WO2023080610A1 - Breeding system - Google Patents

Abstract

The present invention relates to a package structure having an air gap and, more specifically, to a package structure comprising: a first substrate layer; a second substrate layer which is provided on the first substrate layer and has a signal line printed in a predetermined pattern at the center of the upper surface thereof and grounds printed in a predetermined pattern at one side and the other side of the signal line respectively; a third substrate layer which is provided on the signal line and the grounds; and a fourth substrate layer which is provided on the third substrate layer, wherein: an air gap is formed at the center of the third substrate layer; the top of the air gap is in contact with one side of the bottom of the fourth substrate layer; and the bottom of the air gap is in contact with the signal line.

Description

breeding system

The present invention relates to a smart incubation device, and more particularly, to a smart incubation device capable of classifying chicks according to chronological and biological ages.

The present invention relates to a breeding module, and more particularly, to a breeding module capable of maximizing the insulation performance of a chicken farm, facilitating temperature/humidity/noise management, and reducing breeding costs.

The present invention relates to a breeding system capable of comparing and analyzing environments in which livestock are raised, enabling shipment of products of higher quality than existing breeding environments, and continuously developing technology and marketability.

The present invention relates to a system for producing and supplying customized products that can be supplied after producing meat and eggs containing nutrients suitable for customers.

Conventional chick incubation method is to put eggs in an incubation basket and maintain the incubator temperature at a temperature optimized for hatching to incubate. I had a problem with my health.

Later, in order to solve this problem, a method of hatching eggs inside a hatcher where water and feed are supplied was developed, but in the case of this hatcher method, chicks with different chronological and biological ages Because it is located in one Hatcher and cannot be distinguished, there is still a big problem in the weight non-uniformity between chicks shipped on the same day, which is a major factor in reducing the profits obtained when raising chicks in farms and selling sex chickens. .

In detail, the delivery price of broilers is greatly reduced if they are out of the specified weight range. The weight of these broilers varies greatly according to the age at which chicks were born and consumed water and feed (chronological age) and the age until hatching in the incubator after entering the incubator (biological age). Despite this, in the case of a conventional hatching device that hatches eggs inside a hatcher, it is difficult to classify chicks according to chronological age and biological age.

Therefore, there is a need to develop a new type of incubation device capable of solving the above problems.

Since the conventional chicken farm was in the form of an open cage with an inside and outside open, it was difficult to create environmental conditions in which chickens could effectively grow.

Later, in order to solve this problem, a chicken breeding farm (no window cage) was developed in which the inside and outside of the breeding farm were completely sealed and separated. Due to structural and operational reasons, it is difficult to maintain insulation performance, a large amount of water is required for cooling, a large amount of fuel is used to operate a heater used to maintain a constant temperature inside the breeding farm, and the inside of the breeding farm is excessively heated. Due to the size, air circulation is not performed smoothly, so there is a problem in that there is a large temperature difference by location, such as between upper and lower floors, and a problem in which the chick is stressed due to noise generated when a large heater and fan are operated.

Therefore, the need for a new device capable of solving these conventional problems is emerging.

The quality of shipped products (livestock and eggs) differs depending on the environment in which livestock are raised (feed, feed mixing ratio, feed cycle, amount of feed, breeding temperature, breeding humidity, and breeding sunlight).

Therefore, research is being conducted to derive optimized breeding environment information that can obtain higher quality products by collecting conventional breeding environment information made in various ways.

However, since detailed breeding conditions are different for each farm that raises livestock, even if optimal breeding environment information is derived by collecting breeding data from a number of farms, the reliability of the derived optimal breeding environment information is low, making it difficult to actually use it. It is a difficult situation.

In detail, since each farm has different breeding farm structures, detailed breeding methods, and environmental conditions, information obtained without matching all of these conditions has a problem in that its value as comparative data is low.

Therefore, the need for a new breeding system capable of obtaining reliable breeding data and deriving optimized breeding environment information by comparatively analyzing the reliable breeding data is emerging.

Existing meat/egg supply has been carried out in the form of supplying to consumers through distributors that include online/offline wholesalers and retailers after the livestock of the breed selected by the company are raised based on the designed feed composition and then shipped.

In this system, since the supply company unilaterally determines the breed and breeding method of livestock, it is difficult to obtain meat/eggs in the form desired by the customer.

To explain in detail, each customer wants to purchase meat/egg suitable for their taste or health condition, but in the case of meat/egg sold, it is made in a mass production method of small breeds that can maximize the company's profits, so it is the type of meat that the customer wants. /The egg could not be purchased.

In addition, it is difficult to check whether the products sold contain nutrients suitable for oneself, making it difficult to select products that are suitable for oneself.

Therefore, there is a need to develop a new type of production and supply system capable of providing products suitable for customers.

The present invention was made to solve the above problems, and an object of the present invention is to provide a smart hatching device capable of classifying chicks shipped according to chronological age and biological age. .

The present invention has been made to solve the problems described above, and an object of the present invention is to provide a breeding module capable of creating an optimized breeding environment based on low construction cost and more perfect insulation performance.

The present invention has been made to solve the above problems, and an object of the present invention is to obtain reliable breeding environment information (feed mixing ratio, feed supply cycle, feed amount, breeding temperature, breeding humidity, breeding sunlight) It is to provide a breeding system that is.

In addition, it is to provide a breeding system capable of deriving optimized breeding environment information from which higher quality products can be obtained by comparing and analyzing breeding environment information.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a system capable of producing and supplying meat/eggs containing suitable nutrients according to the constitution and health condition of customers.

The smart incubation device of the present invention for achieving the above object is an incubation unit 100 in which an egg holder 110 in which eggs are mounted and a chick drop hole 120 in which chicks hatched from the egg fall are formed; a chick transfer unit 200 for transporting chicks that have fallen through the chick drop port 120; and a chick accommodating unit 300 in which the chick transferred through the chick transfer unit 200 is stored and a nutrient providing unit 310 is formed.

In addition, the first movement guide part 400 forms a path along which the plurality of hatching units 100 are transported, and the second movement guide unit 500 forms a path along which the plurality of chick accommodating units 300 are transported. ) It is characterized in that it includes any one or more of.

In addition, the egg holding portion 110 is characterized in that it includes an egg support lip 111 for supporting the egg to be mounted.

In addition, the nutrient supply unit 310 is characterized by comprising a feeder 311 in which feed is stored and a water supply container 312 in which water is supplied.

In addition, it is characterized in that it includes a hatch unit collecting unit 600 for collecting the hatch unit 100 that has separated from the first movement guide unit 400 .

In addition, a plurality of foreign matter discharge holes 320 are formed at the lower side of the chick accommodating part 300, and a foreign matter processing unit for processing foreign substances discharged through the foreign matter discharge hole 320 at the lower side of the chick accommodating part 300. (700) is characterized in that it is located.

In addition, it is characterized in that it includes a breeding farm transfer unit 800 for transferring the chick accommodation unit 300 separated from the second movement guide unit 500.

In addition, the breeding farm transfer unit 800 is arranged spaced apart from each other with a plurality of slide transfer units 810 obliquely disposed at the end of each of the chick accommodating unit moving guide units 500 and disjointedly from the end of the plurality of slide transfer units, and the slide transfer unit It is characterized in that it includes a transport belt 820 for collecting the chick accommodation unit 300 transported through and transporting it to the destination.

In addition, an input module (M) for providing the hatching unit 100 as the first movement guide unit 400 and providing the chick accommodating unit 300 as the second movement guide unit 500; It is characterized in that it includes an opening/closing means (D) positioned between the input module (M) and the first movement guide part (400) and the second movement guide part (500).

In addition, the input module (M) is characterized in that it includes a lifting module (M1) for moving the object in the height direction, and a transfer module (M2) for providing the object to the lifting module (M1).

In addition, the opening and closing means (D) is mounted on the housing (H) surrounding the first movement guide portion 400 and the second movement guide portion 500, the door housing (DA) in which the entrance and exit (D1) is formed, the door At least one of the door D2 hinged to the housing DA to open and close the inlet and outlet D1, the edge of the door D2 and one surface of the door housing DA facing the edge of the door D2 It is characterized in that it includes a permanent magnet formed.

In addition, the housing (H) includes a heat blocking wall (H2) formed between the entrance wall (H1) and the first movement guide part (400), and the entrance wall (H1) and the heat blocking wall (H2) It is characterized in that the opening and closing means (D) is formed facing each other and spaced apart.

In addition, it is characterized in that it includes a head conveyor (D3) located between the entrance wall (H1) and the heat blocking wall (H2) and operated individually.

The breeding module of the present invention for achieving the above object includes a breeding unit 100 forming a breeding space in which objects to be raised are accommodated; a heat insulation housing 200 in which an accommodation space 210 in which the breeding unit 100 is located is formed, and the breeding unit 100 is spaced apart from an inner surface and an air circulation passage is formed at an edge thereof; a blower 300 located on the accommodating space 210 and blowing wind so that the air in the accommodating space 210 moves along the air circulation passage; It is characterized in that it includes; environment control unit 400 for adjusting the environment of the receiving space (210).

In addition, the rearing unit 100 is located on the edge, the rearing unit frame 110 crossing each other to form a ventilation hole;

A ventilation network 120 coupled to the ventilation hole and having a plurality of holes formed therein;

It is characterized in that it includes; a separating net 130 coupled to the breeding unit frame 110 to separate the breeding space formed inside the breeding unit 100 into a plurality of holes and having a plurality of holes.

In addition, the breeding unit 100 is located on the lower side of the separation net 130, the foreign matter transfer means 140 for moving the foreign matter falling through the separation net 130; It is characterized in that it includes; a foreign matter collecting unit 150 in which the foreign matter transported through the foreign matter conveying means 140 is collected.

In addition, the heat insulating housing 200 includes a ventilation unit 410 that ventilates the air of the accommodation space 210 by receiving external air and discharging internal air; a temperature control unit 420 for controlling the temperature of the accommodation space 210; It is characterized in that it includes; humidity control unit 430 for controlling the humidity of the receiving space (210).

In addition, the ventilation unit 410 is perforated on the heat insulating housing 200, the outside air inlet 411 through which the outside air is introduced; a first opening/closing means 412 for opening/closing the outside air inlet 411; an outdoor air inlet duct 413 connected to the outdoor air inlet 411 and forming an air inlet; A bet outlet 414 formed on the heat insulation housing 200 and spaced apart from the outside air inlet 411 and through which internal air is discharged; It is characterized in that it comprises a; second opening and closing means 415 for opening and closing the bet outlet 414.

In addition, the temperature control unit 420 is installed on the outside air intake duct 413 and includes a cooling means 421 for evaporating water to lower the temperature of the passing air; and a heating means 422 installed on the air circulation passage and generating heat using electricity as a power source.

In addition, the air outlet of the blower 300 is positioned toward the outside air inlet 411, and the humidity control unit 430 for discharging water between the outside air inlet 411 and the blower 300 is It is characterized by being located.

In addition, it is characterized in that it includes; a light emitting means 500 located on one or more of the side and upper side of the breeding unit 100 and emitting light.

The breeding system of the present invention for achieving the above object is a breeding unit 100 forming a breeding space in which livestock are bred; A breeding environment creation unit 200 that creates different breeding environments for livestock separately bred in the breeding space; a breeding information acquisition unit 300 that acquires breeding environment information of livestock raised in the breeding space; a first quality measurement unit 400 that measures quality information by inspecting products shipped from the breeding unit 100; and a breeding information collection unit 500 that derives breeding environment information for each product quality by linking livestock breeding environment information with product quality information.

The breeding environment information includes at least one of nutrient ratio information of supplied feed, feed supply amount information, feed supply cycle information, temperature information of breeding space, humidity information of breeding space, CO2, NH3, and ventilation amount information of breeding space. It is characterized by doing.

The breeding environment creation unit 200 includes an information input unit 210 into which breeding environment information is input; It is characterized in that it includes; an environment creation unit 220 that adjusts the breeding environment of each breeding space according to the breeding environment information input from the information input unit 210.

In addition, the information input unit 210 includes an information storage unit 211 storing the breeding environment information for each product quality transmitted from the breeding information collection unit 500; an information display unit 212 that provides a manager with breeding environment information for each shipment product quality stored in the information storage unit 211; It is characterized in that it includes; a manager terminal 213 through which the manager inputs breeding environment information.

In addition, the breeding environment composition unit 200 generates comparative breeding environment information by collecting breeding environment information for products of the top 1% to 40% quality among the breeding environment information for each shipment product quality stored in the information storage unit 211. It is characterized in that it includes; breeding information generation unit 230 to.

In addition, the breeding environment information input to the information input unit 210 is the top 1% of the breeding environment information input through the manager terminal 213 and the breeding environment information by shipment product quality stored in the information storage unit 211. It is characterized in that it includes; breeding environment information in which a product having a quality of 30% to 30% is made, and comparative breeding environment information created in the breeding information generation unit 230.

In addition, the environment creation unit 220 includes a feed manufacturing unit 221 in which a plurality of feeds provided to the breeding space are made; It is characterized in that it includes; a feed supply unit 222 for separately supplying the feed made in the feed production unit 221 to the breeding space.

In addition, the environment creation unit 220 is characterized in that it includes a climate control unit 223 for controlling at least one of temperature, humidity, and amount of sunlight in the breeding space.

In addition, the first quality measurement unit 400 includes a transfer unit 410 that manages the transfer of products shipped from the breeding unit 100; a sample acquisition unit 420 in which slaughter or sample extraction of products transported through the transfer unit 410 is performed; It is characterized in that it includes; an evaluation unit 430 in which quality evaluation of the product slaughtered or the sample extracted by the sample obtaining unit 420 is performed.

In addition, the breeding target supply unit 600 for supplying livestock to the breeding unit 100; and a second quality measuring unit 700 that acquires quality information of the livestock supplied from the breeding target supplier 600 to the breeding unit 100.

In addition, the breeding information collecting unit 500 receives the quality information of livestock supplied from the second quality measurement unit 700 to the breeding unit 100 and derives breeding environment information according to the change in the quality of the supply target. to be characterized

To achieve the above object, the present inventors customized product production and supply system includes a customer terminal 100 into which customer information is input; an expert terminal 200 into which recommended nutrient information suitable for the customer's condition is input; Based on the customer information transmitted from the customer terminal 100 or the recommended nutrient information transmitted from the expert terminal 200, customized product information is provided to the customer terminal 100, and customized breeding is performed to produce the product selected by the customer. A central server 300 generating information; a breeding unit 400 that breeds livestock using the customized breeding information transmitted from the central server 300; an evaluation unit 500 in which products shipped from the breeding unit 400 are evaluated; and a supply unit 600 supplying a product evaluated by the evaluation unit 500 to a customer.

In addition, the central server 300 includes a customer information storage unit 310 in which customer information is stored; A necessary nutrient derivation unit 320 for deriving nutrient information necessary for the customer based on the customer information; A suitable product classification unit 330 for classifying products containing nutrients derived from the necessary nutrient derivation unit 320 among stored product information; a product information providing unit 340 that provides information on products classified by the suitable product classifying unit 330 to the customer terminal 100; Breeding information generation unit 350 for generating breeding information for producing a product selected by the customer; a breeding information providing unit 360 that provides the breeding information generated by the breeding information generating unit 350 to the breeding unit 400; It is characterized in that it includes.

In addition, the central server 300 provides verification information for providing livestock growth information collected while breeding livestock in the breeding unit 400 and evaluation information of the evaluation unit 500 to the customer terminal 100. It is characterized in that it includes; study (370).

In addition, the necessary nutrient derivation unit 320 includes a health status classification unit 321 that classifies the customer's condition into a healthy state or a non-healthy state in which health deteriorates based on customer information; a constitution classification unit 322 that classifies the customer's constitution by using the customer information classified as a health condition; a first required nutrient derivation unit 323 for deriving nutrient information necessary for the customer according to the constitution classified by the constitution classification unit 322; A second necessary nutrient derivation unit 324 for deriving information about nutrients to be avoided and information on necessary nutrients based on the customer's disease, medication status, blood pressure, etc. classified as having deteriorated health; characterized by including a.

In addition, the suitable product classification unit 330 classifies products containing recommended nutrients transmitted from the expert terminal 200;

In addition, the breeding unit 400 includes a breeding facility 410 in which livestock are raised; The feed manufacturing unit 420 where the feed is made; A feed supply unit 430 supplying the prepared feed to the breeding facility 410; a breeding management unit 440 that receives breeding information from the central server 300 and adjusts the composition ratio of the feed produced by the feed manufacturing unit 420; It is characterized in that it includes; a verification information collection unit 450 that collects feed data provided to livestock and takes a growth image of livestock.

In addition, the evaluation unit 500 includes a sample extraction unit 510 for extracting a sample of products shipped from the breeding unit 400; a suitability evaluation unit 520 for evaluating the suitability of a product by examining the sample extracted from the sample extractor 510; and an evaluation product classification unit 530 for providing products whose suitability has been recognized by the suitability evaluation unit 520 to the supply unit 600 and disposing of unsuitable products.

In addition, the supply unit 600 includes a packaging unit 610 in which shipped products are packaged; A transfer unit 620 that transfers the packaged product to the customer; It is characterized in that it includes; a transport information providing unit 630 that provides product shipping information and transport information to the customer terminal 100 .

The smart incubation device of the present invention has the advantage of being able to obtain sex chickens in the weight range desired by the breeder because chicks can be classified and shipped by chronological age and biological age.

In detail, it is possible to solve the problem of lower income of farm households that occurs when sex chickens are out of the contracted weight range.

In addition, since it is possible to provide sufficient water and feed to hatched chicks and transferred chicks, there is an advantage in promoting the development of chicks.

In addition, since the shell, mucus, and excrement generated when the chick is hatched can be immediately removed, there is an advantage in minimizing the problem of the chick being contaminated by the surrounding environment and getting sick.

In addition, since the hatching and shipment of chicks is performed by an automatic system, there is an advantage in minimizing the manpower required for maintaining and managing the hatchery.

In addition, since the opening and closing means of the hinge movement type are formed on the inlet side and the outlet side of the device, there is an advantage in minimizing wasted energy loss in the process of inserting and discharging the incubation unit and the chick accommodation unit.

In addition, since the plurality of opening and closing means are spaced apart, there is an advantage in solving the problem of lowering the degree of hatching of eggs when the temperature difference between the outside and the inside of the incubation device is large during the input process.

Through this effect, it is possible to improve feed conversion efficiency as well as economic benefits, and further reduce the burden of global warming.

The breeding module according to the present invention has an advantage of minimizing an area requiring a heat insulating material because the insulating housing is disposed in a form surrounding the breeding unit.

That is, by minimizing the area where the insulation material should be used, the construction cost of the farm is minimized.

In addition, since a circulation passage having an optimized flow path is formed along the edge of the insulated housing, there is an advantage in that air can be circulated with a minimum blower.

In detail, when the area in which air must be circulated is widened, the air circulation is not performed smoothly, which solves the problem of temperature difference by location.

In addition, since it is possible to immediately treat the excretion of the breeding target through the foreign matter transfer means, there is an advantage in preventing various diseases that occur when the breeding farm is not cleanly managed.

In addition, since it is sufficient to adjust only the temperature in a narrow area compared to when controlling the temperature of the entire breeding farm, there is an advantage in minimizing the cost used for temperature control.

In addition, since the heating cost can be minimized, there is an advantage in that the breeding farm can be operated even in winter, when the breeding farm could not be operated due to high heating costs in the prior art.

In addition, since electricity is used as an energy source to heat the breeding farm, greenhouse gas emissions can be reduced compared to when fossil fuels are used as an energy source, and noise generation can also be minimized.

The breeding system of the present invention has the advantage of being able to obtain various breeding environment information even in one breeding farm because it is possible to adjust the breeding environment of livestock separately bred in various ways.

In addition, since breeding environment information for each product quality can be provided to the manager, there is an advantage in that the manager can derive optimized breeding environment information by comparing and analyzing the breeding environment information in which high-quality products are produced.

In addition, since the breeding environment information in which high-quality products are made is used as reference data and the newly added breeding environment information is used as comparison data, the breeding environment information is naturally optimized in the process of repeated breeding.

Since it is possible to automatically generate comparative breeding environment information by collecting breeding environment information in which high-quality products are made, it has the advantage of minimizing the manpower required to create new breeding environment information.

Since the manager can check the quality change information of the livestock changed during the breeding process, there is an advantage in that the breeding environment information optimized for improving the quality of the supplied livestock can be derived.

The customized product production and supply system according to the present invention can provide customers with meat/eggs suitable for their health condition and constitution, and thus has the advantage of increasing customer satisfaction.

In addition, since growth information and verification information collected while raising livestock are provided to customers, there is an advantage in that customers can trust and eat the supplied meat/egg.

In addition, after classifying necessary nutrients and avoiding nutrients according to the health condition of the customer, products containing a lot of necessary nutrients are supplied, so there is an advantage that can assist the customer to lead a healthier life.

In addition, since it is provided to customers after confirming whether the product contains suitable nutrients through the evaluation process, the reliability of the product can be further increased.

1 is a perspective view showing a smart incubation device according to the present invention;

Figure 2 is a side view showing the smart incubation device of the present invention.

3 is a plan view and an embodiment showing an incubation unit of a smart incubation device according to the present invention.

Figure 4 is a plan view showing the chick receiving portion of the smart hatching device of the present invention.

5 to 6 are conceptual diagrams for explaining the smart incubation device of the present invention.

Figure 7 is a side view showing a new embodiment of the smart incubator of the present invention.

8 is a conceptual diagram for explaining a new embodiment of a smart incubator according to the present invention;

9 is a conceptual diagram for explaining the automation system of the smart incubator of the present invention.

10 is a conceptual diagram embodying the opening and closing means of the smart hatching device of the present invention.

11 is a conceptual diagram for explaining the head conveyor of the smart incubator of the present invention.

12 is a conceptual diagram for explaining that a heat blocking wall is formed in a housing of a smart hatching device according to the present invention.

Figure 13 is a perspective view showing the breeding module of the present inventors.

14 is a conceptual diagram showing a conventional breeding farm.

15 to 16 are conceptual views for explaining the internal structure of the breeding module of the present invention.

17 is a conceptual diagram showing that guide ribs are formed in the breeding module of the present inventors.

18 is a cross-sectional view showing a noise reduction unit formed at the edge of the blowing unit of the breeding module of the present inventors.

19 to 20 are conceptual views for explaining a modified form of the breeding module of the present invention.

21 is a block diagram showing the breeding system of the present inventors.

22 is a block diagram embodying the breeding environment creation unit and the first quality measurement unit of the breeding system of the present invention.

23 is a block diagram showing that a breeding target supply unit and a second quality measurement unit are added to the breeding system of the present invention.

24 is a block diagram embodying a breeding target supply unit and a second quality measurement unit of the breeding system of the present invention.

25 is a block diagram showing the overall configuration of the breeding system of the present inventors.

26 is a block diagram showing a customized product production and supply system according to the present inventors.

27 is a block diagram embodying the present inventors customized production and supply system.

Figure 28 is a block diagram for explaining the nutrient derivation method made through the required nutrient derivation unit.

Advantages and characteristics of the embodiments of the present invention, and methods for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, the smart incubation device 1000 according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing a smart incubation device 1000 according to the present invention, and FIG. 2 is a side view showing the smart incubation device 1000 according to the present invention.

Referring to FIGS. 1 and 2, the smart incubation device 1000 of the present invention includes an incubation unit 100 located on the upper side and where an egg to be hatched is located, and a chick transfer unit 200 located below the incubation unit 100 and a chick accommodating unit 300 located below the chick transfer unit 200 and receiving chicks transported through the chick transfer unit 200.

Referring to the plan view of the hatching unit 100 shown in FIG. 3 and the conceptual diagram of FIG. 5, the hatching unit 100 includes an egg holding unit 110 in which eggs are placed through a mesh or porous structure formed on the lower side and hatching unit 110. Since the drop hole 120 through which the chicks fall is formed, the chick hatched from the egg falls through the drop hole 120, so that the transfer unit 200 transfers the chicks who have fallen through the drop hole 120 to the receiving part ( 300) so that chicks born at a similar time can gather in one or more chick accommodating units 300.

At this time, the chick hatched from the egg naturally falls through the drop hole 120 in the process of moving, but in the case of a chick whose head is located below, it may fall through the egg holder 100, and the transfer unit 200 Of course, the chicks transferred through the transfer unit 200 naturally fall down at the point where the transfer unit 200 ends due to the inertia and gravity of the transfer unit 200 transporting the chicks and gather in the chick accommodation unit 300.

In addition, although the egg holder 110 and the drop hole 120 are shown as having the same cross-sectional area on the drawing, the chick can more easily fall through the drop hole 120 to the lower side where the transfer part 200 is located, The drop hole 120 may have a larger cross-sectional area than the egg holder 110, and in addition, an LED for attracting chicks is installed in the drop hole 120 so that the chick falls more quickly, or the drop hole 120 The surrounding surface may be coated with a low-friction material such as Teflon to reduce friction so that chicks adjacent to the drop 120 may slide and fall through the drop 120 .

In addition, the egg holder 110 includes an egg support lip 111 for more stably supporting the inserted egg 110 as shown in FIG. 3, and the egg support lip 111 is shown in the drawing. It may be formed at the corner as described, but it is not limited because it may be formed in various locations other than this.

And, as shown in FIG. 4, a nutrient supply unit 310 including a feeder 311 in which feed is stored and a water supply tube 312 in which water is supplied is formed on the accommodation unit 300, as shown in FIG. It was possible to immediately supply water and feed to the chicks transferred to (300).

At this time, water and feed may be supplied to the chick immediately, but if a newborn chick consumes water and feed immediately, a burden may be applied to the digestive system, so it is recommended that water and feed be supplied with a certain time difference, In a more correct form, water may be supplied after a certain time after birth to activate the chick's digestive system, and additional feed may be supplied to the chick whose digestive system is activated.

As described above, in order to supply water and feed to the chicks at a time difference, the nutrient supply unit 310 is located outside the housing unit 300, and a hole through which the chick can stick its head out is formed on the housing unit 300. may be formed.

In addition, the nutrient supply unit 310 is arranged at a certain distance from the initial position of the accommodation unit 300 where the chicks transferred through the transfer unit 200 gather so that the chicks can eat feed and water with a time difference, and the next accommodation unit ( 300) is inserted and it is recommended to be located on the side of the moved housing part 300.

In addition, although not shown in the drawing, an impact reducing portion made of a soft material such as a sponge is formed on the upper part of the support lip 111 in contact with the egg, so that damage to the egg generated during the transfer process can be minimized.

In addition, the chick drop hole 120 may have a square cross-sectional shape as shown in (a) of FIG. 3, but in addition to that, as shown in (b) of FIG. As shown in c), it may have a hexagonal cross-sectional shape.

In addition, a shock absorbing unit is formed on the conveying unit 200 to minimize the shock applied as the chick born from the egg falls, and the shock absorbing unit may be formed of a soft material capable of absorbing the shock.

In addition, as shown in (d) of FIG. 3, the smart hatching device of the present invention is inserted into the frame of the incubator 100 forming the chick drop hole 120, so that chicks falling through the drop hole 120 A shock absorbing unit (SA) capable of preventing injury from colliding with the frame of the hatching unit 100 forming the drop hole 120 may be further included.

At this time, the shock absorber (SA) may be simply attached to the inner wall of the frame of the incubator 100 forming the drop hole 120, but in addition to this, as shown in the drawing, the user can arbitrarily mount the structure In one embodiment, it may be in the form of an assembly in which a plurality of shock absorber units (SA-2) having fastening lips (SA-1) formed at edges thereof are coupled.

The shock absorber unit (SA-2) can absorb shock and at the same time has flexible characteristics, so it can be formed of rubber or silicone material that is easy to combine, and the surface is made of a soft material (sponge) that can absorb shock more effectively. A shock absorbing protrusion (SA-3) made of may be formed.

In addition, although not shown in the drawings, a cushion portion for minimizing the impact suffered by falling chicks may be formed on the upper side of the bottom surface of the chick accommodation unit 300 having a mesh or porous structure and made of plastic.

At this time, the cushion part should have a mesh shape corresponding to the bottom surface of the chick accommodating part 300 or a plate shape with a plurality of holes so that foreign substances can be discharged smoothly, and rubber, silicone, or sponge can be used to effectively absorb shock. It is recommended that it be made of any one material selected from among.

6 is a conceptual diagram for explaining the smart incubation device of the present invention.

Referring to FIGS. 1 and 6, the plurality of hatching units 100 move in a certain direction along the first movement guide unit 400, and the plurality of chick accommodating units 300 move in the first movement guide unit. Since it moves along the second movement guide part 500 located at the lower side of (400), the chronological age of chicks shipped in accordance with the schedule for inserting and replacing the hatching part 100 and the receiving part 300 by the manager and biological age differences can be adjusted.

In detail, when a predetermined number of incubation units 100 are inserted into the first movement guide unit 400 at regular intervals, chicks hatched at the same time are gathered in the housing unit 300, and water and feed are supplied at the same time Therefore, it is possible to ship chicks with a minimum chronological age difference.

In addition, when a plurality of incubation units 100 in which eggs that have stayed in the incubator for the same amount of time are mounted are simultaneously inserted into the first movement guide unit 400, the chronological age is not only the same in the same housing unit 300, but also Alternatively, chicks with minimal biological age differences may be collected.

At this time, the biological age represents the sum of the time in the incubation period when the egg stayed for 18 days before the incubation period and the time until hatching took place within the incubation period, and the hatching type of the chick (early hatching, normal hatching, late hatching) ) are classified, and the growth and quality of subsequent chicks vary according to the hatching type, so in the present invention, the manager can similarly control not only the chronological age but also the biological age of the released chick.

In addition, the chronological age difference and the biological age difference of the chicks shipped in the same chick accommodation unit 300 can be reduced or increased in response to the replacement interval of the chick accommodation unit 300, and this replacement interval can be arbitrarily determined by the manager. I never do that.

For example, replacing the receptacle every 6 hours would reduce the chronological or chronological/biological age to a difference of 6 hours (usually this time difference would be about 72 hours).

In addition, the insertion and transfer of the incubator 100 and the chick accommodation unit 300 may be performed manually by a manager, but may be automatically performed by various transfer means such as a belt type conveyor and a chain type conveyor. Although not limited, the hatching unit 100 and the housing unit 300 may be transported in the same direction as shown in FIG. 6, but hatching unit 100 and the housing unit 300 are transported in the same direction. Since the accommodation unit 300 located below the unit 100 is in a state where chicks are not contained, there is a problem in that the space cannot be effectively utilized, so the directions in which the hatching unit 100 and the accommodation unit 300 are transported are opposite to each other. direction may be made.

In addition, in the present smart incubation device 1000, an incubation unit collection unit 600 is formed at the end of the first movement guide unit 400, and eggs that have been hatched or have not been hatched for a period set by the manager. The remaining hatching unit 100 can be recovered.

At this time, eggs that have not hatched for a set period of time may remain on the hatching unit 100 collected by the hatching unit collection means 600, and in the case of such eggs, they may be separately classified as low-grade and used or discarded.

In addition, in the case of the hatching unit collecting means 600, as shown in FIG. 6, it may be a conveyor belt installed at the end of the chick transfer unit 200.

In addition, it is recommended that a foreign matter treatment unit 700 be formed below the chick accommodation unit 300 to grow chicks more healthily by removing egg shells, mucus, and chick excrement generated while chicks hatch. The furnace foreign matter processing unit 700 may be a conveyor belt.

In addition, the guide parts 400 and 500 may include a conveyor belt and a slide bar that can be pushed and moved while the incubator 100 and the accommodating part 300 are straddled.

7 is a side view showing a new embodiment of the smart incubator of the present invention.

Referring to FIG. 7 , a plurality of smart incubation devices 1000 according to the present invention may be vertically coupled to form one smart module.

In detail, by combining a plurality of smart incubation devices 1000 in the vertical direction, more chicks can be shipped in the same area.

And, in the case of such a smart incubation device, since it is difficult to manage by manpower, it is more recommended to be managed by an automated system. Hereinafter, a configuration for more effectively managing such a large smart incubation device will be described.

8 is a conceptual diagram showing a smart incubator module according to the present invention.

Referring to FIG. 8 , a breeding farm transfer unit 800 for shipping chicks may be formed at the end of the chick accommodation unit 300 where the chick accommodation unit 300 departs from the second movement guide unit, and the breeding farm transfer unit 800 ) is a plurality of slide transfer units 810 inclined at the end of each of the chick accommodation units 300, and a chick accommodation unit 300 that is displaced from the plurality of slide transfer units and transferred through the slide transfer unit 810 It may include a transport belt 820 that collects and transports them to a destination.

In detail, in the case of a module in which a plurality of smart incubation devices are stacked, it is difficult to manage by manpower, so chicks can be automatically shipped through the breeding farm transfer unit 800.

At this time, the breeding farm transfer unit 800 may include various power devices capable of collecting and transporting the chick accommodation unit 300, but since the power unit requires a lot of energy to operate, as shown in FIG. 8, the transfer unit 810 After collecting the chick accommodating parts 300 in a sliding manner by arranging them at an angle, the collected chick accommodating parts 300 can be transported to the destination through the transport belt 820.

9 is a conceptual diagram for explaining the automation system of the smart incubator according to the present invention, and FIG. 10 is a conceptual diagram embodying an opening and closing means.

Referring to FIG. 9, the smart incubation device 1000 of the present invention provides the incubator 100 as the first movement guide unit 400, and uses the chick accommodating unit 300 as the second movement guide unit 500. ), and an opening/closing means (D) positioned between the input module (M), the second movement guide part 400, and the second movement guide part 500. there is.

In detail, when a plurality of smart incubation devices are stacked, input the hatching unit 100 and the chick accommodation unit 300 to the first movement guide unit 400 and the second movement guide unit 500 located at various heights. Since there is a problem that is difficult to do, when the incubation unit 100 or the chick accommodation unit 300 is transferred through the transfer module (M2), the lifting module (M1) lifts the hatching unit 100 or the chick accommodation unit 300. After that, it can be inserted into the first movement guide part 400 or the second ear canal guide part 500 determined thereafter.

In addition, in order to maintain the internal temperature at a temperature suitable for hatching and growing chicks, the smart incubation device 1000 of the present invention is in a state where the inside and outside are isolated from the outside by stacking with the housing (H), so the entrance of the housing (H) A plurality of opening and closing means (D) that can be opened when the incubation unit 100 and the chick accommodation unit 300 are introduced or released must be formed on the side and the exit side.

Referring to FIG. 10, the opening/closing means D includes a door housing DA in which an inlet and outlet D1 is formed, a door D2 hinged to the door housing DA to open and close the inlet and outlet D1, and a door ( A permanent magnet (D4) formed on at least one side of the edge of D2) and one surface of the door housing (DA) facing the edge of the door (D) may be included.

In detail, the door D2 is hinged with the door housing DA so that the hatching unit 100 and the chick accommodation unit 300 can be opened by a moving force, and the opened door D2 is the hatching unit After the 100 and the chick accommodating portion 300 are introduced, they are closely attached to the door housing DA by a permanent magnet and can be more completely closed.

11 is a conceptual diagram for explaining a head conveyor for assisting insertion of the hatching unit and the receiving unit, and FIG. 12 is a conceptual diagram for explaining that a heat barrier wall is additionally formed in the housing.

11 and 12, since the movement time of the incubator 100 and the accommodating unit 300 moves one cell every several hours to tens of hours, a new hatching unit 100 and the accommodating unit 200 are synchronized with this. ) is added, since the insertion of the hatching unit 100 and the chick accommodation unit 300 through the lifting module M1 takes a lot of time, the first movement guide unit 400 and the second movement guide unit 500 ) The head conveyor (D3) is formed on the side, and the first movement guide part 400 and the second It can be quickly inserted into the movement guide part 500 at the same time.

In detail, by preparing the incubation unit 100 and the chick accommodation unit 300 on the head conveyor D3 and then inserting them into the first movement guide unit 400 and the second movement guide unit 500 at the same time, It minimizes problems such as loss of energy due to prolonged opening of the entrance that may occur when the hatching unit 100 and the chick accommodation unit 300 are inserted using only the lifting module M1.

In addition, when the opening and closing means (D) coupled to the housing (H) is opened, there is a problem that temperature congestion occurs in the egg in the existing incubation unit (100), so on the housing (H), the inlet wall (H1) and the first It is recommended that an additional heat shielding wall H2 be formed between the movement guide units 400 .

In detail, as shown in FIG. 12, a pair of opening and closing means (D) are disposed facing each other in the entrance wall (H1) and the heat blocking wall (H2), so that the external space and the incubator 100 with a large temperature difference And the inner space of the housing (H) in which the receiving portion 300 is located does not directly exchange heat with each other.

In addition, when the inlet wall (H1) and the heat barrier wall (H2) are formed on the housing (H), the incoming eggs can be put after preheating between the external space with a large temperature difference and the internal space of the housing (H), There is also an advantage that can solve the decrease in hatchability of eggs caused by large temperature changes.

In addition, the head conveyor D3 may be formed between the entrance wall H1 and the heat barrier wall H2, but as shown in FIG. 12, it is additionally formed on the side of the first movement guide part 400, The movement of the incubator 100 and the receiving part 300 supplied through the head conveyor located between the wall H1 and the heat blocking wall H2 is made faster, and the opening and closing formed in the heat blocking wall H2 The opening time of the means (D) can be minimized.

Also, although not shown in the drawings, the entrance wall H1, the heat blocking wall H2, the head conveyor D3, and the lifting module M1 may be equally formed on the opposite side of the housing H.

The present invention is not limited to the above embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

Advantages and characteristics of the embodiments of the present invention, and methods for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, the breeding module 1000 according to the present invention will be described with reference to the accompanying drawings.

13 is a perspective view showing the breeding module 1000 of the present invention, and FIG. 14 is a conceptual diagram showing a conventional breeding farm.

Referring to FIG. 13, in the breeding module 1000 of the present invention, the breeding unit 100, which forms a breeding space in which objects to be raised are accommodated, is located on the inner floor of a heat insulating housing 200 capable of blocking heat exchange by combining a heat insulating material. Therefore, it is possible to minimize the cost and energy required to optimize the breeding environment of chicks.

If described in detail with reference to the conventional breeding farm shown in FIG. 14, the conventional chicken breeding farm 10 was a form in which chicks were released and raised inside the breeding farm or raised by installing a multi-layer cage.

In such a conventional breeding farm, in order to minimize heat exchange between the inside of the chicken breeding farm 10 and the outside air, the insulation material 6 must be coupled to the entire outer wall 5 of the chicken breeding farm 10, and the internal space of the large breeding farm is heated. In order to do this, there is a problem in that the heater 7 using fossil fuel must be operated frequently, and a large temperature difference occurs between the air between the upper and lower floors or by location because the heat is not spread evenly in a wide space.

In detail, since the insulation material (6) must be coupled to the entire outer wall (5) including the roof of the wide chicken farm (10), a lot of construction costs are required, and the heater (7) used for fossil fuel must be operated for a long time. Because of this, problems such as cost increase/smoke generation and noise generation/greenhouse gas emission have occurred, and since it is difficult to smoothly circulate the air located in the wide chicken farm 10 internal space, the chicken farm 10 inner area A large temperature difference occurred between (1, 2, 3, 4), causing a problem that chicks located in areas with high temperatures died.

Therefore, in the present invention, the breeding unit 100 where chickens are raised is wrapped with the insulating housing 200, minimizing the space required for the insulation installation area and breeding environment.

In other words, the present invention does not use the building itself built as a breeding farm as in the prior art, but since the breeding module 1000 of the present invention is installed in a single or plural number inside the breeding farm, breeding proceeds, so that the area where the insulation must be installed can be minimized to the surface of the insulated housing 200, and the area requiring temperature control and air circulation can also be minimized to the accommodation space 210 inside the insulated housing 200 where the breeding unit 100 is located, so even with less energy It is possible to easily create an optimized breeding environment.

At this time, the optimized breeding environment refers to temperature / humidity / ventilation conditions in which chicks can quickly grow into chickens of a desired weight. Hereinafter, referring to the drawings, the detailed configuration of the breeding module 1000 for creating an optimized breeding environment is described. let me explain

15 to 16 are conceptual diagrams for explaining the internal structure of the breeding module 1000 of the present invention.

Referring to FIGS. 13 and 15, the breeding unit 100 is located at the edge, and the breeding unit frame 110 intersects with each other to form a ventilation hole, and a ventilation network coupled to the ventilation hole and having a plurality of holes ( 120), and a separation net 130 coupled to the breeding unit frame 110 to divide the breeding space formed inside the breeding unit 100 into a plurality of parts and having a plurality of holes formed therein.

In detail, since the breeding unit 100 is a place where objects raised such as chickens are separately accommodated, as shown in FIG. 13, a breeding unit frame of an enclosure structure in which a breeding space is formed by crossing a plurality of bars 110) is formed, and a plurality of breeding unit frames 110 are cross-coupled and a ventilation network 120 is coupled to the hole formed to restrict the breeding target located inside from going out, and at the same time, air is supplied to the breeding unit 100 ), and as shown in FIG. 3, by combining a plurality of separation nets 130 with the breeding unit frame 110, the breeding space is partitioned in a form optimized for breeding targets and breeding purposes.

At this time, as shown in FIG. 15, the separation network 130 is erected vertically and divides the breeding space at the same height, and the vertical separation network 131 spreads in the left and right or front and rear directions to divide the breeding space by height. It may include a horizontal separation network 132, and it is recommended that the horizontal separation network is formed with a plurality of holes for foreign matter treatment.

In addition, a foreign material transfer unit 140 for moving falling foreign materials is located below the horizontal separation network 132, and transfers the fallen foreign materials (dirt) to the foreign material collection unit 150, and the foreign material transfer unit 140 may be a conveyor belt in one embodiment.

In detail, when the foreign material transport means (conveyor belt) operates according to the time set by the manager, the foreign material moves along the rotating conveyor belt to the end of the conveyor belt, and the foreign material moved to the end of the conveyor belt moves along the conveyor belt. It is separated from the end point and goes into the bowel movement located on the lower side.

In addition, the breeding module 1000 of the present invention is provided inside the insulated housing 200, and the environment control unit 400 controls the environment (temperature / humidity / ventilation) of the accommodation space 210 inside the insulated housing 200 And, it may include a blower 300 that circulates air to more smoothly control the internal environment of the accommodation space 210.

At this time, the environment control unit 400 is a ventilation unit 410 that ventilates the air in the accommodation space 210 by receiving external air and discharging internal air, and a temperature control unit that controls the temperature of the accommodation space 210 It is divided into 420 and the humidity control unit 430 for controlling the humidity of the accommodation space 210, and hereinafter, this configuration will be described in more detail.

Ventilation unit 410 is configured to receive outside air and discharge internal air to the outside so that fresh air can always be located inside, and is perforated on the insulation housing 200 to allow outside air to flow in. The inlet 411, the first opening/closing means 412 for opening and closing the outdoor air inlet 411, the outdoor air inlet duct 413 connected to the outdoor air inlet 411 and forming a passage through which air flows, and a heat insulation housing ( 200) It may include a bet outlet 414 spaced apart from the outside air inlet 411 and discharging internal air, and a second opening/closing means 415 for opening and closing the bet outlet 414.

In detail, when ventilation is required, as shown in FIG. Internal air is discharged through the bet outlet 414 by the flow, and outside air can be introduced through the outside air inlet 411 as much as the air discharged to the bet outlet 414.

At this time, when the blower 300 is disposed on the side of the outside air inlet 411, since air is sucked into the outside air inlet 411 by the force of the blower 300 releasing air, ventilation is more efficient. can be done smoothly.

In addition, after the air circulation is completed, the first opening and closing means 412 and the second opening and closing means 415 close the outside air inlet 411 and the inside outlet 414, as shown in FIG. block the inflow and outflow of internal air.

The first opening and closing means 412 and the second opening and closing means 415 may include various devices capable of selectively opening and closing the outside air inlet 411 and the inside outlet 414, respectively. In one embodiment, open and close It may include a plate used for and a power device such as a motor that hinges the plate with rotational force, but it is not limited because it may include various other devices.

The temperature control unit 420 is installed on the outside air inlet duct 413, and is installed on the cooling means 421 for evaporating water to lower the temperature of the passing air, and the air circulation passage, and heats with electricity as a power source. It may include a heating means 422 for generating.

At this time, the cooling means 421 may include various devices capable of cooling the air introduced through the outside air intake duct 413, and in one embodiment, a plurality of holes are formed to allow air to pass through. It may include a cooling plate forming a, and a spraying device for spraying water on the surface of the cooling plate.

In detail, the spray device sprays water on the surface of the cooling plate to lower the temperature of the cooling means 421, so that the air introduced through the cooled means 421 also exchanges heat with the cooling means 421. It was allowed to cool through the process.

In addition, the heating means 422 may include various devices capable of heating the air circulating inside the accommodation space 210, and in one embodiment, may include a heating plate that discharges heat when electricity is applied, , The heat transfer plate may be a porous structure in which a plurality of holes through which air passes are formed.

In detail, while air passes through the holes formed in the heat transfer plate, heat emitted from the heat transfer plate is absorbed and heated.

At this time, the heat transfer plate is the inlet side of the breeding unit 100 through which the air circulated by the blowing unit 300 flows into the breeding unit 100 and the breeding unit 100 through which the air passing through the breeding unit 100 is discharged. ) Even if it is located on one or more of the outlet sides, sufficient heating can be performed, but in consideration of the fact that the temperature of the air is lowered in the circulation process and that the air flowing into the breeding unit 100 should not be excessively heated, the breeding unit ( 100) It is recommended that more heat transfer plates be installed on the outlet side of the breeding unit than on the inlet side.

In addition, when cooling is performed through the cooling means 421, the outside air inlet 411 and the inside outlet 414 are opened as shown in FIG. 3, and when heating is performed through the heating means 422, as shown in FIG. As shown, the outdoor air inlet 411 and the air outlet 414 must be closed so that effective cooling and heating can be achieved.

In addition, the humidity control unit 430 may include various water spray devices capable of regulating the humidity of the accommodation space 210 by discharging water, and a blower unit through which air is discharged so that the sprayed water can spread more effectively ( 300) is recommended.

In addition, a light emitting means 500 for emitting light may be further formed on the upper side of the breeding unit 100 .

In detail, since the brightness of light has a great influence on the biorhythm of the breeding subject, the manager uses the light emitting means 500 to optimize the brightness of the breeding unit 100 to generate a biorhythm conducive to growth. It is possible to adjust the brightness.

At this time, the light emitting means 500 is located on the upper side of the breeding unit 100 and is spaced apart from the inner surface of the heat insulation housing 200 so that a plurality of light emitting means 500 may be spaced apart below the plate forming a circulation passage, the number and arrangement of the light emitting means 500 is not limited because it may be variable according to the design.

In addition, a closing means P2 may be formed on the upper side of the plate P1 to close the air circulation passage AL located on the upper side of the plate so that air flows only through the blower 300, and the blower 300 may be mounted inside the closing means (P2).

In addition, a filter (F) capable of filtering foreign substances mixed in the air is formed on the outlet side of the breeding section 100 where the air passing through the breeding section 100 is discharged, so that contamination occurs when foreign substances move with the air. It is possible to minimize the phenomenon, and a sterilizer may be located after the filter (F) to sterilize the air passing through the filter (F).

17 is a conceptual diagram showing that guide ribs are formed in the breeding module of the present inventors.

In the breeding module 1000 of the present invention, the breeding unit 100 is spaced apart from the inner surface (front, rear, and top) of the insulated housing 200, and the air circulation passage through which air moves to the edge of the insulated housing 200 ( AL) is formed.

At this time, forming the air circulation passage AL enables the air to stably circulate the air in the accommodation space 210 using the minimum blower 300 by having a standardized movement, and the air circulation is smooth. This is to minimize an increase in the temperature difference between regions due to the formation of a space where no space is formed.

The movement of air through the air circulation passage AL is performed in the order of the upper air circulation passage AL-1, the front air circulation passage AL-2, the breeding unit 100, and the rear air circulation passage AL-3. In order to assist such air circulation, it is recommended that a guide lip 600 be formed on the inner surface of the heat insulating housing 200 to assist air circulation.

At this time, the guide lip 600 guides the moving direction of the circulating air to gradually change, so that the air can move without being stagnant in each circulation passage (AL) connection portion having an angular shape, and the insulation housing ( 200) and a first guide lip 610 that guides the air moving from the rear to the front of the upper air circulation passage AL-1 to the front air circulation passage AL-2, and the front air A second guide lip 620 that guides the air introduced into the circulation passage AL-2 into each layer of the breeding unit 100 separated into a plurality of layers by the separation network 130, and a heat insulating housing ( 200) may include a third guide lip 630 that guides air passing through the breeding unit 100 to rise.

And, in the case of the second guide ribs 620, a plurality may be formed to distribute and inject air into each layer of the separated breeding unit 100, and the plurality of second guide ribs 620 have a length lower than the upper side Since is formed long, it is possible to minimize the problem that less air is introduced into the lower layer of the breeding unit 100 than the upper layer of the breeding unit 100 due to a decrease in speed in the course of air circulation.

In addition, the guide lip 600 may have a flat plate shape, but one surface in contact with air may have a curved shape so that the air movement direction guide is made in a more gentle shape.

18 is a cross-sectional view showing that the noise reduction unit is formed at the edge of the blowing unit of the breeding module of the present invention.

Referring to FIGS. 14 and 18 , a noise reduction unit 700 is positioned at the edge of the blower 300, and noise generated while the blower 300 is operated can be minimized.

In detail, the blower 300 is a device in which a motor rotates a fan to create air flow, and noise is generated by the operation of the motor and friction between the fan and the air, and this noise hinders the growth of breeding targets. Since it acts as a factor, in the present invention, the noise reduction unit 700 capable of absorbing and damping vibration covers the blower 300 so that the noise generated when the blower 300 operates is transmitted to the breeding target and does not hinder growth. it did

At this time, the noise reduction unit 700 surrounds the side surface of the blower unit 300 and includes a noise reduction housing 710 having a liquid accommodating space formed therein, a vibration absorbing material 720 accommodated in the liquid accommodating space, and , A vibration damping groove 730 formed on an inner surface of the noise reducing housing 710 may be included.

In detail, since the strength of noise (sound waves) is weakened when they are scattered and absorbed during the transmission process, in the present invention, some of the sound waves spreading out through the side edge of the blower 300 collide with the vibration damping absorber 730 Sound waves that are scattered and transmitted to the noise reduction housing 710 can be absorbed while passing through the liquid vibration absorbing material 720 .

19 to 20 are conceptual diagrams for explaining a modified form of the breeding module 1000 of the present invention.

Referring to FIG. 19, a first form in which a plurality of breeding units 100 are accommodated on one heat insulating housing 200 and a space in which a manager can move is formed between the two breeding units 100, and FIG. As described above, the two breeding units 100 may include a second form combining a plurality of breeding modules 1000 of the first form accommodated in one heat insulating housing 200.

In addition, although only two modified forms are shown on the drawing, the breeding module 1000 of the present invention may be modified in various forms by a designer, so it is not limited thereto.

In addition, the rearing module 1000 of the present invention may circulate internal air in the longitudinal direction of the breeding unit 100 in which the breeding unit 100 is extended, as shown in FIGS. 19 to 20, but the breeding unit 100 It is possible to minimize the gentle path of air by circulating air in a direction perpendicular to the direction in which the is extended.

In detail, when the air circulation path is long, the air circulation is not smooth, so the temperature difference between the upper and lower sides increases.

In addition, as described above, when the air circulation path is formed short, the air circulation is more smooth, so it is possible to solve the problem of air being stagnant and polluted in some areas, and ventilation is also performed more quickly. Of course, the energy consumed to compensate for the heat released in the process can also be minimized.

In addition, since this short air circulation path is a direction crossing the operating direction of the feed supply unit and the operating direction of the foreign matter transfer means 140 installed in the direction in which the breeding unit 100 is extended, In addition to minimizing the scattering of the feed, there is an advantage in that the odor emitted from foreign substances can be removed by providing it to the washer more quickly.

The present invention is not limited to the above embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

Advantages and characteristics of the embodiments of the present invention, and methods for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, the breeding system 1000 according to the present invention will be described with reference to the accompanying drawings.

21 is a block diagram showing the breeding system of the present invention.

Referring to FIG. 21, the breeding system of the present invention includes a breeding unit 100 that forms a breeding space in which livestock are raised, and a breeding environment creation unit 200 that creates different breeding environments for livestock separately bred in the breeding space. A breeding information acquisition unit 300 that acquires breeding environment information of livestock raised in the breeding space, and a first quality measuring unit 400 that acquires quality information by inspecting products shipped from the breeding unit 100 and a breeding information collection unit 500 that derives breeding environment information for each product quality by linking livestock breeding environment information with product quality information.

In detail, the quality of breeding livestock changes according to the breeding environment (nutrient ratio in feed, feed supply amount, feed supply cycle, temperature of breeding space, humidity of breeding space, amount of sunlight in breeding space).

Therefore, in the present invention, the quality of products (livestock, livestock eggs) shipped from the first quality measurement unit 400 is measured, and livestock are raised according to the quality of products shipped from the breeding information collection unit 500. By classifying environmental information, it is possible to derive optimized breeding environment information for managers to obtain higher quality products.

In order to classify breeding environment information according to quality, since livestock must be bred in at least two ways, the breeding unit 100 must be able to separate the spaces in which livestock are raised into two or more, and each of the separated breeding spaces must have a difference in one or more of the components of the supplied feed, feed supply type, temperature/humidity/sunlight.

In other words, by comparing the quality differences of livestock raised in different breeding spaces, it is possible to determine in which method a better quality product can be obtained when breeding livestock.

Hereinafter, detailed components constituting the breeding system 1000 will be described in detail.

22 is a block diagram embodying the breeding environment creation unit 200 and the first quality measuring unit 400 of the breeding system 1000 according to the present invention.

Referring to FIG. 22, the breeding environment creation unit 200 includes an information input unit 210 into which breeding environment information is input, and an environment that adjusts the breeding environment of each breeding space according to the breeding environment information input from the information input unit 210. A composition unit 220 may be included.

In detail, since two or more breeding environment information that can be compared with each other are required to derive more advanced breeding environment information, when two or more breeding environment information is input through the information input unit 210, the environment control unit 220 It is possible to manage the divided breeding space according to different breeding environment information.

At this time, the different breeding environment information may be information having a difference in one or more of the nutrient ratio of the feed, the feed supply amount, the feed supply cycle, the temperature of the breeding space, the humidity of the breeding space, and the amount of sunlight in the breeding space.

In addition, the information input unit 210 includes an information storage unit 211 storing breeding environment information for each shipment product quality transmitted from the breeding information collection unit 500, and shipment product quality stored in the information storage unit 211. It may include an information display unit 212 for providing information on a specific breeding environment to a manager, and a manager terminal 213 for allowing the manager to input breeding environment information.

In detail, the more comparison data there is, the more reliable results can be derived, so the breeding environment information for each product quality derived from the breeding information collection unit 500 is stored in the information storage unit 211 so that it can be used continuously. .

In addition, in order to derive or generate optimized breeding environment information, the manager should be able to more easily compare breeding environment information by quality of shipped products stored in the information storage unit 211, so that the information display unit 212 Environmental information can be compared in the form of a table or graph and displayed to the manager.

In addition, new breeding environment information created by the manager referring to tables and graphs displayed through the information display unit 212 is input to the manager terminal 213 so that the new breeding environment information can be updated.

When new breeding environment information is updated, breeding environment information in which low-quality products are made is excluded from among a plurality of previously used breeding environment information, so that a certain number of breeding environment information can always be applied to the breeding farm.

In addition, the environment creation unit 220 includes a feed manufacturing unit 221 for producing a plurality of feeds provided to the breeding space, and a feed supply unit for separately supplying the feed produced in the feed manufacturing unit 221 to the breeding space ( 222), and a climate control unit 223 that controls at least one of temperature/humidity/sunlight in the breeding space.

In detail, the mixing ratio (nutrient ratio) of the feed is adjusted according to the breeding environment information input from the feed manufacturing unit 221, and the feed made by the feed supply unit 222 can be supplied to the set breeding space.

In addition, the amount/cycle of the feed supplied by the feed supply unit 222 can be additionally adjusted according to breeding environment information.

In addition, the temperature/humidity/ventilation of the breeding space can be controlled by adjusting the operating time and operating intensity of the temperature controller, humidity controller, light emitting device, etc. provided in the breeding unit 100 in the climate control unit 223. Ventilation is for controlling CO2, NH3, etc.

In addition, the breeding environment creation unit 200 collects breeding environment information for products of the top 1% to 40% quality among the breeding environment information for each shipment product quality stored in the information storage unit 211 to obtain comparative breeding environment information. It may further include a breeding information generation unit 230 to generate.

In detail, if the breeding environment information applied to the breeding department is a small number (2 to 10), the manager can directly create the breeding environment information and then input it through the manager terminal. When dog breeding environment information needs to be applied, since it is difficult for the manager to directly create all breeding environment information, in the present invention, the breeding information generator 230 creates new breeding environment information for comparison and provides it to the manager will be.

At this time, the breeding environment information generated by the breeding information generation unit 230 is used as comparative breeding environment information, and is applied to the breeding unit 100 together with the optimized breeding environment information input through the manager terminal 213 to create It can be used as reference information for comparison or reinforcement to determine the excellence of the optimized breeding environment information.

In addition, the first quality measurement unit 400 includes a transfer unit 410 that manages the transfer of products shipped from the breeding unit 100, and a sample acquisition unit 420 that slaughters or extracts samples of the transferred products. , An evaluation unit 430 in which quality evaluation of the meat slaughtered or extracted by the sample obtaining unit 420 is performed.

In detail, the products to be shipped are transferred to the sample acquisition unit 420, which is processed into a form suitable for evaluation through the transfer unit 410, and the products processed in the evaluation unit 430 are evaluated in various grades according to classification criteria. It will do.

In this case, the sample acquisition unit 420 may include a slaughterhouse and a slaughterhouse when the product to be shipped is livestock, and may include an egg collection site or a packaging factory when the product to be shipped is eggs.

23 is a block diagram showing that a breeding target supply unit 600 and a second quality measuring unit are added to the breeding system 1000 of the present invention.

Referring to FIG. 23, the breeding system 1000 of the present invention includes a breeding target supply unit 600 for supplying livestock to the breeding unit 100, and the quality of livestock supplied from the breeding target supply unit 600 to the breeding unit 100. It may further include a second quality measurer 700 that obtains information.

In detail, since the optimized breeding environment information for obtaining a product of better quality is different depending on the initial quality of livestock provided to the breeding farm 100, in the present invention, the breeding information collection unit in the second quality measuring unit 700 By providing the initial quality information of the livestock in 500, the breeding information collection unit 500 enables the breeding environment information to be derived according to the change in the quality of the supply target.

In addition, the manager compares the breeding environment information according to the change in the quality of the supply target to create suitable breeding environment information according to the initial quality of livestock.

At this time, the breeding environment information according to the change in the quality of the supply target is the difference between the initial quality of the livestock measured by the second quality measurement unit 700 and the quality measured by the first quality measurement unit 400 after breeding. It is a classification of environmental information, and breeding environment information with a higher quality can be selected and used as excellent breeding environment information.

24 is a block diagram embodying the breeding subject supply unit 600 and the second quality measurement unit 700 of the breeding system 1000 according to the present invention.

Referring to FIG. 24, the breeding target supply unit 600 includes a development unit 610 in which livestock eggs are maintained at a temperature suitable for hatching and eggs are turned (rotating eggs), and eggs that have passed through the development unit 610 It may include an incubation unit 620 to be hatched, and the second quality measurement unit 700 includes an egg quality information acquisition unit 710 that measures the quality of eggs on the developing unit 610 and eggs hatched in the hatching unit 620. It may include an incubation target quality information acquisition unit 720 that measures the quality of livestock.

In detail, in the case of livestock breeding through eggs, information on breeding environments optimized for obtaining high-quality products may be different depending on the quality of eggs and the quality of offspring born after hatching, so the egg quality information acquisition unit 710 and The quality of eggs measured by the hatching target quality information acquisition unit 720 and the quality of offspring hatched from the eggs are provided to the breeding information collection unit 500, so that more detailed breeding environment information for each quality of supply target can be derived. it was made to

In addition, through more detailed breeding environment information by supply target quality, managers can create optimized breeding environment information according to the quality of eggs and the quality of offspring hatched from eggs.

25 is a block diagram showing the overall configuration of the breeding system 1000 of the present invention.

The breeding information acquisition unit 300 may obtain breeding environment information for each breeding space by receiving information from the breeding environment creation unit, but besides this, a configuration for acquiring breeding environment information is installed in each breeding space to obtain information. You may.

The breeding information acquisition unit 300 includes a feed nutrient information acquisition unit 310, a feed supply amount information acquisition unit 320, a feed supply cycle information acquisition unit 330, a temperature information acquisition unit 340, The humidity information acquisition unit 350 and the ventilation information acquisition unit 360 may be embodied, the temperature information acquisition unit may include various temperature sensors, and the humidity information acquisition unit 350 may include all of the various humidity sensors. can

In addition, the breeding information collection unit 500 includes a first breeding information collection unit 510 that derives breeding environment information for each quality of the shipped product, and a second breeding information collection unit that derives breeding environment information according to a change in the quality of the supply object ( 520) may be included.

For example, the first breeding information collection unit 510 combines the breeding environment information used for each product with the products classified into grades 1 to 10 in the first quality measuring unit 400, so that the manager can This is to make it possible to check breeding environment information.

In addition, the second breeding information collecting unit 520 classifies the products classified as 1 to 10 in the second quality measurement unit 700 and 1 to 10 in the first quality measurement unit 400. After deriving the changed grade change information based on the grade difference of the product grade, the grade change width information and breeding environment information are combined for each product, so that the manager can check the breeding environment information according to the product grade change.

In addition, the incubation unit 620 includes an egg holder located on the upper side and in which eggs to be hatched are located, a chick transfer unit located below the egg holder, and a chick transfer unit located below the chick transfer unit and transported through the chick transfer unit. It may include a chick accommodating portion in which chicks are accommodated.

In detail, since the egg holding part through which the eggs are held and the falling hole through which the hatched chicks fall are formed through the mesh or porous structure formed on the lower side of the egg holder, the chick hatched from the egg falls through the falling hole, The chicks that have fallen from the transfer unit through the drop port are transferred to the receiving unit so that chicks born at a similar time can gather in the chick receiving unit.

And, the chicks gathered in the chick receiving unit can be supplied and used to the breeding unit 100.

When the egg incubator 620 has the above structure, it is possible to supply chicks of similar quality born at the same time to the breeding unit 100, so that the reliability of breeding environment information derived through the system can be further increased.

In addition, the chick hatched from the egg naturally falls through the drop hole in the process of moving, but in the case of a chick whose head is located below, it may fall through the egg holder, and the chick transferred through the transfer unit is at the end of the transfer unit. Of course, they naturally fall down due to the transported inertia and gravity and gather in the chick accommodation unit.

In addition, although the egg holder and the drop hole may have the same cross-sectional area, the drop hole may have a larger cross-sectional area than the egg holder so that the chick can more easily fall through the drop hole to the lower side where the transfer unit is located. An LED for attracting chicks is installed on the drop hole to make the chick fall faster, or the surface around the drop hole is coated with Teflon to reduce friction so that chicks adjacent to the drop hole slide and fall through the drop hole. .

In addition, the egg holding portion includes an egg support lip for more stably supporting an inserted egg, and the egg support lip may be formed at a corner, but may be formed at various locations other than this, so it is not limited thereto.

In addition, a nutrient supply unit including a feeder for storing feed and a water supply tube for supplying water is formed on the accommodation unit so that water and feed can be immediately supplied to chicks transferred to the accommodation unit.

In addition, an impact reducing portion made of a soft material such as a sponge is formed on the upper part of the support lip in contact with the egg, so that damage to the egg generated during the transfer process can be minimized.

In addition, the chick drop port may have a square cross-sectional shape, but may also have a circular cross-sectional shape or a hexagonal cross-sectional shape.

In addition, the egg holding unit may further include a shock absorber capable of preventing a chick falling through the falling hole from being injured by colliding with the frame of the egg holding portion forming the falling hole by being inserted into the frame.

At this time, the shock absorber may be simply attached to the inner wall of the frame of the egg holder that forms the drop hole, but in addition to this, it may have a structure that can be mounted arbitrarily by the user, and in one embodiment, a plurality of fastening lips are formed at the edge. It may be in the form of an assembly in which four shock absorber units are combined.

The shock absorbing unit unit can absorb shock and at the same time has flexible characteristics, so it can be formed of rubber or silicone material that is easy to combine. may be formed.

In addition, a cushion portion may be formed on the upper side of the bottom surface of the chick accommodating unit having a mesh or porous structure to minimize the impact of falling chicks.

At this time, the cushion part should have a mesh shape corresponding to the bottom surface of the chick accommodation unit or a plate shape with a plurality of holes so that foreign substances can be discharged smoothly, and any one selected from rubber, silicone, and sponge can effectively absorb shock. It is recommended that it be made of one material.

Since the plurality of egg holders move in a certain direction along the first movement guide, and the plurality of chick accommodating units move along the second movement guide located below the first movement guide, the manager can use the egg holder and It is possible to adjust the difference in chronological age and biological age of released chicks in response to the schedule of inserting and replacing the housing unit.

In detail, when a predetermined number of egg holders are inserted on the first moving guide unit at regular intervals, chicks hatched at the same time are gathered in the receiving unit and are supplied with water and feed at the same time, thereby minimizing the chronological age difference. It is possible to ship chicks.

In addition, when a plurality of egg holders in which eggs that have stayed in the incubator for the same time are inserted on the first movement guide unit, chicks having the same chronological age and minimizing the biological age difference are gathered in the same receiving unit will be.

At this time, the biological age represents the time from the time of staying in the incubator to the time of hatching, and according to this biological age, the hatching type (early hatching, normal hatching, late hatching) of the chick is classified, and corresponding to the hatching type Since the growth and quality of the subsequent chicks are different, the present invention allows the manager to similarly control not only the chronological age but also the biological age of the released chicks.

In addition, the chronological age difference and the biological age difference of chicks shipped in the same chick accommodation unit can be reduced or increased in response to the chick accommodation unit replacement interval, and this replacement interval is not limited because the manager can arbitrarily determine it.

In addition, the insertion and transfer of the egg holder and the chick accommodation unit may be performed manually by a manager, but in addition to this, it may be automatically performed by various transfer means such as a belt type conveyor and a chain type conveyor, so it is not limited to, and the egg is placed. The part and the receiving part can be transferred in the same direction, but if the egg holding part and the receiving part are transferred in the same direction, the holding part located under the egg holding part is in a state where no chicks are contained, and the space is not effectively utilized. , It is more recommended that the directions in which the egg holding part and the receiving part are transferred are made in opposite directions to each other.

In addition, an egg holding unit collecting means is formed at the end of the first moving guide unit, so that the egg holding unit where hatching is completed or eggs that have not been hatched for a period set by a manager can be collected.

At this time, eggs that have not hatched for a set period of time may remain on the egg holder collected by the egg holder collection means, and in the case of such eggs, they may be separately classified as low-grade and used or discarded.

In addition, in the case of the egg holder collection means, it may be a conveyor belt installed at the end of the chick transfer unit.

In addition, it is recommended that a foreign matter processing unit be formed below the chick receiving unit to remove egg shells, mucus, and chick excreta generated while chicks hatch, so that chicks grow more healthily. In one embodiment, the foreign matter processing unit is a conveyor belt. can be

The present invention is not limited to the above embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

Advantages and characteristics of the embodiments of the present invention, and methods for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

In addition, the transfer of information performed below is performed through communication between elements exchanging information, and such communication may be performed by various methods, so it is not limited.

Hereinafter, a customized product production and supply system 1000 according to the present invention will be described with reference to the accompanying drawings.

26 is a block diagram showing a customized product production and supply system 1000 according to the present invention.

Referring to FIG. 26, the customized product production and supply system 1000 according to the present invention includes a customer terminal 100 into which customer information is input, and an expert terminal 200 into which recommended nutrient information suitable for the customer's condition is input; Based on the customer information transmitted from the customer terminal 100 or the recommended nutrient information transmitted from the expert terminal 200, customized product information is provided to the customer terminal 100, and customized breeding information is generated to produce the product selected by the customer. A central server 300 that breeds livestock using the customized breeding information received from the central server 300, a breeding unit 400, and an evaluation unit 500 that evaluates products shipped from the breeding unit 400. ), and a supply unit 600 that supplies products evaluated by the evaluation unit 500 to customers.

To explain in detail, the nutrients that customers need to consume are different depending on the customer's age, health condition, gender, disease history, surgery history, etc. Even if you know it, it is difficult to select and purchase meat/egg containing these nutrients, so after deriving the necessary nutrient information based on customer information, produce and supply meat/egg containing the derived necessary nutrients to customers. it did

Nutrients suitable for the customer (A) may be derived from the central server 300 based on customer information input through the customer terminal 100, but after experts (doctors, pharmacists, oriental doctors, certified professionals) identify It may be input as the end of the month (200) and transmitted to the central server (300).

At this time, the certified expert (B) may include a variety of people who can derive nutritional information suitable for the customer after identifying the customer's condition, and in one embodiment, a counselor, a delivery person, etc. can include

In addition, the central server 300 provides product (meat/egg) information containing necessary nutrients to the customer terminal 100 so that the customer can select a product suitable for him or her, and the product information provided to the customer. can be provided in order of high nutrient content required by customers.

In addition, when the customer selects a desired product through the customer terminal 100, the central server 300 generates customized breeding information for product production, and then provides the customized breeding information generated to the breeding unit 400 to Allow livestock to be reared in desired conditions.

In detail, since the nutrients contained in the product (meat/egg) vary depending on the breed of livestock raised and the feed supplied to the livestock, the breeding information suitable for product production selected by the customer is transmitted from the central server 300 to the breeding department. (400), so that customers can produce products containing a lot of necessary nutrients.

In addition, the shipped product is supplied to the customer A through the supply unit 600 after it is confirmed by the evaluation unit 500 that it contains nutrients necessary for the customer.

Hereinafter, specific configurations of the central server 300, the breeding unit 400, the evaluation unit 500, and the supply unit 600 described above will be described with reference to the drawings.

27 is a block diagram embodying the customized production and supply system of the present invention, and FIG. 28 is a block diagram embodying the nutrient derivation method performed in the required nutrient derivation unit.

Referring to FIG. 27, the central server 300 includes a customer information storage unit 310 for storing customer information, a necessary nutrient derivation unit 320 for deriving nutrient information necessary for the customer based on the customer information, and stored products. Among the information, a suitable product classification unit 330 for classifying products containing nutrients derived from the necessary nutrient derivation unit 320, and information on products classified by the suitable product classification unit 330 are stored in the customer terminal 100. ), the breeding information generating unit 350 that generates breeding information for producing the product selected by the customer, and the breeding information generated by the breeding information generating unit 350. A breeding information providing unit 360 provided to the unit 400 may be included.

In detail, the customer's information (age, weight, height, blood type, blood pressure, disease history, digestive status, personality, medications being taken) entered through the customer terminal 100 is stored in the customer information storage unit 310. 28, as shown in FIG. 28, the necessary nutrient derivation unit 320 derives the nutrient information necessary for the customer through the designed method, and the product with high nutrient content derived from among the producible products in the suitable product classification unit 330 is selected, and the selected product is transmitted to the customer terminal 100 through the product information providing unit 340 so that the customer can check a product suitable for him/herself.

In addition, the breeding information providing unit 360 transmits the customized breeding information for breeding the customer-selected product generated by the breeding information generating unit 350 to the breeding unit 400 .

At this time, the customized breeding information may be made in the form of extraction from breeding data created by linking nutrient information of shipped products with livestock breeding information.

The necessary nutrient derivation unit 320 uses a health status classification unit 321 that classifies the customer's condition into a healthy state or a deteriorating health state based on customer information, and customer information classified as a health state. A constitution classification unit 322 for classifying the constitution, a first necessary nutrient derivation unit 323 for deriving necessary nutrient information for the customer according to the constitution classified by the constitution classification unit 322, and classifying as having deteriorated health A second necessary nutrient derivation unit 324 for deriving information about nutrients to be avoided and information on necessary nutrients based on the patient's disease, medication status, and blood pressure may be included.

In detail, if the customer is in a healthy state, nutrients suitable for the customer's constitution may be recommended, but if the customer suffers from a specific disease or is taking medicine, there may be nutrients whose intake is limited, as shown in FIG. As described above, the health state classification unit 322 classifies the customer into a healthy state and an unhealthy state according to whether the customer has taken medicine or has a disease.

In addition, if the customer is in a healthy state, the constitution classification unit 332 classifies the customer's constitution into Taeyangin, Soyangin, Taeeumin, and Soeumin based on Sasang Medicine, and nutrients suitable for the constitution classified in the first necessary nutrient derivation unit 323 made it possible to derive.

At this time, the classification based on Sasang medicine can be made based on the customer's body information, long-term activity information, personality information, disease history information, etc. among the customer information input through the customer terminal 100 .

As an example, if the classification based on organ activity information is described, a person with strong lung function and weak liver function is Taeyang, a person with strong digestive function and weak kidney function is Soyang, and a person with good liver function and weak lung function. A person can be classified as a Taeumin, and a person with a weak kidney function as a Soeumin.

In addition, when the customer is classified as unhealthy, the second necessary nutrient derivation unit 324 communicates with the hospital server C to receive recommended nutrient information for the customer, or after receiving recommended food information for the customer, recommended In the form of figuring out the nutrient information contained in the food to be served, we derive recommended nutrient information for customers.

In addition, the nutrient information required by the customer derived from the first required nutrient derivation unit 323 or the second required nutrient derivation unit 324 is transmitted to the suitable product classification unit 330 to select a customized product optimized for the customer. It is used as a material for

Referring to FIG. 27, the breeding unit 400 includes a breeding facility 410 in which livestock are raised, a feed manufacturing unit 420 in which feed is produced, and a feed supply unit 430 which supplies the prepared feed to the breeding facility 410. ), and a breeding management unit 440 that receives breeding information from the central server 300 and adjusts the composition ratio of the feed produced by the feed manufacturing unit 420, collects feed data provided to livestock, and displays images of livestock growth. It may include a verification information collection unit 450 to be photographed.

In detail, since the nutrients contained in slaughtered meat or eggs laid by livestock vary depending on what kind of feed is supplied to the livestock, when the customer selects a specific product, breeding information for making the selected product is transmitted to the breeding management unit 440. , and the breeding management unit 440 adjusts the mixing ratio of the feed produced by the feed manufacturing unit 420 so that a special feed that can make a product desired by the customer can be supplied to the livestock.

In addition, the evaluation unit 500 evaluates the suitability of the product by examining the sample extraction unit 510 for extracting a sample of the product shipped from the breeding unit 400 and the sample extracted from the sample extraction unit 510. It may include a conformity evaluation unit 520 and an evaluation product classification unit 530 that provides products whose suitability is recognized in the conformity assessment unit 520 to the supply unit 600 and discards unsuitable products.

In detail, even if livestock are raised using customized breeding information, since the shipped product may have a quality that does not match the product information provided to the customer, after extracting a sample of the shipped product from the sample extraction unit 510, The evaluation unit 520 allows the product to be delivered to the customer only when it is determined that the sample has a quality higher than that of the product information provided to the customer.

At this time, the quality described above is judged based on how high the ratio of nutrients required by customers among the nutrients contained in the product is, so a product with a quality that exceeds the product information provided to customers means that the ratio of nutrients required by customers is higher than that of other products. It can mean a high product.

In addition, if the shipped product does not meet the quality of the product selected by the customer, the evaluation product classification unit 530 discards it, so that the customer can trust and eat the supplied product.

In addition, the supply unit 600 provides a packaging unit 610 in which shipped products are packaged, a transport unit 620 which transports the packaged products to customers, and shipment information and transport information of the products to the customer terminal 100. It may include a transfer information providing unit 630.

In detail, when the product to be shipped is packaged so that it can be delivered in a fresher state in the packaging unit 610, and the packaged product is delivered through the transport unit 620, the transport information providing unit 630 shows how the delivery is performed. is provided to the customer terminal 100 so that the customer can check the delivery status.

At this time, the transfer information providing unit 630 may provide delivery information to the customer through the central server 300, but may directly provide delivery information to the customer, so it is not limited thereto.

In addition, the customized product production and supply system of the present invention provides the growth information of livestock collected while raising livestock through the customer terminal 100 and the evaluation information of the evaluation unit 500 so that customers can trust the delivered product. did

In detail, the verification information providing unit 370 receives feed information provided to livestock and image information on how livestock grow from the verification information collection unit 440 installed in the breeding unit, and the conformity evaluation unit 520 receives evaluation data. is transmitted to the customer terminal 100 so that the customer can check the growth process and evaluation process of the product.

In addition, in the present invention, new breeding data generated through the breeding system is updated by the breeding information generating unit 350, and this breeding system includes a breeding farm forming a breeding space in which livestock are bred and livestock separately bred in the breeding space. A breeding environment creation unit that creates different breeding environments, a breeding information acquisition unit that acquires breeding information of livestock raised in the breeding space, and a nutrient information acquisition unit that acquires nutrient content information of products by inspecting products shipped from the breeding unit. It may include a breeding data acquisition unit that acquires breeding data for obtaining a product having a specific nutrient by linking the breeding information of livestock with the nutrient content information of the product.

In detail, the more products that can be produced, the more suitable products can be provided to customers. Therefore, breeding data for creating new products can be derived by breeding livestock in various ways in the breeding system.

In addition, the breeding information above may include any one or more of nutrient ratio information of the supplied feed, feed supply amount information, feed supply cycle information, temperature information of the breeding space, humidity information of the breeding space, and sunlight amount information of the breeding space. there is.

In addition, the present invention may further include a breeding target supply unit for providing offspring or eggs of livestock raised in the breeding farm, and the breeding target supply unit includes a development unit in which livestock eggs are stored at a temperature suitable for hatching, and eggs that have passed through the development unit. It may include an hatching unit that is hatched.

In addition, the incubation unit is located on the upper side and includes an egg holder in which eggs to be hatched are located, an incubation target transfer unit located below the egg holder, and a hatching target transported through the hatch target transfer unit located below the hatching target transfer unit. It may include an incubation target accommodation unit.

In detail, a drop hole is formed on the lower side of the egg holder, and when a baby of livestock is born from the mounted egg, it falls down through the drop hole. This is so that offspring born at similar times can gather in the receiving area for hatching.

At this time, a light emitting means for attracting hatchlings from the egg and allowing the hatched offspring to fall more quickly into the falling hole may be located in the falling hole, and Teflon is coated around the falling hole to reduce surface friction and is adjacent to the falling hole. You can also make the chicks slide and fall through the trap.

The present invention is not limited to the above embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

Claims (39)

1. An incubation unit 100 in which an egg holding unit 110 in which eggs are placed and a chick drop port 120 in which chicks hatched from the eggs fall are formed;

   a chick transfer unit 200 for transporting chicks that have fallen through the chick drop port 120; and

   A smart incubation device comprising: a chick receiving unit 300 in which chicks transported through the chick transfer unit 200 are collected and a nutrient providing unit 310 is formed.
2. According to claim 1,

   Of the first movement guide part 400 forming a path along which the plurality of hatching units 100 are transported, and the second movement guide unit 500 forming a path along which the plurality of chick accommodating units 300 are transported A smart hatching device further comprising any one or more.
3. According to claim 1,

   The egg holder 110 includes an egg support lip 111 for supporting the egg to be mounted.
4. According to claim 1,

   The nutrient supply unit 310 includes a feeder 311 in which feed is stored and a water supply tube 312 in which water is supplied.
5. According to claim 4,

   The nutrient providing unit 310 is spaced apart from the side of the receiving unit 300, and an opening is formed in the receiving unit 300, the smart incubation device.
6. According to claim 2,

   The smart incubation device further comprises an incubation part collection means 600 for collecting the incubation part 100 that has deviated from the first movement guide part 400.
7. According to claim 2,

   The chick accommodating part 300 has a plurality of foreign matter discharge holes 320 formed on the lower side, and a foreign matter processing unit 700 for processing foreign substances discharged through the foreign matter discharge hole 320 on the lower side of the chick accommodating part 300. ) is located, the smart hatching device.
8. According to claim 2,

   Smart incubation device further comprising a breeding farm transfer unit 800 for transporting the chick accommodation unit 300 detached from the second movement guide unit 500.
9. According to claim 8,

   The breeding farm transfer unit 800 includes a plurality of slide transfer units 810 inclined at the ends of each chick accommodating unit movement guide unit 500, and a plurality of slide transfer units 810 that are spaced apart from the end of the slide transfer unit and transported through the slide transfer units. A smart hatching device including a transportation belt 820 for collecting the chick accommodation unit 300 and transporting it to a destination.
10. According to claim 2,

    An input module (M) providing the hatching unit 100 as the first movement guide unit 400 and providing the chick accommodating unit 300 as the second movement guide unit 500, and the input module (M) and an opening/closing means (D) positioned between the first movement guide part 400 and the second movement guide part 500, further comprising a smart incubator.
11. According to claim 10,

    The input module (M) includes a lifting module (M1) for moving the target in the height direction and a transfer module (M2) for providing the target to the lifting module (M1).
12. According to claim 10,

    The opening/closing means (D) is mounted on the housing (H) surrounding the first movement guide part 400 and the second movement guide part 500 and includes a door housing (DA) in which an inlet and outlet (D1) are formed, and the door housing ( A door (D2) hinged to DA) to open and close the inlet and outlet (D1), an edge of the door (D2) and a surface of the door housing (DA) facing the edge of the door (D2) Formed on at least one side A smart incubator containing a permanent magnet.
13. According to claim 12,

    The housing (H) includes a heat blocking wall (H2) formed between the entrance wall (H1) and the first movement guide part (400), and between the entrance wall (H1) and the heat blocking wall (H2). The smart incubation device, characterized in that the opening and closing means (D) are formed facing each other and spaced apart.
14. According to claim 13,

    The smart incubator further comprises a head conveyor (D3) positioned between the entrance wall (H1) and the heat blocking wall (H2) and operated individually.
15. a breeding unit 100 forming a breeding space in which objects to be raised are accommodated;

    a heat insulation housing 200 in which an accommodating space 210 in which the breeding unit 100 is provided is formed and an air circulation passage is formed at an edge of the accommodating space 210;

    a blowing unit 300 that blows wind to move the air in the accommodation space 210 along the air circulation passage;

    A breeding module comprising a; environment control unit 400 for controlling the environment of the accommodation space 210.
16. According to claim 15,

    The breeding part 100 includes a plurality of breeding part frames 110 crossing each other to form vents;

    A ventilation network 120 coupled to the ventilation hole and having a plurality of holes formed therein;

    A breeding module including a separating net 130 coupled to the breeding unit frame 110 to separate a breeding space formed inside the breeding unit 100 into a plurality of holes and having a plurality of holes.
17. According to claim 16,

    The breeding unit 100 includes a foreign material conveying means 140 that is located below the separation net 130 and moves foreign matter falling through the separation net 130;

    A breeding module comprising a; foreign matter collection unit 150 in which the foreign matter transported through the foreign matter conveying means 140 is gathered.
18. According to claim 15,

    The environmental control unit 400 is a ventilation unit 410 that ventilates the air of the accommodation space 210 by receiving external air and discharging internal air;

    a temperature control unit 420 for controlling the temperature of the accommodation space 210;

    A breeding module comprising a; humidity control unit 430 for controlling the humidity of the accommodation space 210.
19. According to claim 18,

    The ventilation unit 410 includes an outside air inlet 411 perforated on the heat insulating housing 200 and through which outside air is introduced;

    a first opening/closing means 412 for opening/closing the outside air inlet 411;

    an outdoor air inlet duct 413 connected to the outdoor air inlet 411 and forming an air inlet;

    A bet outlet 414 formed on the heat insulation housing 200 and spaced apart from the outside air inlet 411 and through which internal air is discharged;

    A breeding module comprising a; second opening and closing means 415 for opening and closing the bet outlet 414.
20. According to claim 19,

    The temperature controller 420 includes a cooling means 421 installed on the outside air intake duct 413 and lowering the temperature of the air passing through by evaporating water;

    A breeding module comprising a; heating means 422 installed on the air circulation passage and generating heat with electricity.
21. According to claim 18,

    In the air blower 300, an air outlet is positioned toward the outside air inlet 411, and the humidity controller 430 for discharging water is positioned between the outside air inlet 411 and the blower 300. Characterized in that, breeding module.
22. According to claim 18,

    A breeding module further comprising; a light emitting means 500 positioned on one or more of the side and upper sides of the breeding unit 100 and emitting light.
23. A breeding unit 100 forming a breeding space in which livestock are raised;

    A breeding environment creation unit 200 that creates different breeding environments for livestock separately bred in the breeding space;

    a breeding information acquisition unit 300 that acquires breeding environment information of livestock raised in the breeding space;

    A first quality measurement unit 400 that obtains quality information by inspecting products shipped from the breeding unit 100; and

    A breeding system comprising: a breeding information collection unit 500 that derives breeding environment information for each product quality by linking livestock breeding environment information with product quality information.
24. 24. The method of claim 23,

    The breeding environment information includes at least one of nutrient ratio information, feed supply amount information, feed supply cycle information, temperature information of the breeding space, humidity information of the breeding space, and ventilation amount information of the breeding space. .
25. 24. The method of claim 23,

    The breeding environment creation unit 200 includes an information input unit 210 into which breeding environment information is input;

    A breeding system comprising: an environment creation unit 220 that adjusts the breeding environment of each breeding space with the breeding environment information input from the information input unit 210.
26. 26. The method of claim 25,

    The information input unit 210 includes an information storage unit 211 storing the breeding environment information for each product quality transmitted from the breeding information collection unit 500;

    an information display unit 212 that provides a manager with breeding environment information for each shipment product quality stored in the information storage unit 211;

    A breeding system including a manager terminal 213 through which the manager inputs breeding environment information.
27. 27. The method of claim 26,

    The breeding environment composition unit 200 generates breeding information for generating comparative breeding environment information by collecting breeding environment information of products of quality within the top 40% among breeding environment information by shipment product quality stored in the information storage unit 211. Part 230; including, breeding system.
28. 28. The method of claim 27,

    The breeding environment information input to the information input unit 210 is within the top 30% of the breeding environment information input through the manager terminal 213 and the breeding environment information by shipment product quality stored in the information storage unit 211. Breeding environment information in which the product having is made, and comparative breeding environment information created in the breeding information generating unit 230;
29. 26. The method of claim 25,

    The environment creation unit 220 includes a feed manufacturing unit 221 in which a plurality of feeds provided to the breeding space are made;

    A breeding system including a feed supply unit 222 for separately supplying the feed made in the feed manufacturing unit 221 to the breeding space.
30. 26. The method of claim 25,

    The environment creation unit 220 includes a climate control unit 223 that controls one or more of temperature, humidity, and ventilation of the breeding space.
31. 24. The method of claim 23,

    The first quality measurement unit 400 includes a transfer unit 410 that manages the transfer of products shipped from the breeding unit 100;

    a sample obtaining unit 420 in which a sample of the product transported through the transfer unit 410 is extracted;

    A breeding system comprising an evaluation unit 430 for evaluating the quality of the sample extracted from the sample acquisition unit 420.
32. A customer terminal 100 into which customer information is input;

    an expert terminal 200 into which information on nutrients recommended to customers is input;

    Based on the customer information transmitted from the customer terminal 100 or the recommended nutrient information transmitted from the expert terminal 200, customized product information is provided to the customer terminal 100, and customized breeding is performed to produce the product selected by the customer. A central server 300 generating information;

    a breeding unit 400 that breeds livestock using the customized breeding information transmitted from the central server 300;

    an evaluation unit 500 in which products shipped from the breeding unit 400 are evaluated; and

    A supply unit 600 supplying a product evaluated by the evaluation unit 500 to a customer; and a customized product production and supply system.
33. 33. The method of claim 32,

    The central server 300 includes a customer information storage unit 310 in which customer information is stored;

    A necessary nutrient derivation unit 320 for deriving nutrient information necessary for the customer based on the customer information;

    A suitable product classification unit 330 for classifying products containing nutrients derived from the necessary nutrient derivation unit 320 among stored product information;

    a product information providing unit 340 that provides information on products classified by the suitable product classifying unit 330 to the customer terminal 100;

    Breeding information generation unit 350 for generating breeding information for producing a product selected by the customer;

    a breeding information providing unit 360 that provides the breeding information generated by the breeding information generating unit 350 to the breeding unit 400; Including, customized product production and supply system.
34. 34. The method of claim 33,

    The central server 300 is a verification information providing unit that provides growth information of livestock collected while raising livestock in the breeding unit 400 and evaluation information of the evaluation unit 500 to the customer terminal 100 ( 370);, a customized product production and supply system.
35. 34. The method of claim 33,

    The required nutrient derivation unit 320 includes a health status classification unit 321 that classifies the customer's condition into a healthy state or a deteriorating state based on customer information;

    a constitution classification unit 322 that classifies the customer's constitution using the customer information classified as healthy;

    a first required nutrient derivation unit 323 for deriving nutrient information necessary for the customer according to the constitution classified by the constitution classification unit 322;

    A second necessary nutrient derivation unit 324 for deriving information about nutrients to avoid and necessary nutrients of customers classified as having deteriorated health; including, a customized product production and supply system.
36. 34. The method of claim 33,

    Characterized in that, the customized product production and supply system; the suitable product classification unit 330 classifies products based on the necessary nutrient information transmitted from the expert terminal 200.
37. 33. The method of claim 32,

    The breeding unit 400 includes a breeding facility 410 in which livestock are raised;

    A feed manufacturing unit 420 where the feed is made;

    A feed supply unit 430 supplying the prepared feed to the breeding facility 410;

    a breeding management unit 440 that receives breeding information from the central server 300 and adjusts the composition ratio of the feed produced by the feed manufacturing unit 420;

    A customized product production and supply system including; a verification information collection unit 450 that collects feed data provided to livestock and takes a growth image of livestock.
38. 33. The method of claim 32,

    The evaluation unit 500 includes a sample extraction unit 510 for extracting a sample of products shipped from the breeding unit 400;

    a suitability evaluation unit 520 for evaluating the suitability of a product by examining the sample extracted from the sample extractor 510;

    An evaluation product classification unit 530 for providing products whose conformity has been recognized in the conformity evaluation unit 520 to the supply unit 600 and discarding unsuitable products; including, customized product production and supply system.
39. 33. The method of claim 32,

    The supply unit 600 includes a packaging unit 610 in which shipped products are packaged;

    A transfer unit 620 that transfers the packaged product to the customer;

    A customized product production and supply system including; a transport information providing unit 630 that provides product shipment information and transport information to the customer terminal 100.

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