of the normal temperature air OA to the outlet 1123 by a certain degree of disturbance of the flow of the normal temperature air OA.

The air circulation passage 1121 is installed on the outer partition wall C of the insect incubator 10 and is installed on the left, right and rear sides of the insect custodial housing 11 except for the door D, So that it is installed in a 'C' shape. This is so that the normal temperature air (O-A) can be propagated entirely and rapidly inside the insect's hatchery 11.

In addition, it is preferable that the discharge ports 1123 are also formed in the air circulation passage 1121 at a predetermined interval, and the air shielding film 1122 is disposed in front of each of the discharge ports 1123 and fixedly installed .

3, the air circulation passage 1121 is connected to the partition wall C of the insect custodial 11 by one of the air circulation passages 1121 and 1122, And the upper discharge port 1123a and the lower discharge port 1123b are paired with each other to form an air circulation passage (not shown) formed in the form of a triangular prism 1121 on the upper surface and the lower surface, respectively.

As described above, the air circulation passage 1121 is formed in a triangular prism shape having an inner space so that the normal temperature air OA can flow into the air circulation passage 1121, and one side of the air circulation path 1121 is attached and installed so as to be the insect breeder partition wall C, It is possible to allow the normal temperature air OA to be more rapidly diffused into the insect sowing machine 10 by forming a pair of outlets 1123 on the side of the insect sowing machine 10.

The temperature and humidity controller 1110 takes charge of the role of cooling or heating the abnormal temperature air EA in FIG. 3 to convert it into normal temperature air OA and forming a flow of the two air (EA, OA) do. 3 is a structural diagram of the temperature and humidity controller 1110. As shown in FIG. Hereinafter, the configuration and operation of the temperature / humidity controller 1110 will be described with reference to FIG.

As shown in FIG. 4, the temperature and humidity controller 1110 is installed on the partition C of the insect incubator 10 and is connected to both sides of the air circulation passage 1121 as described above.

The temperature and humidity controller 1110 includes a thermoelectric element 1111 that can actually change the temperature of the abnormal temperature air EA and an inlet heat sink 1113 is attached to one side of the thermoelectric element 1111 And an inlet fan 1112 capable of changing the flow of air is mounted on the inlet heat sink 1113.

An auxiliary heat sink 1114 is attached to the other side of the thermoelectric element 1111 and an auxiliary fan 1115 is installed on the auxiliary heat sink 1114 to change the flow of air.

The inlet heat sink 1113 and the auxiliary heat sink 1114 may be formed of a conventional heat sink such as copper or aluminum and the inlet fan 1112 and the auxiliary fan 1115 may be made of conventional ventilation You can use a fan or a heat-dissipating fan. It is preferable that the inlet heat sink 1113 is larger in size than the auxiliary heat sink 1114 for efficiency and the blowing capacity is higher than that of the auxiliary fan 1115, It is preferable to use a larger one.

The thermoelectric element 1111 is mounted on the hole formed in the partition C of the insect custody 11 and does not move.

The inlet fan 1112 is installed in a hole formed in an outer circumferential surface of the air circulation passage 1121 and is installed in a portion of the partition C where the air circulation passage 1121 is installed, Respectively. On the outer circumferential surface of the air circulation passage 1121, a partition wall 1117 for controlling the temperature and humidity controller is formed at a certain distance from the inlet fan 1112. The heat insulating material 1116 is filled between the protruding portion of the inlet fan 1112 and the inner partition wall 1117 of the temperature / humidity regulator. By installing the inlet heat sink 1113 and the inlet fan 1112 in the above-described manner, the abnormal temperature air EA does not leak to the outside but is completely drawn through the inlet fan 1112 and flows into the inlet heat sink 1113 ).

For the installation of the auxiliary heat sink 1114 and the auxiliary fan 1115, a temperature and humidity control external barrier 1118 is installed outside the insectivorous zearing barriers C.

The external partition 1118 is for protecting the thermoelectric element 1111, the auxiliary heat sink 1114 and the auxiliary fan 1115 from external obstacles or environmental factors, Further, in order to protect the above-described components, an extended partition wall C1 may be further extended in the outer partition wall 1118, and at least one ventilation hole C2 may be formed in the extended partition wall C1 for ventilation .

The auxiliary heat sink 1114 and the auxiliary fan 1115 serve to protect the thermoelectric element 1111 from overheating or supercooling of the thermoelectric element 1111. This function is the same as that of a general heat sink and a heat sink, The description is omitted.

10: Insect Breeders. 11: Insect hatchery.
110: Temperature and humidity sensor part. 111: Temperature and humidity control device.
1110: Temperature and humidity controller. 1111: Thermoelectric element.
1112: Incoming fan. 1113: Incoming heat sink.
1114: Auxiliary heat sink. 1115: Secondary fan.
1116: Insulation. 1117: Internal bulkhead of temperature and humidity controller.
1118: Temperature and humidity controller external bulkhead. 1120: Air circulation part.
1121: Air circulation passage. 1122: Air shroud.
1123: Outlet. 12: Catcher control section.
120: Temperature and humidity control section. 121: Automatic / manual switching section.
122: Maker Display. 123: Maker communication module.
20: Main server. 21: Server communication module.
22: Setting the breeding season DB. 23: Insect setting DB.
24: Manager control section. 30: Manager terminal.
31: Login section. 32: Control interface.

Claims (11)

As an insect mass rearing system,
One or more insect breeders; Main server; And an administrator terminal,
Wherein the at least one insect breeder includes an insectivorous breeding ground and a breeding control unit,
Each of the insect kills
A temperature / humidity detection sensor unit; And a temperature / humidity control device, wherein the temperature / humidity control device
A thermoelectric element for changing an internal air temperature to change an internal air temperature, an inlet heat sink installed on one side of the thermoelectric element, an inlet which is installed on the inlet heat sink, A fan, an auxiliary heat sink attached to the other side of the thermoelectric element, and an auxiliary fan mounted on the upper surface of the auxiliary heat sink and capable of changing the flow of air, wherein the amount of the inlet fan A side wall of the intake fan, and a side wall of the intake fan. The side wall of the intake fan is formed by a double partition wall having a 'C' shape with empty spaces on both sides in a direction facing the intake fan. Humidity controller;
And an air circulation passage formed in the form of a triangular prism with an inner space for transferring the air whose temperature has been changed by the temperature / humidity controller to circulate the air whose temperature has changed through the temperature / humidity controller. The air circulation path is formed on the side surface of the air circulation passage. The upper and lower discharge ports are formed on the top and bottom surfaces of the air circulation passage, respectively. At least one outlet for allowing the insect to be ejected into the insect custody; And an air circulation part including at least one air shielding film provided on an inner side surface of the air circulation passage,
Each of the saucer control units includes a temperature / humidity control unit; An automatic / manual switching section; Nursery display; And a feeder communication module,
The main server includes a server communication module; A breeding season setting DB in which temperature and humidity ranges of each of the at least one insect breeding machine are individually and updatably stored; And an insect setting DB in which temperature and humidity ranges for each insect are individually and renewably stored; And an administrator control unit,
Wherein the manager terminal comprises: a login unit; And a control interface. ≪ Desc / Clms Page number 17 >
delete delete delete delete The insect cage according to claim 1, wherein the air circulation passage is installed on an outer bulkhead of the insect cage and is arranged in a shape of a letter 'C' surrounding the left, right and rear sides except the door of the insect cage. , Insect mass breeding system. The insect mass feeding system according to claim 1, wherein the discharge ports are formed at regular intervals, and the air shielding film is disposed in front of each of the discharge ports and fixedly installed. delete delete The insect mass feeding system according to claim 1, wherein the inlet heat sink is formed larger than the auxiliary heat sink, and the inlet fan has a larger air flow capacity than the auxiliary fan. delete

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