CN113040054A - Pig raising system for multi-storey buildings - Google Patents

Abstract

The invention relates to a multilayer pig raising building house, which comprises: the frame comprises a plurality of bearing columns, a plurality of transverse frame beams and a plurality of longitudinal frame beams, wherein the transverse frame beams and the longitudinal frame beams are arranged on the bearing columns and are vertical to each other; a multi-layered floor slab disposed on the frame; the excrement leaking floor is arranged between the floor slabs; the excrement discharge device comprises a excrement discharge floor, a plurality of excrement ditches and a plurality of excrement discharge pipes, wherein the excrement discharge pipes are arranged on the excrement discharge floor; wherein the side walls of the manure pit comprise the transverse frame beams and/or the longitudinal frame beams arranged at the top of the inner space of the manure pit. This application building house passes through structural change, and the floor height that can greatly reduced building house to can reduce construction cost, reduce the investment in earlier stage.

Description

Pig raising system for multi-storey buildings

Technical Field

The invention relates to the field of livestock feeding, in particular to a pig raising system for a multi-storey building.

Background

In view of the background of severe environment and normalized non-plague of livestock breeding, scattered households in the Chinese breeding market select to quit the farm in a dispute, the number of the scattered households for pig breeding in 2010 is reduced from 6170 households in 2019, practitioners for pig breeding are further reduced, but large-scale breeding gradually becomes a trend, and the proportion of large-scale pig breeding is increased from 34.5% in 2010 to 52.3% in 2019. In order to meet the increasing demand of meat food consumption in China, some large group enterprises and medium-sized breeding companies strive for first fear and then increase the breeding intensity of live pigs, so that the contradiction between human and animal land is increased, and the environmental pollution is intensified. In order to solve the contradiction, the pig raising in multilayer buildings is successively promoted by all the large groups. In the natural resource regulation [2019] 4' notice of problems related to facility agricultural land use management of the department of agricultural rural areas, which is jointly issued by the ministry of natural resources and the ministry of agricultural rural areas, the cultivation facilities are clear to allow the construction of multi-storey buildings, and the development situation of pig raising of the multi-storey building is further determined.

Wherein, the multi-storey building is mostly the reinforced concrete frame construction form, and the increase of various affiliated buildings and the increase of elevator, each kind of pig only transfer apparatus all have very big increase to investment in earlier stage and later maintenance cost. In order to meet the requirements of equipment installation and ventilation in a pigsty, the storied building of the multi-storey building is generally higher in storey height; and in order to meet the ventilation requirements of pigs in different seasons and improve the internal environment of the pigsty, higher requirements are provided for the multi-storey building. All of which increase the investment cost. Therefore, all groups are researching economically applicable pig raising systems to reduce the early investment and the later maintenance cost.

Disclosure of Invention

Aiming at the technical problems in the prior art, the invention provides a multilayer pig raising building house, which comprises: the frame comprises a plurality of bearing columns, a plurality of transverse frame beams and a plurality of longitudinal frame beams, wherein the transverse frame beams and the longitudinal frame beams are arranged on the bearing columns and are vertical to each other; a multi-layered floor slab disposed on the frame; the excrement leaking floor is arranged between the floor slabs; the excrement discharge device comprises a excrement discharge floor, a plurality of excrement ditches and a plurality of excrement discharge pipes, wherein the excrement discharge pipes are arranged on the excrement discharge floor; wherein the side walls of the manure pit comprise the transverse frame beams and/or the longitudinal frame beams arranged at the top of the inner space of the manure pit.

The building as described above, wherein the manure pit comprises a bottom plate, which is connected to the beam frame beam and mounted on the frame.

A building as claimed in any preceding claim, wherein the surfaces of the floor and the dung trench floor comprise concrete elements, the concrete elements being integrally formed.

A building as claimed above wherein the concrete component comprises impervious concrete.

The building as described above, wherein the manure pit comprises a waterproof layer disposed on an outer surface of a floor of the manure pit.

The building as described above, wherein the manure pit provided at the lowermost layer is not connected to the frame.

The building house further comprises a dung scraping machine which penetrates through the inner space of the dung ditch of each floor through the steel wire rope and scrapes dung by utilizing the scraping plates on the steel wire rope.

The building as described above, wherein the steel wire rope passing through the space between two adjacent manure ditches is covered with a protection pipe.

The building further comprises a feces discharging vertical pipe, wherein the feces discharging vertical pipe is arranged at one end of the building and is communicated with the feces ditch on each floor.

The building as described above, wherein the floor height of the building is 3.2m-3.6 m.

The building house further comprises a ventilation system, wherein the ventilation system comprises an air inlet end and an air outlet end, and the air outlet end is provided with a negative pressure fan.

As above building house, wherein, the air inlet end includes: a protective net configured to block external animals from entering the building; a filter wall configured to filter impurities, viruses in air; a water curtain configured to humidify air entering a building; and the outside air sequentially passes through the protective net, the filter wall and the water curtain to enter the building.

The building house as described above, wherein the air intake end further comprises: a negative pressure window configured to control an amount of air the outside air enters the building.

The building as described above, wherein the top of each floor of the building comprises a suspended ceiling window configured to accommodate external air vertically entering the building, wherein the external air enters the building through the suspended ceiling window after passing through the protective net and the filtering wall in sequence.

The building house as described above, wherein the air outlet end comprises a deodorizing room.

A building as claimed above wherein the load bearing rating of the deodorising block is lower than the load bearing rating of the building.

This application building house passes through structural change, and the floor height that can greatly reduced building house to can reduce construction cost, reduce the investment in earlier stage.

Drawings

Preferred embodiments of the present invention will now be described in further detail with reference to the accompanying drawings, in which:

FIG. 1 is a schematic overall layout of a pig raising system for multi-storey buildings according to an embodiment of the application;

FIGS. 2A and 2B are schematic diagrams of a manure pit in a building of a pig raising system according to one embodiment of the present application;

FIG. 3 is a partial schematic view of a single-story fecal scraping system according to one embodiment of the present application;

FIG. 4 is a partial schematic view of a manure scraping system for each building of a pig farming system according to one embodiment of the present application;

FIG. 5 is a schematic illustration of a gestational house according to one embodiment of the present application;

fig. 6A and 6B are schematic illustrations of a birthing house arrangement according to one embodiment of the present application;

FIG. 7 is a schematic illustration of a building interior partition according to one embodiment of the present application;

fig. 8A and 8B are schematic illustrations of ventilation in a hog house according to an embodiment of the present application;

figures 9A-9C are schematic illustrations of ventilation within a building according to another embodiment of the present application; and

FIG. 10 is a flow chart of a method for swine breeding according to one embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the following detailed description, reference is made to the accompanying drawings that form a part hereof and in which is shown by way of illustration specific embodiments of the application. In the drawings, like numerals describe substantially similar components throughout the different views. Various specific embodiments of the present application are described in sufficient detail below to enable those skilled in the art to practice the teachings of the present application. It is to be understood that other embodiments may be utilized and structural, logical or electrical changes may be made to the embodiments of the present application.

The application discloses novel economical multilayer building system of raising pigs adjusts through the part structure to in the system of raising pigs, and the effectual floor height that reduces the system structure of raising pigs, reduce the building area and practiced thrift the use of relevant corollary equipment to reduce the earlier stage investment and the later stage cost of maintenance of the system of raising pigs fundamentally.

In addition, when pigs are raised in a multi-storey building, the breeding density of a single square area is increased, and more severe requirements are provided for biological safety prevention and control. And the ammonia concentration in the plant house is high, and especially multi-storey building, the stink radiation range is wide, and the influence area is big, causes certain influence to surrounding villager residential environment. One important reason for the return of most of scattered households in recent years is the normalization of African swine fever. Therefore, biosafety is becoming increasingly important for swine systems.

The pig raising system of the application also makes a series of improvements on the aspects.

According to one embodiment of the present application, the pig raising area may be divided into: dirty areas, isolation areas, in-field safe areas, and clean areas. Wherein the dirty area is an area outside the culture system. The isolation zone may include areas such as transit piggery, staff dormitory, dining room, pig farm office, dining room, dirty treatment zone of excrement, staff isolation zone, dead pig treatment zone. The on-site safety area includes areas inside the production area, outside the building (where pigs are accommodated, which may also be referred to as a "pigsty"), production auxiliary facilities, facilities outside the building, and the like. The clean area can be the area such as building inside and airtight vestibule. The areas of the pig raising system are distinguished, and corresponding adjustment is carried out on different areas, so that the biological safety of the pig raising system can be effectively guaranteed.

Fig. 1 is a schematic overall layout of a pig raising system for a multi-storey building according to an embodiment of the application.

As shown in the figure, a plurality of buildings with a single function can be constructed in a clean area of a pig raising system 100 (hereinafter referred to as a "pig raising system") of a multi-storey building according to a plurality of main stages of pig raising. According to one embodiment, the pig raising system 100 may include at least 1 gestational shed 110, 1 farrowing shed 120, and 1 nursery 130 and one fattening house 140 connected to each other by a corridor 150, thereby achieving peer-to-peer transfer of pigs. According to one embodiment, the clean zone may also include a backup house 160. In some embodiments, the number of floors in a building may be, for example: 2, 3, 4 or more layers. According to another embodiment, it is also possible to place care and fattening in the same building but to distinguish between care and fattening fields.

In some embodiments, separate washing and disinfecting facilities and deodorizing facilities may be provided in each of the gestational shed, the birthing shed, the nursery and the fattening shed. Of course, independent decontamination or deodorization may be provided in only one or more of the plants as desired.

According to one embodiment, the isolation region may include: an isolation house 170, a pig house 180 and a fecal sewage treatment area 190. The functions and features of each zone will be described below in terms of the process of circulation of pigs.

According to one embodiment, the pig farming system 100 may include an isolation house 170, which may be used to introduce isolation of pigs. According to one embodiment, the isolation shed can be connected with other buildings without corridors, and the pigs are only transported by vehicles. For example, after the isolation is finished, the replacement sows are transferred from the pig-out platform on-site pig carrying cars at the outlet of the isolation shed 170 to the replacement shed 160 along the on-site roads for replacement breeding. This is for better isolation purposes. According to one embodiment, the number of isolation houses 170 and the number of layers can be a single layer, but can be adjusted as desired.

In some embodiments, 200 replacement pigs are externally introduced, aged about 4 months and weighing about 50 to 60 kg, into the isolation shed from an entrance at one side of the isolation shed 170, and observed and isolated in the isolation shed for 4 to 5 weeks, according to the size of the basal sows and the number of commercial pigs that are released each year.

According to one embodiment, the pig farming system 100 may also include a back-up house 160 that may be used to introduce the breeding view of pigs and the breeding view of back-up growing pigs. According to one embodiment, the backup houses may be connected to other buildings via an enclosed corridor 150.

In some embodiments, artificial insemination is performed at the second through third instar, typically at the second through third instar, after 4 weeks of post-house 160 large-size rearing, for a suitable 4 weeks of breeding in the check-out cage, for a month of age of about 7 to 8 months, and a weight of about 130 to 140 kg, and then delivered to the gestational house.

As will be appreciated by those skilled in the art, the present application is described in terms of whole-course feeding (i.e., self-breeding), and the present application may also be applied to other feeding regimes, such as: when only the fattening pig feeding (i.e., the feeding by purchasing piglets) is performed, only the nursing fattening house may be included.

According to one embodiment, the pig farming system 100 may include a gestational shed 110 for sow mating. The breeder determines that a sow successfully bred is driven to the gestational litter for gestational feeding, e.g., 16 weeks, via, e.g., the containment corridor 150.

According to one embodiment, the pig raising system 100 may comprise a farrowing house 120 for farrowing sows, wherein the sows to be farrowing are transferred from the internal walkway to the farrowing house for farrowing 2 to 3 days before the edd, and wherein the sows are weaned after the farrowing house 120 to 3 weeks. According to one embodiment, the bred weaned piglets can be transferred from the closed corridor to a replacement house for replacement breeding, the sows are transferred to the gestational house 110 for next mating after oestrus is given again, and the bred piglets can be transferred from the closed corridor to a nursing house and a fattening house for breeding.

In some embodiments, the breeding sows are selected and marked with ear defects before weaning according to appearance, parental production performance, defect-free other pigs in the same litter, and the like. The reserved weaned piglets and the rest weaned piglets are fed in groups and are all driven to a nursing house and a fattening house through a closed corridor for breeding. For example, after 11.5 weeks in a nursery house, pigs are 14.5 weeks old and transferred to a fattening house through an internal walkway. The pigs are transferred out after 11.5 weeks of breeding in a fattening house to 26 weeks of age. In some embodiments, it is also necessary to clean and disinfect the columns, equipment, etc. in the nursery and fattening houses. For example: the washing and the disinfection are respectively carried out in the nursery house and the fattening house for 0.5 week.

According to one embodiment, the pig farming system 100 may include a nursery house 130 and a fattening house 140 as spaces for growth and fattening of piglets. The volume of the pigs in the fattening stage is generally larger than that of the pigs in the nursing stage. Therefore, generally, the field of the fattening house is larger than the field of the nursing house. In addition, the conventional breeding method is to breed pigs in the breeding house for 8 weeks and the fattening house for 16 weeks, that is, the number of the fattening house columns is more than that of the breeding house, for example, the number of the fattening house columns is 2 times of that of the breeding house columns.

However, the present inventors have observed that pigs only leave the nursery often not have a volume that the nursery columns cannot accommodate. In order to improve the utilization efficiency of the building area and follow the law of pig breeding, the inventor adjusts the nursing and fattening weeks to be the same, for example, 12 weeks. Thus, the number of the columns in the nursery house and the number of the columns in the fattening house can be set to be the same, and the pigs are changed from the period of time when being used in the fattening house to the period of time when being used in the nursery house. Compared with the traditional pigsty, the building house arranged in such a way can reduce the total building area by 5 percent.

According to one embodiment, the pig farming system 100 may also include an exit pigsty 160, which may be used to store the transports of fattened pigs for sale, or to reject the transports. According to one embodiment, the fattening house may be connected with the pig house through a rotary staircase or a closed corridor, or may be transported through vehicle transport.

In some embodiments, the following conditions occur during the feeding process, such as a multiparous sow. Such as: the sow is not suitable for the intra-site gestational age structure, the sow has the existing service life, the body condition is poor, the litter yield is low, the number of non-pregnant days is too long, the sow is difficult to estrus again, the conception is difficult, the maternal performance is poor, the production score is low, and the like, and the sow needs to be eliminated. According to one embodiment, sows to be eliminated on each floor in the gestational facility 110 may be driven to the first floor by a spiral staircase, transferred from the on-site road to an out-pig facility by an on-site pig transport cart, and transferred to an external pig pulling cart by an out-pig platform.

In some embodiments, when dead pigs appear in each building, the dead pigs are transported from each building to a hydraulic elevator of the deodorization room, descend to the first floor and then are pulled to a harmless treatment workshop of the fecal sewage treatment area for uniform treatment.

In some embodiments, the corridor 150 may be a closed corridor, which is mainly used for transporting pigs between houses in clean areas in the same layer, thereby avoiding cross-layer infection and improving biological safety. Of course, the vestibule 150 may not be sealed, but may be provided that a same layer of swine transfer is possible.

In some embodiments, each building house in the pig-raising system 100 may further include a deodorization room, which may be used to deodorize and filter the gas in the building house, prevent odor radiation from affecting the surrounding environment or surrounding residents, and achieve independent ventilation, which is a consideration in terms of biosafety. In some embodiments, because the deodorization room does not contain pigs, the bearing grade of the deodorization room can be lower than that of other components in the building house, so that the building cost can be reduced and the surrounding environment can be greatly improved on the premise of meeting the requirement of the deodorization function. In some embodiments, a deodorization room is not necessarily arranged in each building, and the deodorization rooms can be arranged according to the mutual relation of buildings.

In some embodiments, the pig raising system 100 may further include a fecal sewage treatment area 190, which may be used to treat sewage, feces, etc. generated by the whole pig raising system, so as to avoid pollution to the surrounding environment, and to treat dead pigs harmlessly to prevent disease transmission.

In some embodiments, the number of layers of each building house is the same, so that the pigs in each building house in the same layer can be conveniently transported, the crossing among the layers of the building houses can be avoided, and the biological safety of the pigs in the building houses can be ensured. For example: when the sows to be delivered in the gestational house are transferred to the same-layer farrowing house for delivery before the estimated delivery period (for example, 2 to 3 days), the sows are transferred to the same-layer nursery and fattening house after the piglets in the farrowing house stay to weaning, and the sows return to the gestational house.

In some embodiments, the building foundation in pig farming system 100 may be formed as a pile foundation with a cap. Wherein, the main structure form can be a frame structure. In some embodiments, the building roof can adopt the steel construction to reduce the dead weight, practice thrift the cost, reduction of erection time. In some embodiments, the house roof insulation can be heat preservation and insulation by adopting glass wool and steel wire meshes. In some embodiments, the roofing glass wool has a fire retardant rating of class a1 and may be 75mm thick. In some embodiments, the P6 grade impervious concrete can be used as the floor concrete, and the impervious and waterproof capabilities of the concrete can be utilized, so that the construction of a flexible waterproof layer and a leveling protective layer can be eliminated, the construction process is reduced, and the construction cost is saved.

In some embodiments, the floor of the pig raising system 100 can be trowelled by concrete raw slurry and formed in one step, and no leveling layer or surface layer is needed, so that the construction procedures can be reduced. In some embodiments, the exterior wall insulation material of the pig raising system 100 can be polyphenyl granule insulation mortar, which not only meets the energy-saving requirement, but also has high strength, and can avoid common quality problems such as cracking, water seepage, falling and the like caused by using plastic plates, thereby improving the engineering quality, shortening the construction period and reducing the cost.

The application further saves the building cost by changing the specific structure in each building house, and the improvement of the specific structure of the building house in the pig raising system is introduced below.

In the building house of the pig raising system, the dung drain is generally arranged below the column where the pigs are located. The application provides a system building house of raising pigs, has realized the reduction of floor through the structure of adjustment excrement ditch and building cost's reduction.

Fig. 2A and 2B are schematic views of a manure pit in a building of a pig raising system according to an embodiment of the present application.

As shown, the manure pit 200 includes: a bottom plate 210 and sidewalls 220. Wherein, the two ends of the bottom plate 210 are connected with the side walls 220 to form a groove together in a surrounding manner, and the groove can be used for storing excrement discharged by pigs. In some embodiments, the dung-leaking floor 201 is supported by the side walls 220 above the dung drain, so that the dung drain can be shielded and dung from the pigs can be leaked into the dung drain. In some embodiments, the clearance height H1 inside the manure pit is 350-750 mm. In some embodiments, the width W1 of the sidewall is 350-400mm and the height H2 is 500-550 mm. In some embodiments, the thickness G1 of the bottom plate 210 is 120-150 mm.

According to a typical building design, the building body structure is a frame structure comprising a plurality of transverse and longitudinal frame beams perpendicular to each other, floor slabs are arranged on part of the frame structure, and a dung-leaking floor 201 is laid between the floor slabs and/or on the dung trench to form the floor of the building. In conventional pigsty designs the floor of the manure pit sits above the longitudinal frame beams and the height of each floor therefore includes the height of the longitudinal frame beams. In some embodiments, the width W2 of the longitudinal frame beams may be 350-400mm and the height H3 may be 500-550 mm.

In the present application, as shown in fig. 2A, the longitudinal frame beams 230 are moved from below the dung trench to the upper surface of the dung trench, and the upper surface of the longitudinal frame beams 230 is flush with the dung-leaking floor, so that the dung trench hangs on the longitudinal frame beams, which are partly accommodated in the dung trench space in the height direction. Therefore, the floor height of the building can be greatly reduced compared with the original traditional design.

As shown in fig. 2B, the longitudinal frame beams are disposed at the upper portion of the dung pit space, so that the height H5 of the building floor can be reduced to 3.2m-3.6m while ensuring a clearance height H4 of 2.25m in the building and a normal operation of the dung scraper. Therefore, the material usage amount of the building structure can be reduced, the building cost and the environmental protection cost can be greatly reduced, and the construction period can be greatly shortened.

In some embodiments, the transverse frame beams of the building house can be used as the side walls of the manure pit, so that the side walls do not need to be separately constructed for the manure pit, the building structural members are reduced, the construction process and the input of building materials such as concrete are reduced, and the building cost is reduced. In some embodiments, the transverse frame beams may be embedded in the load-bearing columns 240 of the frame.

In some embodiments, the load-bearing columns 240 bear the transverse frame beams as the side walls of the dung trench, so that the distribution of the load-bearing columns can be arranged according to the distribution of the columns, the load-bearing requirements can be met, and meanwhile, the load-bearing columns are prevented from occupying the space in the aisle or the columns, which is beneficial to saving the building cost.

In some embodiments, the manure pit floor 210 may be a cast-in-place concrete slab, which may be formed in one step during the casting of the concrete of the cast-in-place slab. In some embodiments, the surface of the dung trench floor 210 may be troweled and integrally formed with the concrete slurry.

In some embodiments, in addition to using waterproof concrete for the floor concrete, a flexible waterproof layer may be coated on the bottom of the manure pit (bottom of the cast-in-place slab) and/or the outside of the side walls of the manure pit, so that water leakage problems such as cracks in the concrete slab may be prevented, costs may be reduced, construction period may be shortened, and space inside the manure pit may not be occupied. In some embodiments, the flexible waterproof layer may be a full batch asphalt mastic. In some embodiments, the surface of the bottom plate 210 is finished by using the raw concrete slurry without a leveling layer, a waterproof layer and a protective layer, so that the height of the excrement trench can be increased, the excrement scraper can conveniently shuttle in the excrement trench, and the waterproof layer on the back of the excrement trench is not damaged.

In some embodiments, the bottom layer dung ditch (i.e. the dung ditch on the first floor of the building) can be separated from the building frame structure, and is not attached to the frame structure, so that the self weight of the building frame structure can be reduced, and the building cost can be reduced. In some embodiments, the bottom manure pit side walls may be cast-in-place concrete walls, the bottom slab may be cast-in-place concrete rafts, and a gravel bed is disposed under the rafts. In some embodiments, the clearance height H6 in the bottom layer manure pit is 600-650 mm. In some embodiments, the height H7 of the side wall of the bottom layer dung trench may be 850-900mm, and the wall thickness G2 may be 200-250 mm. In some embodiments, the floor thickness G3 of the bottom layer manure channel may be 120-150 mm.

Fig. 3 is a partial schematic view of a single-story fecal scraping system according to one embodiment of the present application. In some embodiments, the whole layer can be driven by a dung scraping machine to scrape dung, specifically, the scraping plate can be arranged in the dung ditch, and the steel wire rope 301 is driven by a machine outside the dung ditch to control the movement of the scraping plate, so that the dung can be scraped out. In some embodiments, the exposed part of the steel wire rope 301 of the dung scraping machine (i.e. the outer part of the dung ditch) is sleeved with a PVC protection pipe 302 which is arranged between two adjacent dung ditches, so that the liquid or dung in the dung ditch can be prevented from being brought out of the dung ditch and dropping to the lower layer by the steel wire rope entering and exiting the dung ditch, and thus, the biological safety can be greatly ensured.

Fig. 4 is a partial schematic view of a manure scraping system for each building of a pig raising system according to one embodiment of the present application. In some embodiments, the house dung cleaning mode can be implemented by the whole mechanical dung cleaning, namely a flat scraper dung cleaning mode (referred to as "flat scraper dung cleaning"). Referring to fig. 4, in some embodiments, the second-level dung scraping is omitted in the building, the first-level dung scraping is only adopted, and the dung can be directly discharged through the vertical pipe 250, so that the construction processes of the second-level dung ditch can be reduced, the construction difficulty can be reduced, the construction period can be shortened, and the biosafety independence between units can be ensured.

In some embodiments, the clear excrement mode of this application building house can also be carried out the water bubble excrement, utilizes siphon principle to form the negative pressure promptly, makes the dirty evenly distributed of excrement at the drain of bottom of the pool to discharge in order. For example: the excrement pipe divides the excrement ditch under the leak board of the building into a plurality of sections, a joint is arranged under the excrement ditch of each section, an excrement ditch plug is arranged at the joint of the excrement ditch, and liquid excrement can be remained in the excrement ditch of the building when the excrement ditch plug is plugged. When liquid dung is not discharged, the pipeline is filled with air, when the septic tank is to be emptied, a hook of the dung ditch plug is manually lifted, the dung is discharged from the small-unit dung ditch to the sewage discharge pipeline and flows into the pipeline, the air in the pipeline is gradually discharged, the exhaust valve is automatically opened, when the pipeline is completely filled with the dung, the air in the pipeline is not discharged outwards any more, and the exhaust valve is closed, so that the dung flows into the pipeline and is smoothly discharged under the action of pressure difference by utilizing the vacuum principle.

In some embodiments, the bottom layer of manure channels may be cleaned by soaking manure in water, and the other layers (i.e., 2-4) of manure channels may be cleaned by scraping manure with a flat plate. In some embodiments, the bottom layer manure channels in the birthing house and the nursing house can be cleaned by soaking manure, and the other layers are cleaned by scraping manure. In some embodiments, 12 250mm or 315mm PVC manure pit plugs are provided in the bottom manure pit of the breeding house. In some embodiments, 4 PVC manure pit plugs of 250mm or 315mm per unit are provided in the bottom manure pit of the birthing house. In some embodiments, the arrangement of the faecal plug should be placed in a position in front of or behind the access opening. In some embodiments, an access opening is provided between each two load bearing columns 240. In some embodiments, floor drain drainage is arranged at the passageway positions in the building.

In the buildings of the pig raising system, columns, equipment and the like are required to be added for raising. The application provides a system building house of raising pigs has realized reducing the building area through the arrangement mode in the adjustment building house to and building cost's reduction. In the following, reference will be made to specific breeding buildings, although it will be understood by those skilled in the art that the different breeding buildings may be integrated in the same building.

Fig. 5 is a schematic diagram of a pregnancy shed, according to one embodiment of the present application.

As shown, a plurality of columns 500 may be placed in the building. Wherein column 500 includes side rails 510 and 520 and front door 530 (the door near the pig's head) and back door 540 (the door near the pig's tail). Wherein front doors 530 and rear doors 540 are attached to the ends of side rails 510 and 520, respectively, and enclose an area for receiving a sow. In some embodiments, the sow may enter the field through the back door 540 and exit the field through the front door 530. In some embodiments, the front door 530 is fixed to the ends of the side rails 510 and 520 and cannot be opened, and sows enter the field through the back door and leave the field through the back door. In some embodiments, the side walls 510 and 520 and the front door 530 and the rear door 540 are each formed by joining a plurality of tubes. In some embodiments, the column may also include a trough 550, disposed below the front door 530, that may be used to hold feed for consumption by the sow.

In some embodiments, the front door 530 is disposed at the end of the side rails 510 and 520 with an inclination toward the inside of the column, and the side of the side rails 510 and 520 connected to the front door 530 has an inclined contour. Therefore, the actual clearance of the passageway outside the front door 530 column can be increased, the size of the passageway in the building can be reduced on the premise that the operation space of pigs is ensured, and the building area can be reduced by 1%. In some embodiments, the side of the front door 530 near the trough 550 is closer to the column outer aisle than the side away from the trough 550. In some embodiments, the angle of inclination of the front door may be 70-80 degrees.

Fig. 6A and 6B are schematic illustrations of a birthing house arrangement according to one embodiment of the present application.

As shown, a plurality of rows of beds 610 may be placed in the birthing house 600, wherein each row includes a plurality of beds, each bed being configured to receive a sow for farrowing. In the application, a single-inlet and single-outlet obstetric table is provided, and a sow to be born enters the obstetric table, enters the obstetric table through the rear end of the obstetric table and leaves the obstetric table through the rear end (refer to the direction of the sow entering the obstetric table). In the traditional obstetric table, the sow enters the obstetric table from the rear end of the obstetric table and leaves the obstetric table from the front end of the obstetric table. Thus requiring two rows of channels in front of and behind the obstetric table. After the obstetric table of this application arranges the design, just can cancel the head (being the front end) passageway of obstetric table 610 in the building house when multirow obstetric table arranges, passageway 601 in order to reduce many obstetric tables can be shared to two rows of adjacent obstetric tables in interval, thereby can not set up the passageway (be equivalent to pig head-to-head arrangement) between two rows of inseparable adjacent obstetric tables and can reduce 3% building area of childbirth house, reduce the cost of investment earlier stage.

Referring to fig. 6B, in some embodiments, two rows 610 of beds spaced adjacent to each other may share a manure pit 620, in other words, the manure pit may be disposed below the rear ends of the beds in the two adjacent rows and below the passage therebetween. In some embodiments, the manure-leaking floor is not included at the channel, in other words, the floor at the channel is not hollowed out. When the sow enters the obstetric table, the moving range of the sow is limited, and the excrement ditch is arranged at the rear end of the obstetric table to completely meet the defecation requirement. Above-mentioned design can reduce nearly 50% excrement ditch volume, for in traditional design will arrange the excrement ditch for whole obstetric table below alone, has reduced the weight of building house self and the work load of construction to cost saving that can be very big shortens construction period.

Fig. 7 is a schematic view of a building interior partition according to an embodiment of the present application.

As shown, the internal partition wall 700 includes a brick wall 710 and a partition 720 disposed on the brick wall 710. Only fence is carried out to the pig through set up baffle 720 on brick wall 710, can be satisfying under the prerequisite of collision, impact, reduce construction cost, shorten construction period. In some embodiments, the brick wall 710 is built of 200mm thick blocks of aerated concrete. In some embodiments, the height of the brick wall 710 may be 1 m. In some embodiments, the partition 720 may be a PVC partition, which may reduce square cost, reduce building load, and more thoroughly sterilize to ensure biosafety. In some embodiments, the thickness of the spacer may be 35 mm.

Fig. 8A and 8B are schematic illustrations of ventilation in a building according to one embodiment of the present application. Fig. 8A and 8B show the structure of the pigsty air inlet end and the pigsty air outlet end, respectively.

As shown, the ventilation of the building can be performed in a tunnel ventilation mode, and the air inlet end 810 comprises a protective net 811 and a filter wall 812. The protective net 811 can be used to prevent external animals (such as flies and mice) from entering the building, and the filter wall can be used to filter impurities and viruses from entering the building. In some embodiments, the filter wall includes primary and sub-high efficiency air filtration devices. In some embodiments, the air intake end 810 may further include a water curtain 813, which may be used to adjust the humidity of the air inside the building, and may perform evaporation cooling on the air inside the building. In some embodiments, the size of the water curtain can be adjusted according to the wind speed requirements and design requirements of different buildings. In some embodiments, the intake end 810 may further include a weighted vacuum window 814 that may be used to regulate the amount of air entering the barn. In some embodiments, the protective mesh 811 may be multiple passes, each of which may be used to block a different animal.

As shown, the air outlet 820 includes a high negative pressure blower 821 which can exhaust air from the building, so as to form negative pressure in the building and circulate the air inside. In some embodiments, the high negative pressure blower 821 is equipped with a backflow prevention device (not shown in the drawings), which prevents air from flowing backward, and the discharged air is sent to a deodorization room for deodorization and filtration. In some embodiments, the deodorization room may be independently installed at the air outlet end, in other words, the structure of the deodorization room is independently installed outside the frame structure of the building, and the deodorization spraying device 830 is used to deodorize the extracted air. In some embodiments, the deodorizing chamber may also be deodorized using a filtering device. When the tunnel is ventilated, the high negative pressure fan is started, and wind outside the building enters the building through the water curtain and the counterweight type negative pressure window after passing through the protective net and the filter wall and is discharged from the wind outlet end. In some embodiments, tunnel ventilation may be used in summer.

Fig. 9A-9C are schematic illustrations of ventilation in a building according to another embodiment of the present application. Fig. 9A and 9B show the structure of the air inlet end and the air outlet end of the building respectively.

As shown, ventilation in the building can be in a vertical ventilation mode. The air inlet end 910 comprises a protective screen 911 and a filter wall 912. The protective net 911 can be used to prevent external animals (such as flies, mice, etc.) from entering the building, and the filter wall can be used to filter impurities, viruses, etc. from entering the building. In some embodiments, the filter wall 912 includes primary and sub-high efficiency air filtration devices. Referring to fig. 9C, the building includes a plurality of suspended ceiling windows 913, which may be disposed in the ventilation channels between the adjacent excreta channels or the ventilation channels of the top floor to communicate with the interior of the building, so that air circulating in the ventilation channels vertically enters the building from top to bottom. The side walls of the adjacent dung ditches are used as ventilation channels in winter, so that the ventilation uniformity can be met, the number of air pipe materials can be reduced, and the cost is reduced. In some embodiments, the protective mesh 911 may be multiple guards, each of which may be used to block different animals.

In the vertical ventilation mode, the ceiling window 913 is opened, the water curtain and the counterweight type negative pressure window are closed, and wind outside the building enters the cavity of the adjacent excrement trench of the building after passing through the protective net and the filter wall, vertically enters the building through the ceiling window and is discharged from the air outlet end. In some embodiments, the air discharged from the air outlet 920 may enter a deodorization room for deodorization. In some embodiments, the deodorization room can be independently installed at the air outlet end, in other words, the structure of the deodorization room is independently installed outside the frame structure of the building, and the deodorization spraying device 930 is used for deodorization. In some embodiments, the deodorizing chamber may also be deodorized using a filtering device. In some embodiments, the air outlet end may include a high negative pressure fan 921, which may pump air from inside the building, so that a negative pressure is formed inside the building, and the inside air circulates. In some embodiments, the vertical ventilation mode may be applicable for winter and other transitional seasons.

FIG. 10 is a flow chart of a method for swine breeding according to one embodiment of the present application.

In step 1010, the gilt to be born in the gestational shed is transferred to a farrowing house for farrowing. Sows may be bred in a gestational shed and fed in the gestational shed. In some embodiments, the sow may be transferred from the internal path between houses to a farrowing house on the same floor for delivery 2-3 days before delivery. In some embodiments, the interior road may be an enclosed corridor.

In step 1020, weaned piglets in the farrowing barn are transferred to the same-floor nursery and fattening barn for breeding. In some embodiments, after feeding farrowing sows in a farrowing house for 3 weeks until weaning of the piglets, the piglets may be transferred from an internal road between houses to a nursing home at the same floor for breeding. In some embodiments, farrowing sows may be returned to the gestational facility for the next mating from the internal roadways between houses. In some embodiments, the interior road may be an enclosed corridor.

In some embodiments, piglets may be independently bred in a breeding house. For example, the breeding is carried out in a fattening house for a certain number of weeks and then transferred to a fattening house for breeding. In some embodiments, the nursing house and the fattening house can be independently arranged, the nursing house and the fattening house can be connected through a closed corridor, and the pigs can only be transported in the nursing house and the fattening house on the same floor through the closed corridor. In some embodiments, the pig can be transferred to a fattening house for breeding after being bred in the nursery house for 12 weeks, and then bred in the fattening house for 12 weeks, so that the breeding of the pig is completed.

In step 1030, the bred pigs are only transferred out. In some embodiments, the bred pigs may be transferred to a piggery for marketing. In some embodiments, transfer to the pig house may be via internal roads between pig houses or on-site transport vehicles.

Therefore, the pig raising system makes remarkable contributions in the aspects of biosafety, building cost saving and the like.

Design principles in terms of biosafety include: physical isolation, namely isolating the pig farm from the outside so as to effectively control the swine fever and other pig diseases; reasonably dividing the pig farm and the off-farm area; the pig, the human, the feed, the material and the vehicle all flow in one direction, and the trans-regional flow must have corresponding decrement and physical isolation measures; the effective application of air filtration; independent ventilation, no wind channeling, independent decontamination of each layer and independent pollution discharge.

Through the design and the utilization of the frame beam, the floor height of a building house is reduced, and the construction cost of the excrement ditch and even the whole building is reduced.

By adjusting the feeding mode and period, the feeding area is reduced or the culture efficiency per unit area is improved.

Through the improvement of the obstetric table of the gestational housing, the layout of the dung ditch of the gestational housing is optimized, and the construction cost is reduced.

The above embodiments are provided only for illustrating the present invention and not for limiting the present invention, and those skilled in the art can make various changes and modifications without departing from the scope of the present invention, and therefore, all equivalent technical solutions should fall within the scope of the present invention.

Claims (16)

1. A multi-storey hog house comprising:

the frame comprises a plurality of bearing columns, a plurality of transverse frame beams and a plurality of longitudinal frame beams, wherein the transverse frame beams and the longitudinal frame beams are arranged on the bearing columns and are vertical to each other;

a multi-layered floor slab disposed on the frame;

the excrement leaking floor is arranged between the floor slabs; and

a plurality of dung ditches arranged below the dung leaking floor and used for containing excrement of pigs;

wherein the side walls of the manure pit comprise the transverse frame beams and/or the longitudinal frame beams arranged at the top of the inner space of the manure pit.

2. The building of claim 1 wherein the manure pit includes a floor plate connected to the beam frame beams, mounted on the frame.

3. The building house of claim 2, wherein the floor and the faces of the manure pit floor comprise concrete components, the concrete components being integrally formed.

4. The building house of claim 3, wherein the concrete component comprises impervious concrete.

5. The manure pit of claim 3 or 4, wherein the manure pit comprises a waterproof layer provided on an outer surface of a floor of the manure pit.

6. The building of claim 1, wherein the manure pit disposed at the lowermost floor is not connected to the frame.

7. The building as claimed in claim 1, further comprising a dung scraper which penetrates the inner space of the dung trench of each floor through a wire rope and scrapes dung by using a scraper on the wire rope.

8. The building of claim 7, wherein the steel wire rope passing through the space between two adjacent excretory canals is covered with a protective pipe.

9. The building of claim 7, further comprising a fecal standpipe disposed at one end of the building in communication with the fecal ditch of each floor.

10. A building according to claim 1, wherein the floor height of the building is 3.2m-3.6 m.

11. The building house of claim 1, further comprising a ventilation system, wherein the ventilation system comprises an air inlet end and an air outlet end, and the air outlet end is provided with a negative pressure fan.

12. The building house of claim 11, wherein the air intake end comprises:

a protective net configured to block external animals from entering the building;

a filter wall configured to filter impurities, viruses in air;

a water curtain configured to humidify air entering a building;

and the outside air sequentially passes through the protective net, the filter wall and the water curtain to enter the building.

13. The building house of claim 11, wherein the air intake end further comprises: a negative pressure window configured to control an amount of air the outside air enters the building.

14. The building of claim 12, wherein each roof of the building comprises a ceiling window configured to accommodate vertical entry of outside air into the building, wherein the outside air enters the building through the ceiling window after passing through the protective mesh and the filter wall in sequence.

15. The building house of claim 11, wherein the air outlet end comprises a deodorizing chamber.

16. A building according to claim 15, wherein the load bearing rating of the deodorising block is lower than the load bearing rating of the building.

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