KR102605018B1 - Apparatus for recognizing character on straw of alivestock specification management system - Google Patents

Abstract

The information written on the semen straw can be accurately recognized and recorded to prevent recording errors or errors, and to increase the efficiency of livestock artificial insemination management, it is installed on a terminal equipped with a camera and has a groove for camera exposure according to the camera position. An additionally formed fixed frame, a connecting frame installed on the fixed frame, an insert installed on the connecting frame to provide a shooting space within the angle of view and focusable range of the camera, and inserting a straightening straw into the side so that the straightening straw is located within the space. A semen straw recognition device for a livestock feeding management system is provided, including a housing that forms a hole and is open at the top facing the camera so that a camera can photograph the semen straw placed in the space.

Description

Semen straw recognition device for livestock production management system {APPARATUS FOR RECOGNIZING CHARACTER ON STRAW OF ALIVESTOCK SPECIFICATION MANAGEMENT SYSTEM}

This disclosure relates to a semen straw recognition device in a livestock feeding management system.

In general, livestock farming is an old industry that breeds and raises livestock to provide useful products.

As investment and research continues to be made in the field of livestock farming, many environmental improvements have been made and productivity has also improved. However, productivity efficiency is currently at its limit, and it is difficult to increase productivity simply by improving the existing livestock environment. If more efficient livestock management methods are introduced, great progress can be made beyond existing productivity limits.

Systematically managing livestock breeding according to individual characteristics of livestock, keeping livestock free from disease and increasing conception rates is a very important factor in improving economic efficiency and productivity. However, in the conventional case, the management of the specifications of livestock livestock is manually recorded and managed based on the experience and judgment of the farm owner or some experts, so efficient management is not achieved.

For example, in the past, information engraved on straws containing semen for artificial insemination was manually recorded and managed in the field, and management was not carried out properly and systematically due to misreadings and errors.

Accordingly, productivity may decrease and large losses may occur due to a decrease in conception rate.

In recent years, the importance of the livestock industry has been increasing, and providing improvements to the conventional livestock feeding management system provides many advantages to users.

This project is to provide a semen straw recognition device for a livestock feeding management system that can accurately recognize and record the information written on the semen straw, preventing recording errors or errors, and increasing the efficiency of livestock artificial insemination management.

This project is to provide a semen straw recognition device for a livestock breeding management system that can minimize the time and effort required to manage livestock breeding for artificial insemination.

The system of this implementation is a management server that receives and manages specification information for livestock specification management of livestock farms and is connected to a terminal at a livestock-related workplace to provide an integrated environment for livestock specification management, and the management server and the livestock farm. A communication server for exchanging information by connecting terminals through a wired or wireless network, an IoT receiver that receives detection values transmitted from IoT devices that detect biometric information of livestock individuals in the livestock farm and authorizes them to the management server, and the management server It includes a web application server that is connected to and provides web pages for input and output required for livestock specification management to each terminal at the request of each livestock farm, and a data server that is connected to the management server and stores various data necessary for livestock specification management. can do.

The management server includes a management ledger module that manages the specification information for livestock management of livestock farms, an estrus management module that analyzes the biometric information of livestock individuals and manages the estrus status and fertilization time of livestock individuals, and artificial insemination of livestock individuals. It may include a fertilization management module that manages semen information, an infectious disease analysis module that manages infectious diseases by analyzing biometric information of livestock individuals, and an image analysis module that manages volume and weight by analyzing images of livestock individuals.

The semen information may be information about the semen number and marker characters written on the surface of the semen straw containing semen for insemination.

The insemination management module may have a structure that recognizes and manages semen information written on a semen straw containing semen for artificial insemination through a camera provided in the terminal.

The system may further include a semen straw recognition device for recognizing semen information printed on the surface of the semen straw for information management of the semen straw selected for artificial insemination of livestock individuals.

The fixed straw recognition device includes a fixed frame installed in a terminal equipped with a camera and having a groove for exposing the camera in accordance with the camera position, a connecting frame installed in the fixed frame, and a viewing angle and focus of the camera installed in the connecting frame. A shooting space is provided within the possible range, and an insertion hole for inserting a semen straw is formed on the side so that the semen straw is located within the space, and the top facing the camera is open to allow the camera to photograph the semen straw placed in the space. It can be included.

The housing or the connection frame may be formed of a material that transmits external light.

The fixed frame may be detachably installed on the terminal.

The fixing frame may be fixedly installed on the back of a cover installed to surround the terminal, and may be structured to connect the fixing frame to the terminal by mounting the cover on the terminal.

Including a shaft member formed at the front end of the fixed frame and the corresponding front end of the connecting frame, and a shaft axially coupled between the shaft members, the connecting frame is rotatably installed with respect to the fixed frame, and includes the housing. It may be folded toward the back of the terminal or unfolded at a right angle from the back of the terminal.

It may further include a stopper member that protrudes from the connection frame and limits the rotation angle of the housing in contact with the fixed frame when the housing is unfolded at a right angle from the rear of the terminal.

A female thread member is installed on the shaft member of the connection frame, and the shaft is made of a male thread, penetrates the shaft member of the fixed frame and is screwed to a female thread member installed on the shaft member of the connection frame, and the outer end of the shaft rotates. A knob may be installed to tighten or loosen the connection frame and the fixed frame by rotating the rotation knob forward or backward.

The management method of this embodiment includes the steps of providing an integrated environment for livestock specification management by checking registration through a terminal at a livestock business related to a livestock farm's livestock individual specification management system, and providing an integrated environment for livestock individual specification management. Managing biometric information of a livestock individual by receiving detection values transmitted from an IoT device that detects information, analyzing changes in biometric information of the livestock individual through the biometric information of the livestock individual received from the IoT receiver, biometric information Depending on the change analysis, it may include steps to provide results on estrus, fertilization, birth, disease, and shipment of livestock individuals.

In the biometric information management step, the biometric information of the livestock individual can be obtained from an IoT device installed on the livestock individual.

The biometric information of the livestock individual may be the unique ID of the livestock individual, real-time body temperature information of the livestock individual, information about the movement of the livestock individual, and image information of the livestock individual.

The biometric information change analysis step may include monitoring information on the body temperature or movement of the livestock individual, and predicting the fertilization time of the livestock individual by analyzing the detected change in body temperature or movement of the livestock individual.

The biometric information change analysis step may include monitoring information on the body temperature of the livestock individual and determining whether the livestock individual is infected with an infectious disease by calculating the detected change in body temperature of the livestock individual.

The biometric information change analysis step may include monitoring image information of the livestock individual and measuring volume and weight from the image of the detected livestock individual.

The management method may further include the step of receiving and managing livestock semen information for artificial insemination of livestock individuals.

The semen information management step includes identifying the livestock individual through the IoT device of the livestock individual, recognizing the management mark printed on the semen straw containing semen for artificial insemination through a camera provided in the terminal, and receiving approval and managing it. may include.

The management method may further include a consulting step of providing analysis information by a livestock expert.

The consulting step may include a step of providing information authorized by the system for management of livestock production to an expert, and a step of providing analysis results of an expert on the business management of a livestock farm and the management of the production of livestock individuals.

The various embodiments disclosed herein may be combined wholly or selectively.

According to this embodiment, it is possible to accurately record and manage livestock biometric information and management information through systematic and smart management of specifications.

By using the biometric information of livestock individuals, livestock specification management and livestock management according to the characteristics of each individual can be efficiently performed.

By continuously monitoring changes in the biometric information of livestock animals, analyzing it, and sharing the information, you can check the status of livestock anytime, anywhere.

By checking body temperature changes by farm, region, and individual livestock in real time, you can identify abnormal body temperature changes early and take necessary measures. Accordingly, it is possible to prevent infectious diseases in livestock and prevent their spread.

By accurately detecting changes in livestock's biometric information, you can easily check the timing of estrus or fertilization in livestock, thereby increasing the conception rate.

By automatically recognizing and managing the characters printed on the straight straw, errors caused by handwriting are prevented and efficient management is possible.

By measuring and managing the weight of livestock in stages through video information, the workload can be reduced.

Through standardized management, the time and effort required to manage livestock specifications can be minimized and advanced livestock management can be introduced. Accordingly, it is easy to raise and manage livestock on farms even with non-professional personnel, which can promote the development of the livestock industry and improve the quality of livestock breeding management.

Figure 1 is a schematic diagram showing the entire network of the livestock breeding management system according to this embodiment.
Figure 2 is a schematic diagram showing the configuration of a livestock breeding management system according to this embodiment.
Figure 3 shows a service screen provided by another livestock breeding management system in this embodiment.
Figure 4 is a schematic diagram for explaining livestock estrus management in the livestock breeding management system according to this embodiment.
Figure 5 is a schematic diagram for explaining semen management for livestock fertilization in the livestock breeding management system according to this embodiment.
Figure 6 is a schematic diagram for explaining livestock infectious disease management in the livestock livestock breeding management system according to this embodiment.
Figure 7 is a schematic diagram illustrating livestock image management of the livestock breeding management system according to this embodiment.
Figure 8 is a perspective view showing the semen straw recognition device of the livestock breeding management system according to this embodiment.
Figure 9 is an exploded perspective view showing the configuration of the straight straw recognition device according to this embodiment.
Figure 10 is a schematic cross-sectional view of the rectangular straw recognition device according to this embodiment.

Hereinafter, embodiments of the present invention will be described in detail. However, this is presented as an example, and the present invention is not limited thereby, and the present invention is only defined by the scope of the claims to be described later. The embodiments described below may be modified into various forms without departing from the concept and scope of the present invention. As much as possible, identical or similar parts are indicated using the same reference numerals in the drawings.

The terminology used below is only for referring to specific embodiments and is not intended to limit the invention. As used herein, singular forms include plural forms unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of .

Figure 1 shows the entire network of the livestock breeding management system according to this embodiment, and Figure 2 shows the configuration of the livestock breeding management system according to this embodiment.

As shown in FIG. 1, the system 100 for livestock livestock specification management of this embodiment connects livestock individuals and livestock-related businesses participating in livestock specification management through a wired and wireless network including an Internet network to manage livestock specifications. Provides services that perform integrated management for

Livestock or livestock individuals may refer to types such as cows, pigs, sheep, goats, horses, etc. raised on livestock farms, or individual individuals of each type of livestock.

Livestock-related businesses may be livestock farms that directly raise livestock, livestock industry officials, breeders, and veterinarians. Additionally, livestock experts such as consultants can participate in livestock-related business sites, and the system 100 can provide analysis information by livestock experts. The analysis information may be the result of an expert's analysis of the management of livestock farms and the management of livestock individual specifications. Livestock experts can receive information through the system 100, analyze it, and provide the analysis results to businesses such as farms connected through the system 100.

As shown in Figure 2, the system 100 of this embodiment receives and manages specification information for livestock specification management at a livestock farm and is connected to the terminal 200 at a livestock-related business site to provide integrated information for livestock specification management. The management server 110, which provides the environment, is connected to the communication server 120 and the management server 110 for exchanging information by connecting the management server 110 and the terminal 200 of the livestock farm through a wired and wireless communication network. At the request of the livestock farm, each terminal 200 is connected to the web application server 130 and the management server 110, which provides web pages for input and output required for livestock specification management, and various data necessary for livestock specification management are stored. It may include a data server 140.

Additionally, this system 100 may be structured to utilize IoT for livestock management.

To this end, the system 100 of this embodiment may further include an IoT receiver 150 that receives a detection value transmitted from an IoT device that detects biometric information of livestock individuals in a livestock farm and applies it to the management server 110. there is.

The management server 110 can manage the livestock specifications of each farm in real time by analyzing the detection values received from the IoT receiver 150.

IoT devices are devices that use Internet of Things technology, and can refer to devices that have sensors and communication functions built into various objects and are connected to the Internet to transmit detected data. IoT devices can vary in structure or form depending on the object, and can be applied to any device that can transmit the sensed value to the outside using IoT technology.

In this embodiment, the IoT device is a tag 300 that is attached to the ears of livestock individuals, detects biometric information of livestock individuals, and wirelessly transmits the detected information to the outside, and is installed on farms, etc. to tag each livestock individual ( It may include a gateway 400 that transmits data transmitted from 300) to the outside through a wireless communication network.

The tag 300 may be equipped with, for example, a chip containing the unique registration information of the livestock individual, a sensor that detects the body temperature or movement of the livestock individual, a communication unit that transmits biometric information to the outside, and a battery for power supply. You can. The shape of the tag 300 or the installation structure for livestock may be modified in various ways.

For example, the communication unit provided in the tag 300 may be structured to support LoRa wireless communication, which transmits a detection signal to the outside through a LoRa wireless communication network, which is a low-power, long-distance wireless communication. The LoRa wireless communication network is a communication network that supports wireless communication between a node and an external server, and transmits information detected at the node to the external gateway 400.

LoRa wireless communication is a Low Power WideArea (LPWA) method, which stands for Long Range, and has low standby power and low module prices. Therefore, unlike the existing smart device connection environment that requires a high-speed, broadband network, small-scale data can be exchanged at low power by installing a chipset on the node without a separate base station or relay equipment, and can provide seamless interaction such as secure two-way communication and mobility. Provides compatibility. In addition to LoRa wireless communication, the communication department can also apply low-power wireless communication protocols such as Bluetooth and Zigbee.

The gateway 400 may collect data transmitted from the tag 300 installed on the livestock individual and transmit it to the management server 110, for example, through the wireless communication unit of the system 100. For example, the gateway 400 may be located within an area capable of wireless communication with the tag 300 attached to a livestock individual.

The gateway 400 manages a plurality of tags 300 and collects data transmitted from each tag 300. The gateway 400 may transmit the collected data to the external system 100 through a wireless communication network.

Data transmitted through the gateway 400 is received through the IoT receiver 150 of the system 100, and the system 100 of this embodiment processes, organizes, analyzes, etc. the data transmitted from the gateway 400. After going through the process, information can be provided to actual users in real time.

Information may be provided to the terminal 200 at each business site through, for example, a mobile web or a general web page. Accordingly, users belonging to each business site can check the biometric information of livestock as well as the information provided by the system 100 in real time through the terminal 200.

In this way, through IoT technology, livestock specification management can be performed in real time on any farm without missing information or errors. Therefore, various records and biometric information for livestock management can be accurately identified and managed without error, thereby increasing the farm's livestock management efficiency.

The terminal 200 may include a computer such as a desktop or laptop provided at each workplace, or a personal portable terminal such as a mobile phone or a personal digital assistant (PDA). The terminal 200 can be understood as a device that inputs and outputs data and processes given computing tasks while exchanging wired and wireless communications.

The terminal 200 can access the management system 100 of this embodiment through a wired or wireless network. Accordingly, participating entities belonging to each workplace can be connected to the integrated management system 100 anytime, anywhere through the network using the terminal 200.

An application provided by the management system 100 may be installed and executed on each terminal 200. An application may be a program or a web page running in a web environment. Accordingly, participating entities at each business site can access the management system 100 of this embodiment through the terminal 200 and perform tasks necessary for livestock specification management under the integrated environment provided by the system 100. For example, a format environment for inputting information for each task for livestock specifications may be provided to each terminal 200 through the system 100, and the information entered through the terminal 200 is input into the system 100. and can be managed.

In this embodiment, the web application server 130 provides an interface for executing applications to terminals 200 at each business site connected to the management server 110. The web application server 130 converts various information in accordance with communication standards and provides it to each terminal 200, and authorizes the information input from each terminal 200 to the management server 110.

For example, the web application server 130 provides a connection screen for accessing participating subjects at each livestock-related business including livestock farms, a screen for registering livestock farms and livestock objects or tags 300, and job selection for livestock farms. Screens necessary for livestock specification management, including a screen for managing selected tasks, an information input screen for managing selected tasks, and a screen displaying information for livestock specification management, are provided to the terminal 200 through the management server 110, and the terminal Information input from (200) can be transmitted to the management server (110).

Figure 3 shows an example of a service screen provided through the web application server 130 according to this embodiment.

As shown, participating entities at each workplace can be connected to the specification management system 100 of this embodiment through the service screen provided on each terminal 200. Participating entities at each business site access the system 100 by entering their ID and password, and select a series of tasks for registering tags 300 of livestock objects or managing livestock specifications through the services provided by the system 100. Able to perform management tasks.

In this way, participating entities at each business site can perform related tasks under a single, integrated management environment, such as accessing the system 100 and providing or receiving information through various service screens provided by the web application server 130. . The service screen provided by the web application server 130 can be modified in various ways.

The management server 110 analyzes changes in the biometric information of the livestock individual through the biometric information of the livestock individual received from the IoT receiver 150 and receives authorization for semen information for artificial insemination, from registration of each livestock individual to estrus, fertilization, and Performs necessary tasks for overall livestock management, including birth, disease, death, and shipping.

The management server 110 is connected to the terminal 200 at each business site through a wired or wireless network through the communication server 120. The management server 110 is connected to the web application server 130 and the data server 140, and provides services such as web pages necessary for information input and output to each terminal 200 through each server, and each terminal ( 200) and save the input information.

Through the management server 110, all information required for livestock specification management, from object registration to shipment, is integrated and managed.

As shown in Figure 2, the management server 110 of this embodiment includes a management ledger module 111, an estrus management module 112, a correction management module 113, an infectious disease analysis module 114, and an image analysis module 115. ) may include.

The management server 110 can manage specification information for livestock specification management at the livestock farm through the management ledger module 111.

The management ledger module 111 can manage information recorded in the livestock breeding management ledger. The construction management module connects and manages information input and generated through the terminal 200 at each business site in relation to livestock breeding management.

The management ledger module 111 of this embodiment can manage registration information of the livestock farm, registration information about livestock individuals of the livestock farm, biometric information of registered livestock individuals, and specification information required for livestock specification management.

The registration information of the livestock farm may be information about the livestock farm's unique ID, address, farm owner, type of livestock in the farm, and number of animals by type. For example, the registration information of the livestock farm may be provided from the terminal 200, stored in the data server 140, and managed through the management ledger module 111.

Registration information for a livestock entity may be a unique ID of the livestock entity or history information of the livestock entity. Registration information for livestock entities may be provided from, for example, the terminal 200 or an IoT device, stored in the data server 140, and managed through the management ledger module 111.

The biometric information of the livestock individual may be the unique ID of the livestock individual, real-time body temperature information of the livestock individual, information about the movement of the livestock individual, and image information of the livestock individual. For example, the biometric information of a livestock individual may be authorized by an IoT device installed on the livestock individual, stored in the data server 140, and managed through the management ledger module 111.

Specification information includes information on purchase of feed, information on feeding of feed, information on entering and exiting the farm, information on calving of livestock, information on estrus of livestock, information on death of livestock, and information on shipping of livestock. , It may be information related to the purchase of a livestock individual, information related to fertilization of a livestock individual, information related to fertilization of a livestock individual, and information related to pregnancy of a livestock individual.

Specification information may be provided, for example, from the terminal 200 or an IoT device, stored in the data server 140, and managed through the management ledger module 111.

In this way, the management ledger module 111 provides input and output information necessary for overall specification management of livestock individuals to the corresponding terminal 200, and provides information on tasks performed for specification management from the terminal 200 or IoT devices. It is authorized and stored and managed in the data server 140.

The management ledger module 111 provides the service screen required for livestock specification management to the terminal 200 through the web application server 130. The worker can enter and confirm necessary information through the service screen provided to the terminal 200 by the management ledger module 111.

Accordingly, workers at each workplace can easily input and manage information on necessary items through the specification management screen provided on the terminal 200, and proceed with subsequent steps by checking the entered information.

In addition, the management server 110 can manage information related to estrus of the livestock individual by analyzing biometric information of the livestock individual through the estrus management module 112, and manage the estrus state and fertilization period of the livestock individual. The estrus management module 112 connects and manages information generated by the IoT device of each livestock individual in relation to livestock estrus.

The estrus management module 112 of this embodiment can manage information necessary for estrus and fertilization management, such as registration information for livestock individuals and biometric information generated by measurement from IoT devices attached to registered livestock individuals. Registration information and biometric information of livestock individuals identified for estrus and fertilization management are provided from IoT devices, stored in the data server 140, and can be managed through the estrus management module 112.

The estrus management module 112 may include an analysis unit 116 that predicts the fertilization time according to estrus of a livestock individual. The analysis unit 116 predicts the fertilization time of the detected livestock individual by analyzing changes in body temperature and movement of the detected livestock individual.

The biometric information of the livestock individual managed in the estrus management module 112 may include the unique ID of the livestock individual, real-time body temperature information of the livestock individual, and information about the movement of the livestock individual.

For example, Figure 4 shows an example of livestock estrus management using the present system 100.

As shown in Figure 4, the body temperature of a livestock individual is measured through a tag 300 attached to the livestock individual. Body temperature information measured by the tag 300 is collected from the nearby gateway 400, and the gateway 400 transmits the measured body temperature information to the management server 110 through a wireless communication network. The estrus management module 112 of the management server 110 analyzes and manages biometric information transmitted from the gateway 400.

In this way, the estrus management module 112 continuously monitors changes in body temperature and movement of livestock individuals transmitted from the IoT device, and analyzes the monitored information through the analysis unit 116 to determine the exact state of estrus and fertilization time as well as childbirth. Even the timing can be predicted.

The results of the estrus status or fertilization period of livestock animals analyzed by the estrus management module 112 are provided to the terminal 200 of the business entity at the necessary business site through a wireless communication network.

Accordingly, farms can check the exact status of livestock individuals, such as estrus and fertilization time, anytime and anywhere and take necessary actions.

Therefore, it is possible to reduce the effort required for estrus management and increase the conception rate by detecting estrus and artificial insemination periods in time without missing them due to neglect of management.

The system 100 of this embodiment analyzes changes in body temperature and movement of livestock through IoT devices and provides accurate estrus and fertilization times to each business site, enabling more effective spec management. Accordingly, it is possible to minimize losses due to artificial insemination failure and improve productivity.

The estrus management module 112 can provide a service screen necessary for estrus and artificial insemination management of livestock individuals to the terminal 200 through the web application server 130. The worker can enter and confirm necessary information through the service screen provided to the terminal 200 by the estrus management module 112.

Additionally, the management server 110 can manage semen information for artificial insemination of livestock individuals through the insemination management module 113. The insemination management module 113 connects and manages the information generated by the IoT device for each livestock individual in relation to artificial insemination of livestock and the semen information for artificial insemination.

The insemination management module 113 of this embodiment can manage registration information for livestock individuals and information necessary for managing semen used for artificial insemination. Registration information of livestock entities identified for revision management is provided from IoT devices, stored in the data server 140, and can be managed through the revision management module 113.

Semen for artificial insemination can be stored and used in a semen straw. Semen straws can have semen information printed on their surface. Semen information may be the number of the male individual used for artificial insemination, serial number of the semen straw, manufacturer, date of manufacture, barcode, etc.

In this embodiment, the marker characters printed on the straight straw can be recognized and managed through the camera 210 provided in the terminal 200. The terminal 200 may be further equipped with a separate recognition device to recognize the marker characters printed on the straight straw. For example, the recognition device can be mounted on the terminal 200 and can recognize the character mark using the camera 210 provided on the terminal 200.

Accordingly, by inserting a semen straw into the recognition device, the operator can manage semen information by automatically recognizing the marking characters printed on the semen straw through the recognition device.

The fixed amount information recognized by the recognition device is transmitted to the management server 110 through the terminal 200, stored in the data server 140, and can be managed through the modification management module 113.

Figure 5 shows an example of semen management for artificial insemination of livestock in the present system 100.

As shown in Figure 5, the unique ID of the livestock individual can be confirmed through the tag 300 attached to the livestock individual. The fixed amount information of the fixed amount straw is recognized through the recognition device provided in the terminal 200, and this information is transmitted to the management server 110 through a wireless communication network. The correction management module 113 of the management server 110 connects the transmitted livestock individual information and the semen information of the semen straw, stores it in the data server 140, and manages it.

In this way, the correction management module 113 records and stores the unique ID and semen information of the livestock individual from the IoT device directly on site through the terminal 200, thereby preventing semen management errors. As a result, semen management for artificial insemination can be carried out accurately on farms.

In the conventional case, there was a high risk of misreading and errors as semen information was manually recorded by manually checking the marking characters printed on the semen straw in the field.

The system 100 of this embodiment enables more effective specification management as semen management for artificial insemination is performed through the recognition device of the IoT device and the terminal 200. Accordingly, it is possible to minimize losses due to artificial insemination errors and improve productivity.

The insemination management module 113 can provide the terminal 200 with a service screen necessary for semen management for artificial insemination of livestock individuals through the web application server 130. The worker can enter and confirm necessary information through the service screen provided to the terminal 200 by the modification management module 113.

In addition, the management server 110 can analyze the biometric information of livestock individuals through the infectious disease analysis module 114 to manage information related to infectious diseases in livestock individuals and manage whether infectious diseases have occurred in livestock individuals. The infectious disease analysis module 114 connects and manages biometric information generated by the IoT device of each livestock individual in relation to the outbreak of infectious diseases in the livestock individual.

The infectious disease analysis module 114 of this embodiment can manage information necessary for infectious disease management, such as registration information for livestock individuals and biometric information generated by measurement from IoT devices attached to registered livestock individuals. Registration information and biometric information of livestock individuals identified for infectious disease management are provided from IoT devices, stored in the data server 140, and can be managed through the infectious disease analysis module 114.

The infectious disease analysis module 114 may include an operation unit 117 that determines whether a livestock individual is infected with an infectious disease. The calculation unit 117 determines whether the livestock individual is infected with an infectious disease by calculating the change in body temperature of the detected livestock individual.

The biometric information of the livestock individual managed in the infectious disease analysis module 114 may be information about the unique ID of the livestock individual and the real-time body temperature of the livestock individual.

For example, Figure 6 shows an example of livestock infectious disease management of the present system 100.

As shown in Figure 6, the body temperature of a livestock individual is measured through a tag 300 attached to the livestock individual. Body temperature information measured by the tag 300 is collected from the nearby gateway 400, and the gateway 400 transmits the measured body temperature information to the management server 110 through a wireless communication network. The infectious disease analysis module 114 of the management server 110 analyzes and manages changes in biometric information transmitted from the gateway 400.

In this way, the infectious disease analysis module 114 continuously monitors the change in body temperature of the livestock individual transmitted from the IoT device and calculates the monitored body temperature change through the calculation unit 117 to confirm the occurrence of abnormal body temperature change in the livestock individual. Signs of infectious disease infection can be identified.

The results of signs of infectious disease infection in livestock individuals analyzed by the infectious disease analysis module 114 are provided to the terminal 200 of the business entity at the necessary workplace through a wireless communication network.

Accordingly, it is possible to accurately confirm and monitor infectious diseases in livestock from farms or related organizations and take necessary measures in a timely manner.

In addition, the infectious disease analysis module 114 can construct a nationwide military service system 100 by displaying and providing changes in body temperature of livestock individuals nationwide on a map (GIS).

Accordingly, in the event of a livestock infectious disease such as foot-and-mouth disease or swine fever, the location of the suspected farm can be displayed on the map and confirmed in real time to monitor and take related measures. In addition, only livestock with abnormal signs can be selected and managed to prevent the spread of infectious diseases and can be used as basic data for setting up quarantine lines.

Therefore, large-scale livestock damage can be reduced by not missing the outbreak of infectious diseases due to neglect of management and by detecting abnormal signs in livestock early.

The infectious disease analysis module 114 can provide the terminal 200 with a service screen necessary for managing whether livestock are infected with an infectious disease outbreak through the web application server 130. Workers can enter and confirm necessary information through the service screen provided on the terminal 200 by the infectious disease analysis module 114.

Additionally, the management server 110 can analyze images of livestock individuals through the image analysis module 115 to manage volume and weight. The video analysis module 115 manages the image information of each livestock individual by linking biometric information, such as a unique ID generated by the IoT device of each livestock individual, with the image information of each livestock individual in relation to the volume and weight management of the livestock individual.

The image analysis module 115 of this embodiment can manage information necessary for managing the volume and weight of livestock, such as information on the unique ID of the livestock individual and image information of the livestock individual captured by the camera 210. Unique ID information of livestock individuals identified for livestock volume and weight management is provided from IoT devices, stored in the data server 140, and can be managed through the video analysis module 115.

The image analysis module 115 may include a detection unit 118 that measures the volume and weight of the livestock individual. The detection unit 118 measures the volume and weight of the livestock object by image processing the image information of the captured livestock object. The video information may be a video of the entire livestock.

In this embodiment, the image analysis module 115 may be configured to capture and manage images of livestock individuals through the camera 210 provided in the terminal 200.

Accordingly, the worker can manage the weight and volume of the livestock by obtaining image information about the livestock by photographing the livestock using the camera 210 of the terminal 200. Image information recognized by the camera 210 may be transmitted to the management server 110 through the terminal 200, stored in the data server 140, and managed through the image analysis module 115.

For example, Figure 7 shows an example of the system 100 for managing livestock body volume and weight.

As shown in Figure 7, the unique ID of the livestock individual can be confirmed through the tag 300 attached to the livestock individual. When the entire image of a livestock individual is captured through the camera 210 provided in the terminal 200, this image information is transmitted to the management server 110 through a wireless communication network. The video analysis module 115 of the management server 110 connects the transmitted livestock individual information and video information, stores it in the data server 140, and manages it. In addition, the image analysis module 115 analyzes the image information and calculates the weight and volume of the corresponding livestock individual.

In this way, the image analysis module 115 can measure body weight and volume through images of livestock individuals transmitted from the terminal 200 and continuously monitor changes in body weight and volume. By measuring body weight and volume through the detection unit 118 and continuously monitoring the measured results, it is possible to effectively manage the weight and volume of each livestock individual.

The results of the weight and volume of the livestock individual measured by the video analysis module 115 are provided to the terminal 200 of the business entity at the necessary business site through a wireless communication network.

Accordingly, the work time and effort required to measure the weight and volume of the relevant livestock individual can be reduced and the measurement can be performed more simply.

In the conventional case, there is a problem that the work is difficult and accuracy is low because the weight is measured by placing each livestock on a scale in the field or relying on the visual judgment of an experienced worker.

The system 100 of this embodiment enables more effective specification management by managing the volume and weight of livestock individuals through information obtained through the IoT device and the camera 210 of the terminal 200. Accordingly, through efficient feed supply, feed costs can be reduced and workability can be increased to reduce labor costs and improve productivity.

The video analysis module 115 can provide a service screen necessary for managing the weight and volume of livestock individuals to the terminal 200 through the web application server 130. The worker can input and confirm necessary information through the service screen provided to the terminal 200 by the video analysis module 115.

In this way, the management server 110 provides an integrated management environment necessary for livestock breeding management. Participating entities at each business site can access the integrated network established through the management server 110 to receive information and upload necessary data.

Data uploaded to the management server 110 are stored in the data server 140 and provided through the management server 110 when necessary.

The data server 140 stores all history and information managed by the management server 110. The data server 140 provides necessary information to the management server 110 according to the request of the management server 110. The data server 140 stores information transmitted to the management server 110 from the terminal 200 of the participating entity at each business site or the IoT device of the livestock individual.

The data server 140 of this embodiment includes a management ledger DB 141 that stores specification information necessary for managing livestock individual specifications for each livestock farm, a farm information DB 142 that stores registration information for livestock farms, and livestock individual specifications. It may include an individual information DB 143 in which individual registration information is stored, and a biometric information DB 144 in which biometric information for each livestock individual is stored.

For example, the management ledger DB 141 includes information on purchase of feed, information on feeding of feed, information on entering and exiting the farm, information on calving of livestock, information on estrus of livestock, and information on death of livestock. , specification information including information related to shipment of livestock individuals, information related to purchase of livestock individuals, information related to fertilization of livestock individuals, information related to fertilization of livestock individuals, and information related to pregnancy of livestock individuals may be stored.

The farm information DB 142 may store livestock farm information including information on the livestock farm's unique ID, address, farm owner, type of livestock in the farm, and number of animals by type.

The farm information DB 142 may store additional information about participating entities at each business site in addition to the livestock farm. Information about participating entities at each business site may be, for example, information about unique ID, address, business owner, etc.

The individual information DB 143 may store livestock individual registration information, including the unique ID of the livestock individual and the history information of the livestock individual.

The biometric information DB 144 may store biometric information of the livestock individual, including the unique ID of the livestock individual, real-time body temperature information of the livestock individual, information about the movement of the livestock individual, and image information of the livestock individual. The biometric information DB can further store semen information for artificial insemination.

Meanwhile, the system 100 of this embodiment mechanically recognizes and provides on-site semen information written on a semen straw containing semen selected for artificial insemination of a livestock individual and managed by the insemination management module 113 of the management server. It may further include a recognition device.

Semen for artificial insemination is injected into a semen straw and frozen and stored at cryogenic temperatures in a liquid nitrogen tank. Semen information is printed on the surface of the semen straw, so this semen information must be accurately checked and recorded in order to manage livestock specifications.

The semen straw recognition device of this embodiment can more simply and accurately recognize and manage the semen information written on the semen straw.

Figures 8 to 10 show the configuration of a straight straw recognition device according to this embodiment.

The fixed straw (P) recognition device 10 of this embodiment is installed on the terminal 200 equipped with a camera 210 and has a groove 21 for exposing the camera 210 in accordance with the position of the camera 210. A frame 20, a connection frame 30 installed on the fixed frame 20, a shooting space 41 installed on the connection frame 30 and within the angle of view and focusable range of the camera 210 are provided, and a space on the side ( 41), an insertion hole 42 for inserting the semen straw is formed so that the semen straw (P) is located within the camera (210), and the upper end facing the camera (210) is open to insert the semen straw (P) placed in the space (41) into the camera (210). It may include a housing 40 capable of taking pictures.

Accordingly, by simply inserting the semen straw (P) into this device, the semen information written on the surface can be accurately recognized and confirmed. As mentioned above, semen information may be the number of the male individual used for artificial insemination, serial number of the semen straw, manufacturer, date of manufacture, barcode, etc.

Therefore, it is possible to reduce the inconvenience and workload of a conventional operator having to visually check and record the semen information written on a small semen straw (P), prevent errors or typos that occur during the recording process, and record and manage accurate information. there is.

The fixed frame 20 may be detachably installed on the terminal 200. Accordingly, only the terminal 200 can be used, or, if necessary, the fixed frame 20 can be mounted on the terminal 200 and used as a straight straw (P) recognition device.

The structure for attaching and detaching the fixing frame 20 from the terminal 200 can be simply a structure of attaching double-sided tape to the upper surface of the fixing frame 20 that is in contact with the terminal 200 and attaching it to the rear of the terminal 200.

In another embodiment, the fixing frame 20 may be a structure fixedly installed on the rear of a cover (not shown) installed to surround the terminal 200. Accordingly, the cover can be mounted on the terminal 200 to connect the fixing frame 20 to the terminal 200.

The cover is placed on the rear of the terminal 200 to protect the terminal 200 and is coupled to the terminal 200. The fixing frame 20 is already fixed to the cover, and the fixing frame 20 can be mounted on the terminal 200 by installing the cover on the terminal 200.

In another embodiment, a groove (not shown) into which the terminal 200 is inserted is formed in the fixing frame 20, and the device can be attached to or detached from the terminal 200 by inserting the tip of the terminal 200 into the groove. there is.

The fixing frame 20 may have a groove 21 formed at a position corresponding to the camera 210 of the terminal 200. Through the groove 21, the camera 210 is exposed to the outside without being obscured by the fixed frame 20, so that the semen straw P can be photographed.

The fixed frame 20 may have shaft members 22 formed at both ends for coupling to the connecting frame 30.

The connection frame 30 is installed on the fixed frame 20 to position the housing 40 in front of the camera 210.

A shaft member 32 is formed at the tip of the connection frame 30 facing the fixed frame 20, and is rotatably coupled to the shaft member 22 and the shaft 23 of the fixed frame 20.

Accordingly, the connection frame 30 is rotatably coupled to the fixed frame 20, so that the housing 40 can be folded toward the rear of the terminal 200 or unfolded at a right angle from the rear of the terminal 200.

Therefore, as shown in FIG. 10, when in use, the housing 40 is unfolded at a right angle from the rear of the terminal 200 to position the housing 40 in front of the camera 210, and after use, the housing 40 is placed in the terminal 200. It can be folded backwards to minimize its size. Therefore, it can be used and carried more simply and easily.

A stopper member 34 may be further formed at the top of the connection frame 30. The stopper member 34 protrudes from the connecting frame 30 and comes into contact with the fixed frame 20 when the connecting frame 30 is rotated and unfolded with respect to the fixed frame 20. Accordingly, as the stopper member 34 contacts the bottom of the fixed frame 20, the connecting frame 30 is no longer rotated and the connecting frame 30 can be rotated only at a preset angle.

Accordingly, the rotation angle of the connection frame 30 is limited by the stopper member 34, making it possible to accurately position the housing 40 installed on the connection frame 30 at the shooting position of the camera 210.

The device of this embodiment may have a structure in which the connecting frame 30 is rotated and fixed with respect to the fixed frame 20. Accordingly, by rotating the connection frame 30, the housing 40 can be stably maintained in an unfolded or folded state with respect to the terminal 200.

For this purpose, a female thread member 25 is installed on the shaft member 22 of the connection frame 30, and the shaft 23 is made of male threads and penetrates the shaft member 22 of the fixed frame 20 to connect the connection frame 30. ) is screwed to the female screw member 25 installed on the shaft member 22, and a rotation knob 27 is installed on the outer end of the shaft 23, and the connection frame 30 is connected by rotating the rotation knob 27 forward and backward. It may be a structure that tightens or loosens the and fixing frame 20.

Unlike the above structure, a structure in which the shaft member 22 of the connecting frame 30 is located outside the shaft member 22 of the fixed frame 20 can also be applied. In this structure, the female thread member 25 is installed on the shaft member 22 of the fixed frame 20, and the shaft 23 penetrates the shaft member 22 of the connecting frame 30 and is connected to the female thread member 25. Can be screwed.

Hereinafter, this embodiment will be described as an example of a structure in which the shaft member 22 of the fixed frame 20 is located outside the shaft member 22 of the connecting frame 30, as shown in FIG. 8.

The shaft 23 made of male threads penetrates the shaft member 22 of the fixed frame 20 and is screwed to the female thread member 25 installed on the shaft member 22 of the connecting frame 30.

According to the screw fastening, the rotation knob 27 fastens and secures the shaft member 22 of the fixed frame 20 to the shaft member 22 of the rotating frame. The shaft member 22 of the fixed frame 20 is pressed and fixed between the shaft member 22 of the rotating frame and the rotation knob 27 of the shaft 23. Therefore, the rotary frame can be simply fixed to the fixed frame 20 by rotating the rotary knob 27 to tighten or loosen the shaft 23.

Accordingly, work can be performed stably by fixing the housing 40 installed on the rotating frame in a folded or unfolded state to the rear of the terminal 200.

A housing 40 is installed on the front of the connection frame 30.

The housing 40 is combined with the connecting frame 30 to form an imaging space 41 therein. The shooting space 41 is an area in which the camera 210 of the terminal 200 can shoot, that is, within the range of the angle of view of the camera 210, and does not deviate from the range in which the camera 210 can shoot, and allows the camera 210 to focus. It may mean an area within a range that can be adjusted. Accordingly, the semen straw P located in the photographing space 41 can be accurately photographed by the camera 210 without missing all of the semen information printed on the semen straw P.

The top of the housing 40 facing the camera 210 is open so that the camera 210 can photograph the sperm straw (P) placed in the space 41.

An imaging space 41 is provided inside the housing 40, and an insertion hole 42 is formed on the side of the housing 40 to insert the straightening straw P so that the straightening straw P is positioned within the space 41. The insertion hole 42 communicates with the internal imaging space 41 of the housing 40. The semen straw (P) is inserted into the insertion hole (42) and placed in the imaging space (41).

Accordingly, the fixed straw P inserted into the housing 40 through the insertion hole 42 is located within the viewing angle and focusable range of the camera 210 inside the housing 40. Therefore, the camera 210 can accurately focus on the surface of the semen straw (P) and capture the printed semen information without omission.

In this embodiment, the housing 40 or the connecting frame 30 may be formed of a material that transmits external light.

Accordingly, external light is irradiated into the shooting space 41 through the housing 40 or the connecting frame 30, so that the inside of the housing 40 can secure sufficient illumination required for shooting.

As shown in Figure 3, this device can use the terminal 200 by rotating the connection frame 30 with respect to the fixed frame 20 and folding the housing 40, and when necessary, the connection frame 200 can be connected to the terminal 200. By rotating (30) to unfold the housing (40), the semiconductor straw (P) recognition work can be easily performed.

For the straight straw (P) recognition operation, when the operator unfolds the connection frame 30 from the terminal 200, the connection frame 30 is rotated with respect to the fixed frame 20 via the shaft 23. Accordingly, the housing 40 installed on the connection frame 30 is expanded at a right angle to the terminal 200.

When the housing 40 is unfolded, the shooting space 41 inside the housing 40 is aligned with the shooting area of the camera 210 of the terminal 200. In this state, when the operator inserts the semen straw (P) into the housing 40, preparation for recognition of the semen straw (P) is completed.

Also, the operator can recognize the semen information written on the surface of the semen straw (P) by operating the terminal 200 and photographing the semen straw (P) with the camera 210. The semen straw (P) is located within the shooting angle and focus range of the camera 210, so the camera 210 can accurately capture the semen information printed on the surface.

The semen information captured by the camera 210 may be recorded as semen information through an information recognition program provided in the terminal 200 and authorized to the system. Alternatively, semen information captured by the camera 210 may be transmitted to the system and recorded as semen information through a recognition program provided in the system.

This device has the structure described above, and can easily recognize and manage the semen information written in the semen straw (P).

In the past, workers had to visually check the information printed on the straight straw and record it individually by hand, which resulted in misreadings and errors, making accurate management difficult.

However, in the case of this embodiment, by managing the semen information of the semen straw (P) through the recognition device 10, the semen information written in the semen straw (P) can be more easily and accurately checked and managed, and the amount of time required to manage the semen information It can reduce effort and time and increase workability.

Hereinafter, a method for managing livestock livestock production through the system of this embodiment will be described as follows.

The feeding management method of this embodiment includes the steps of providing an integrated environment for livestock feeding management through a terminal at a livestock-related workplace connected to a system for managing the feeding of livestock subjects on a livestock farm, and managing biometric information of livestock subjects on a livestock farm. It may include a step of analyzing changes in the biometric information of the livestock individual through the biometric information of the livestock individual, and providing results on estrus, fertilization, childbirth, disease, and shipment of the livestock individual according to the analysis of the biometric information change. there is.

Each step can be performed sequentially within the system, and each step can be performed independently for each participating entity at each workplace.

First, participating entities at each workplace, such as farms, livestock officials, breeders, veterinarians, or livestock experts, can be registered in this system and managed as members. Livestock managed at each farm are also attached to IoT devices such as tags for each individual livestock, so they are registered and managed in this system through IoT devices. The tag has a chip embedded with the unique registration information of each livestock individual, so each livestock individual can be simply registered and managed in the system through the tag.

Participating entities at each workplace can receive service screens for specification management from the system through terminals and perform necessary management tasks.

The system manages information entered through the terminal and provides stored data through the terminal upon request from participating subjects.

For example, when a user accesses the system by logging in, he or she can register information for livestock specifications or select the type of task, and perform management tasks by selecting the necessary task.

Work for livestock breeding can cover the entire breeding management work, from feed purchase and supply to farm entry, livestock estrus, insemination, birth, disease, shipping, and death.

The user can select the required task in the environment provided through the terminal and record the task history. Livestock specification information entered through the terminal is transmitted to the system, stored and stored, and provided to the terminal at the user's request when necessary.

In the step of managing biometric information, biometric information of livestock individuals can be detected and obtained in real time through IoT devices such as tags installed on livestock individuals. As mentioned, the tag is equipped with a sensor that detects the body temperature or movement of the livestock individual in addition to the chip, so the biometric information of the livestock individual can be detected in real time through the tag.

The biometric information of the livestock individual may be the unique ID of the livestock individual, real-time body temperature information of the livestock individual, information about the movement of the livestock individual, and image information of the livestock individual.

Biometric information detected through IoT devices is transmitted to the system. Accordingly, the actual biometric information of livestock individuals can be uploaded to the system in real time without omission or error in the biometric information.

The system stores and manages the biometric information of transmitted livestock individuals, and when necessary, information can be provided through a terminal at the request of each operator.

The changing values of biometric information obtained through the biometric information management stage are analyzed through the system. The results of the analysis of the amount of change in biometric information are stored and managed in the system and, when necessary, can be provided through the terminal at the request of the operator.

In this way, by analyzing the amount of change in biometric information, appropriate specifications can be managed according to the change. Accordingly, livestock feeding management can be performed more efficiently.

In this embodiment, the biometric information change analysis step may include a correction time prediction step, an infectious disease determination step, and an image analysis step.

The fertilization time prediction step may include monitoring information on the body temperature or movement of the livestock individual, and predicting the fertilization time of the livestock individual by analyzing changes in body temperature and movement of the detected livestock individual.

Information about the body temperature and movement of livestock individuals is transmitted to the system and continuously monitored. The system detects the timing of estrus and fertilization in livestock by analyzing changes in body temperature or movement.

The system can check the analysis results and determine that it is time for fertilization due to estrus, for example, if the body temperature or movement of the livestock individual reaches a preset reference value. The reference value can be understood as an appropriate range of values for the body temperature or movement of a livestock individual that indicates the time of estrus or fertilization. The reference value can be set according to results obtained by research or experience.

The system can predict the fertilization time of livestock individuals according to the analysis results and provide the results through the terminal.

The infectious disease determination step may further include monitoring information on the body temperature of the livestock individual and determining whether the livestock individual is infected with an infectious disease by calculating a change in body temperature of the detected livestock individual.

Information about the body temperature of livestock individuals is transmitted to the system and continuously monitored. The system detects whether livestock are infected with infectious diseases by analyzing changes in body temperature.

The system checks the results of calculations on changes in body temperature and, for example, can suspect an infectious disease outbreak if the body temperature of a livestock individual exceeds a preset standard value range and abnormal signs appear. The reference value can be understood as the standard value range for the body temperature of a livestock individual infected with an infectious disease. The reference value can be set according to results obtained by research or experience.

The system can provide results on signs of infectious diseases in livestock individuals through the terminal according to the calculation results.

Accordingly, measures can be taken against infectious diseases through a message sent to the farm that supplies the livestock in question as well as related organizations, and the location of the farm is displayed through the quarantine system as a basis for preventing the spread of infectious diseases nationwide and establishing a defense line. It can be used as data.

The image analysis step may include monitoring image information of the livestock individual and measuring volume and weight from the image of the detected livestock individual.

Image information of livestock individuals is transmitted to the system and continuously monitored. The system analyzes the approved image information and measures the weight and volume of livestock individuals.

The system can measure the volume and weight of a livestock individual from image information, for example through image processing. The system can provide measured results through a terminal.

In addition, the breeding management method of this embodiment may further include a semen management step of receiving and managing livestock semen information for artificial insemination of livestock individuals.

The semen management step includes the step of checking the livestock individual through the IoT device of the livestock individual, recognizing the management mark printed on the semen straw containing semen for artificial insemination through a camera installed in the terminal, and receiving approval and managing it. can do.

Biometric information of livestock individuals for artificial insemination and semen information for artificial insemination are transmitted and managed in the system. Since fixed-cost information is entered through the terminal's camera, it can be accurately stored and managed in the system without errors or mistakes. Semen management information can be provided through the terminal when necessary.

The management method of this embodiment may further include a consulting step of providing analysis information by a livestock expert.

The consulting step may include providing information approved by the system for livestock management management to livestock experts, and providing analysis results by livestock experts on management of livestock farms and management of livestock individuals.

The system can provide livestock management information to livestock experts at the request of workers such as farm owners.

Based on the information provided, livestock experts can perform consulting for livestock individual specification management as well as farm management, breeding, breeding, and disease management of livestock individuals, and provide the results.

The system can store and manage the livestock expert's consulting results and provide the results to the requester's terminal. Accordingly, farm owners and others can check the advice of livestock experts to perform more effective and productive breeding management.

Although exemplary embodiments of the present invention have been shown and described as described above, various modifications and other embodiments will occur to those skilled in the art. These modifications and other embodiments are to be considered and included in the appended claims without departing from the true spirit and scope of the present invention.

10: Recognition device 20: Fixed frame
21: groove 22: shaft member
23: Shaft 25: Female thread member
27: Rotation knob 30: Connection frame
32: shaft member 40: housing
41: shooting space 42: insertion hole
100: Specification management system 110: Management server
111: Management ledger module 112: Estrus management module
113: Modification management module 114: Infectious disease analysis module
115: video analysis module 116: analysis unit
117: calculation unit 118: detection unit
120: communication server 130: web application server
140: data server 150: IoT receiver
200: terminal 210: camera
300: Tag 400: Gateway

Claims (3)

A semen straw recognition device in the livestock specification management system to recognize the semen information printed on the surface of the semen straw for information management of the semen straw selected for artificial insemination of livestock individuals.
The fixed straw recognition device includes a fixed frame installed in a terminal equipped with a camera and having a groove for exposing the camera in accordance with the camera position, a connecting frame installed in the fixed frame, and a viewing angle and focus of the camera installed in the connecting frame. A shooting space is provided within the possible range, and an insertion hole for inserting a semen straw is formed on the side so that the semen straw is located within the space, and the top facing the camera is open to allow the camera to photograph the semen straw placed in the space. Contains,
It further includes a shaft member formed at the front end of the fixed frame and the corresponding front end of the connection frame, and a shaft axially coupled between the shaft members, wherein the connection frame is rotatably installed with respect to the fixed frame, and the housing A semen straw recognition device for a livestock feeding management system that folds to the back of the terminal or unfolds at a right angle from the back of the terminal. delete According to claim 1,
The housing or the connection frame is a semen straw recognition device of a livestock feeding management system formed of a material that transmits external light.