RU2051573C1 - Rabbit growing method - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves growing rabbits at low temperatures (12 C below zero to 8 C) with the use of artificial cold produced by natural gas expansion at gas-distributing stations and transferred first to some circulating neutral cooling agent and then to air to be cooled. The viability of rabbits is virtually 100%. EFFECT: high liveweight gain; high quality of hides. 10 cl, 1 dwg

Description

 The invention relates to agriculture and may find application in the cultivation of rabbits by industrial methods.

 In the summer period of time, and in the southern latitudes almost all year round, the high ambient temperature is a serious obstacle to the highly productive raising of rabbits both indoors and outdoors. The main reason is associated with overheating of animals, deterioration of their appetite and related diseases. In addition, rabbits suffer from parasitic insects that are particularly active in a warm and humid environment. All this leads to irreparable loss of live weight and a decrease in the quality of the skin.

 To improve the conditions for growing rabbits, it is advisable to keep them all year round at a low temperature, using artificial cold.

A cage for breeding rabbits is known. The cage is made of heat and electrical insulating material that is resistant to the claws and teeth of rabbits and is easily disinfected. The ceiling and / or side walls of the cell may contain an electrical equipment system with or without temperature control [1]
The main disadvantage of this invention is the inability to maintain the temperature in the cage for breeding rabbits below ambient temperature.

Closest to the invention is a method of growing rabbits in enclosed spaces, including keeping rabbits under artificial light in the cells [2]
The main disadvantage of this method is the impossibility of lowering the temperature of rabbits in the summer period below the ambient temperature, although the author of the selected prototype himself indicates the positive effect of lower temperatures on the quality of the skins. In particular, he wrote: "For example, when Contents of up to 165 days of age when exposed to light 12 hours a day at ambient temperature, ^about 9-13 C can receive 64% of the skins of the 1st grade, and at a temperature of 19-26 ^о С and the same light mode, this indicator is almost 5 times lower and makes up only 13%
In addition, the analysis of the data provided by the prototype author on the content of the control group of rabbits (outdoors; under natural light) shows that the number of skins of the 1st grade at 165 days of age and a temperature of 2 - (- 8) ^о С is 57% at a temperature of 18-19 ^about 0% (i.e. the complete absence of skins of the 1st grade).

 The task underlying the present invention is the development of a method of growing rabbits, providing the possibility of their year-round keeping under natural and artificial lighting and at low temperatures with the achievement of maximum meat productivity and high quality fur skins. At the same time, energy consumption for the production of artificial cold should be minimal. The way to get cold should be environmentally friendly.

 The problem is solved by obtaining refrigeration at gas distribution stations of natural gas (GRS) or substations (hydraulic fracturing), transferring this refrigeration to a liquid neutral refrigerant that “conveys” cold, circulating between hydraulic fracturing (hydraulic fracturing) and rabbitry, and cooling the air entering the enclosed space (or on a semi-open area) for raising rabbits.

 Cold is produced by utilizing the existing differential pressure of natural gas, which is currently irretrievably lost to gas distribution and hydraulic fracturing during conventional throttling.

 As a cold generator (depending on specific conditions and capabilities), any known device that converts gas pressure energy can be used: expanders, pulsating gas coolers (POG), vortex tubes, gas-dynamic refrigeration machines (GDM), etc. The expander is a fairly a complex and expensive machine, however, it has high refrigeration efficiency and can be used on powerful gas distribution stations and hydraulic fracturing, which provide large energy facilities with natural gas (for example, thermal power plants, compressor stations, etc.). Pulsation gas coolers are somewhat simpler than turbo expanders, but they are rather bulky and have certain performance limitations. GDM are relatively simple, but require direct contact of the coolant and natural gas in the Loval nozzle, which is not always acceptable.

 The simplest and most reliable device for obtaining cold in the conditions of gas distribution and hydraulic fracturing is, according to the authors, the Rank-Hills vortex tube. In terms of cooling capacity, it significantly exceeds the usual throttle valve and is not inferior in this indicator to POG and GDHM. However, having a low cost and low operating costs, it is quite competitive with the most efficient cold expander generator.

As neutral refrigerant and can use a wide range of substances in r. H. The ordinary water (at a temperature of cooling from + 2-3 ° ^C), based brines of sodium chloride and calcium chloride, ethylene glycol (diethylene glycol), and others.

The essence of the invention lies in the fact that in the proposed method of raising rabbits, the regime of low temperatures, regardless of the time of year and climatic zone. Thus animals are preferably at temperatures from minus 12 to plus 8 ° ^C. In a possible combination with artificial illumination this technique can significantly improve the quality of fur skins and to increase the average live weight of rabbits.

 The scheme for producing artificial cold based on GDS and hydraulic fracturing guarantees low energy consumption, which ensures the overall profitability of the process of raising rabbits at a high level. Moreover, in the technological chain there are no refrigerators with freon, propane, and ammonia cycles, which, along with high energy consumption, are environmentally unsafe.

 The drawing shows as an example a flow chart of a complex for raising rabbits at low temperatures in the warm season using a vortex tube.

 It consists of a vortex tube 1, a gas-liquid heat exchanger 2 and a pump 3, which are located on the gas distribution system, as well as an air cooler 4 located directly in the rabbitry.

Natural gas with a temperature of 15-20 ^{° C} and high pressure (35-40 kg / cm ^2). It is sent to the vortex tube 1, where it expands, twists and splits into two streams. One, called the cold stream, goes through the diaphragm; the second, called the hot stream, goes in the opposite direction.

A cold stream with a temperature of -10 - (- 30) ^о С enters heat exchanger 2, where it gives its cold to an inert refrigerant and then mixes with a hot stream under a pressure of 6-7 kg / cm ² (temperature 40-60 ^о С) and goes to low pressure trunk pipeline.

Refrigerant with a temperature of -5 - (- 25) ^о С is transported by means of pump 3 to rabbitry. Here, in the air cooler 4, it contacts the air that enters the rabbitry premises, cooling it to a temperature of 0 - (- 20) ^о С. Moreover, the air at the inlet of the apparatus 4 is partially sucked from the atmosphere, and partially comes from the same rabbitry (recirculation ) Thus, the cooling and ventilation systems are combined, as it were. It is possible to fully combine these systems when air recirculation is not provided.

 Their complete separation is also possible. In this case, cold air is recycled through special air ducts and the cold is transferred to the rabbitry through its wall. The second option is more cumbersome to implement, it cannot be preferred, because in this case, drafts are minimized.

 For small rooms, it is possible to directly transfer the cold from pipes through which the liquid refrigerant circulates to the chilled air of rabbitry. This technical solution somewhat simplifies the scheme, because no air cooler needed, does not require an increase in pump power 3.

 The issue of dividing the cold as a whole for individual volumes of the premises for rabbits can be solved in different ways, depending on the specific conditions of the animals.

 So the ventilation system (or ducts) can provide for the sequential movement of cold air from the compartment (box) into the compartment with its gradual heating (as conditionally shown in the figure). At the same time, various "climatic zones" are formed, which will allow for keeping groups of animals of different ages at optimal temperatures.

 It is possible to place several air coolers in one rabbitry (for example, one per compartment) or create a system for the parallel distribution of chilled air. This allows for flexible temperature control in a separate compartment, regardless of others.

 In addition to enclosed spaces, a scheme for using cold in conditions of keeping rabbits in half-open areas with a canopy and continuous fence around the perimeter (air-permeable fence) is provided. In this case, heavier cold air is fed into the "air bath" formed by the field and the fence, where rabbit cages or the so-called mini-farms (Mikhailov I.N. “What does a rabbit need. L. 1991).

 As it heats up, the exhaust air rises and leaves the environment. This ensures simultaneous temperature control and ventilation of the space where the rabbits are placed.

This method allows contents to maintain the temperature in the rabbitry from 2 to 8 ^{° C,} which is quite efficient and cost in the summer time and in hot climates.

 The vortex tube used is equipped with a device for automatically controlling the flow of compressed gas, which ensures the possibility of its operation in the GDS (hydraulic fracturing) circuit, as a conventional throttle valve. The temperature regime of the vortex tube itself is set using the control valve 5 in the hot stream.

 Defrosting the rabbitry refrigeration system can be quickly accomplished by reversing the cold and hot flows. In this case, the heated gas enters the heat exchanger 2 and gives off its heat to the circulating liquid. She, in turn, heats the entire rabbitry refrigeration system.

 Keeping rabbits at low temperatures begins at 30 days of age after the young has formed a coat. The temperature of the contents is gradually (over several days) reduced from plus to minus values in order to ensure the gradual adaptation of rabbits and avoid diseases from hypothermia.

 The method is implemented as follows.

 PRI me R. Silver rabbits are kept in mesh cages in a closed room equipped with a vortex tube-based refrigeration system.

From 30-day-old young animals begin to adapt to low temperatures, gradually lowering the temperature of the air in the room to 8 ^C and then to minus 12 ° ^C Room lighting either natural or artificial (9 to 12 hours per day).

Rabbits of all ages are fed with a high-protein granular mixed feed containing 158 g of digestible protein in 1 c.e. At six months of age, rabbits had an average live weight of 5.0 kg. All skins handed over after 165 days of cultivation were evaluated by grades 1 and 2, while the share of skins of the 1st grade was 75% and the proportion of skins of the 2nd grade was 25%
Using the proposed method of growing rabbits allows you to provide the following advantages: to ensure high quality rabbit skins with grades of only 1 and 2 grades; provide high live weight of rabbits; to ensure almost 100% safety of the livestock of rabbits; ensure minimal energy consumption for the production of artificial cold; to provide the opportunity to effectively raise rabbits on subsidiary farms of the gas and energy industries, maximally bringing the premises for raising rabbits to sources of throttling of compressed gas and producing artificial cold.

Claims (10)

1. METHOD OF BREEDING RABBITS, including their content in the summer and hot climatic zones at low temperatures, characterized in that the air temperature is maintained mainly in the range from minus 12 to plus 8 ^o C by using artificial cold obtained by expanding natural gas to gas distribution substations, and its subsequent transfer to a circulating neutral refrigerant and then to the refrigerant and then to the cooled air.  2. The method according to claim 1, characterized in that the content of rabbits at a reduced temperature is carried out either under natural or artificial lighting. 3. The method according to PP.1 and 2, characterized in that the content of rabbits at a reduced temperature mainly from minus 12 to plus 8 ^o C is carried out in closed rooms with convective air cooling directly with neutral refrigerant circulating through the cooler pipes.  4. The method according to claims 1 to 3, characterized in that the cold from the neutral refrigerant is transferred by means of an air cooler to either the air directly circulating in the room or through the walls of special air ducts. 5. The method according to PP. 1 to 4, characterized in that the content of rabbits at a reduced temperature is preferably from plus 2 to plus 8 ^o C is carried out on semi-open areas by supplying cold air to the lower, fenced part, where cages or mini-farms with animals are installed, without subsequent circulation.  6. The method according to PP. 1 to 5, characterized in that the content of rabbits at a low temperature begins with 30 days of age.  7. The method according to claims 1 to 6, characterized in that the expander, pulsating gas coolers, gas-dynamic refrigeration machines, Rank-Hills vortex tubes are used as a cold generator when expanding natural gas.  8. The method according to claims 1 to 7, characterized in that the vortex tube is equipped with a device for automatically controlling the flow of natural gas.  9. The method according to PP. 1 to 8, characterized in that as a neutral refrigerant use water, brines based on sodium chloride and calcium chloride, solutions of ethylene glycol and diethylene glycol.  10. The method according to PP.1 to 9, characterized in that the heating of the refrigeration system is carried out using a hot stream of a vortex tube.

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