DE2409233A1 - Feed compsn. contg. non-protein nitrogen - and hydrolysed plant matl., giving optimum conversion of energy - Google Patents

Abstract

Compsn. contg. 50-90, esp. 60-70% of its total N as non-protein N (NPN) comprising an acid-hydrolysed polysaccharide-contg. material of vegetable origin (I) and an NPN source (e.g. urea) and opt. other types of feed matl. is improved when (I) has a specific surface of >=10 dm2/g, acid equiv. of 5-50, esp. 20-30 g acetic acid equiv. per kg dry matter, and when it contains 3-20, esp. 8-10 g (I), dry basis per g of NPN. (I) contains >=1 of pentosans, cellulose, lignin or C-contg. matl. The acidity of (I) may be adjusted if necessary with (in)org. acids pref. by vapour treatment. This is a complete feed compsn. and gives max. feed-energy utilisation e.g. energy required to produce 1 kg meat and milk is 15,000 kcal and 800-900 cal resp. (if 19,800 and 1,100-1,200).

Description

D e ctio n in g Ensuring an optimal utilization of feed energy and 50 to 90%, preferably 60 to 70%, of its total nitrogen not as protein nitrogen Monodietic feed containing and method of making the same Die Invention relates to a monodietic that ensures optimal use of feed energy, that is also feed that can be administered alone, in which 50 to 90%, preferably 60 to 7CPz, of the nitrogen are not present as protein nitrogen and by which the utilization of energy is improved, and a method for producing the same.

It is known that the economical feeding of animals on the all over :: Ielt is prevented by the general lack of protein. The protein can from the animal organism in a form degraded to amino acids be included. Efforts are being made to replace at least part of the Proteins by feeding on materials that don't make nitrogen as protein included, known. These attempts led to certain results by adding in the organism the ruminants from this nitrogen, which is not present as protein nitrogen Protein can be synthesized. That in the digestive system of one stomach with several Animals exhibiting cavities in the hydrolysis of non-protein nitrogen existing nitrogen-containing materials (for example urea) inevitably However, released ammonia limits its use because the ammonia level increases of animal blood is increased and shifted to the alkaline range. Even though the ammonia content of the blood in the liver is detoxified by the formation of urea, this process takes place only up to a certain limit, beyond which already Symptoms of poisoning take place, which often lead to the death of the animal. Both This threshold value corresponds to a procedure that is widespread on the operational scale 30% replacement of the total nitrogen requirement by non-protein nitrogen present nitrogen. When this amount of nitrogen is administered as urea a period of 15 to 20 days to get used to it is still required.

In the experiments of Virtanen (Science, 19B6, Volume 153, No. 3 744) was the total nitrogen requirement from urea and from other proteins various nitrogen compounds covered. However, these attempts are only theoretical Significance because only cheinically pure materials (e.g. α-cellulose or sucrose) could be used as feed components.

The different in the acid hydrol.-rse of polysaccharide-containing So-called residues formed from vegetable waste are for feeding purposes under advantageous Conditions applicable. When it comes to animal feed on the basis of by-products it succeeded with a 50% nitrogen utilization To cover 75% of the total nitrogen requirement with urea nitrogen. Included the well-known poisoning hazards are non-existent and it is no getting used to. At the top feeds are to be produced from 1 kg live weight 19,000 to 21,000 calories required (allattenyésztés, 1971, Volume 20, No. 7, page 41). This value corresponds to the general energy utilization of feeding (Nature, 1967, Volume 216, No. 5 116, page 721).

It is also a procedure that addresses the disadvantages of urea feeding by co-administration with inorganic salts, preferably sodium chloride, are known (Hungarian patent specification 156 601).

It has now been found, surprisingly, that with one through Use of treatment products obtained from vegetable waste compound feed produced with a certain quality when dosing the feed components in a certain ratio the degree of energy utilization increases and also the other properties of the mixture improve noticeably, the extremely high Ratio of urea nitrogen to total nitrogen of 75% and the 50% nitrogen utilization remain unchanged. This product of special quality and composition represents a 20 to 25% increase in the conversion of nutrients into energy for sure. Awake the test results of the applicant increases the energy utilization so that the energy consumption in meat production of the usual value of 19 800 kcal / kg drops to 15,000 kcal / kg, while in milk production instead of the usual values from 1,100 to 1,200 cal / kg values of 800 to 900 cal / kg are achieved, the Proportion of nitrogen not present as protein nitrogen in the total nitrogen content of Feed is 50 to 90%.

The invention is based on the finding that the in from vegetable Treatment products of certain quality obtained from waste materials are present high energy carbohydrates at a given. Ratio of these treatment products to a nitrogen-containing material not present as protein nitrogen by assimilating the nitrogen that is not present as protein nitrogen Microorganisms: can be used much better because they multiply Microorganisms mainly an optimal amount due to the large surface area of the abovementioned aterial bound short-chain fatty acids is required.

The subject of the invention is therefore an optimal feed energy utilization ensuring and 50 to 90%, preferably 60 to 70.0 ', of its total nitrogen Mono-dietetic feed not containing as protein nitrogen from a through acid hydrolysis of polysaccharide-containing materials of vegetable origin Material and / or mixture of such and one not considered protein nitrogen present nitrogen-containing material, e.g. urea, and possibly other types of feed, which is characterized in that the by acid hydrolysis of polysaccharide-containing materials of vegetable origin obtained material or mixture of such such a one from 1 or more pentosans, cellulose, lignin and / or carbon containing materials dissipative material, which has a specific surface area of at least 10 dm2 / g and an acid content of 5 to 50 g acetic acid equivalent / kg dry substance, preferably 10 to 45 g acetic acid equivalent / kg dry substance, in particular 20 to 30 g acetic acid equivalent / kg Dry matter, has, and is the amount of dry matter of the acidic solid of vegetable origin per g not as protein nitrogen present Nitrogen is 3 to 20 g, preferably 5 to 18 g, in particular 8 to 10 g.

The subject of the invention is also a process for the production of the Feed according to the invention, which is characterized in that the on a specific surface of at least 10 dm2 / g, expediently by hydrolysis, crushed dry material of vegetable origin and / or mixture of such until the acid content of 5 to 50 g acetic acid equivalent / kg dry substance is reached is acidified and the product obtained with that not present as protein nitrogen Nitrogen-containing material and optionally the other types of feed homogenized will.

According to an advantageous embodiment of the method according to the invention the acidification of a specific surface area of at least 10 dm2 / g vegetable material with an inorganic acid and / or a low molecular weight organic acid, preferably carried out with steam treatment.

The organic ones on the large specific surface In addition to slowing down the release of ammonia, acids can also act as eilie easily usable energy source for the microorganisms that serve on such other than processing what is not present as protein nitrogen Nitrogen also special quality product polysaccharides in one to implement excellent yield.

Another advantage of the feed according to the invention is that that its use does not require special feed additives that are difficult to obtain, but also together with others on local farms Place available chucks can be used.

The compound feed according to the invention is a non-dietetic feeding feasible by doing it without any getting used to any season or whole Year can be administered continuously without feeding with other feeds.

The invention is not to be construed as a limitation on the basis of the following Examples explained in more detail.

Example 1 Various polysaccharide-containing materials were used treated according to Table 1. The selected raw material vX was under atmospheric pressure sprinkled with water containing 4% acetic acid up to a moisture content of 40% and then under a pressure of 10 atm with saturated steam for 1 hour on one Maintained temperature of 17500, with the tightness of the steam 2.4 times the dry matter content of the raw material.

Table 1 Raw material Moisture Properties of the treated material before after Acetic acid content * Water content Specific surface ** Berie- Ber- in in in selung selung g acetic acid equi-% dm2 / g in in valent / kg dry %% substance Corn on the cob 18 40 26 43 85 Corn on the cob 29 41 25 44 80 Corn lice 24 39 27 42 22 Corn stover 32 41 25 44 43 Sunflower 13 39 25 41 20 core shell Table 1 continued Raw material Moisture Properties of the treated material before after Acetic acid content * Water content Specific surface ** Berie- Ber- in in in selung selung g acetic acid equi-% dm2 / g in in valent / kg dry %% substance Beech wood 25 41 27 43 34 sawdust * The weighed amount of the treated material was shaken for 1 hour with 0.01 N KOH, then the pH was determined and the acetic acid equivalent was calculated from this. ** The specific surface area was determined by the BET method using helium adsorption Proceeded as described in Example 1, but with the difference that the material was treated under a pressure of 10 atmospheres at 175 ° C., whereupon it was allowed to relax before cooling to atmospheric pressure. The system was then placed under vacuum and its moisture content was reduced to values from 16 to 20:% / compared to the values given in Example 1.

Example 3 The procedure described in Example 1 was followed, however with the modification that the material instead of the 4% acetic acid containing water svurde sprinkled with a calculated amount of glacial acetic acid, eliminating the in the following Table 2 compiled values were obtained.

Table 2 Raw material Moisture properties of the treated material hold on Acetic acid content Water content Specific surface spray in in in in g acetic acid equi-% dm2 / g % valent / kg dry substance Corn on the cob 23 28 26 105 Corn on the cob 17 50 19 120 Corn lice 21 40 24 35 Sunflower 15 28 17 33 core shell @ uchenholz- 28 28 31 42 sawdust Example 4 Any material obtained according to Example 1 or 3, as well as urea, corn meal, alfalfa flour, dried beet pulp from sugar factories and the other materials specified below, are used in the amounts according to the following recipes.

A B Corn meal 12.50% by weight 7.14% by weight Lucerne flour 6.00% by weight 3.56% by weight dry beet pulp, 37.00% by weight silage corn - 60.70% by weight molasses 6.50 wt% 3.65 wt% urea 3.00 wt% 2.00 wt% feed salt z 1.00 wt% 0.80% by weight mineral premix of 1.00% by weight 0.80% by weight type AP 18 Any material according to 33.00% by weight - Example 1 Any material according to - 15.35% by weight Example 3 Water - 6.00% by weight 100.00% by weight 100.00% by weight Comment: The percentage composition given above relates to feed with the usual moisture levels.

Mixture B can also be subjected to a previous homogenization of the after Example 3 of the material produced with the mineral premix and with the urea and a subsequent 2-month storage can be generated.

The mixture weighed together with the exception of the molasses was in a Rotary drum with a horizontal axis, which is used to promote the mixing of the material padded, stirred for 45 minutes. During this treatment was the molasses sprayed into the drum.

The feed mixture labeled A above became that in the next Test group no. 8 listed below in Table 3 and also there 6, 7 and 9, but the last three with the modification that the weight ratio of the dry matter content of the respective Material according to Example 1 for the H 'present in the feed: urea nitrogen (at unchanged ratio of the other components) was 2, 3 and 21 respectively. The butter mixture of Composition B became that of the following Test group no. 1 given in Table 4.

Example 5 The material produced from corn on the cob according to Example 1 became so at 130 ° C under atmospheric pressure with superheated steam Long treated until a material is found with an unchanged specific surface with an acid content of 3 or 5 g acetic acid equivalent / kg dry substance revealed. The materials produced from the materials according to Example 4 thus obtained of composition A were those in Table 3 below Test groups No. 1 and 2 administered. I.it the one treated according to Example 3 Acid content of 50 g acetic acid equivalent / kg corn on the cob containing dry egg substance a mixture of composition A was prepared according to Example 4 and this was administered to test group no. 3 in Table 3 below.

Example 6 From any material produced according to Example 2 a mixture of the composition W was prepared according to Example 4 and this was administered to test group No. 11 shown in Table 3 below Example 7 The one treated according to Example 3 has an acid content of 28 g acetic acid equivalent / kg Beechwood sawdust containing dry substance according to Example 4 of composition A became that in Table 3 below Test group no. 10 administered.

Example 8 Corn on the cob according to Example 1 were treated in the manner that is finally achieved by a suitable change in the type of surface enlargement a product with a specific surface area of 8 and a product with a specific The surface area was 12 dm2 / g, but the acid content remained unchanged stayed. Mixtures of composition A are prepared from these according to Example 4 and the test group no. 5 listed in Table 3 below and 4 administered, respectively.

The test conditions and results for the out of 10 Hungarian 12 test groups made up of colored fattening bulls are listed in Table 3 below.

The fattening bulls consumed the feed during a fattening period (from approximately 6 months).

Tabel @ Experimental parameters of the feed energy utilization group in Acidity Specific Upper Hydrolyzed number kcal / kg meat in area of hy- dry matter g acetic acid-drolyzed male equivalent / kg teriales g / g not as Dry matter in protein stick dm2 / g substance available- the nitrogen 1 3 20 10 - 2 5 20 10 19 500 3 50 20 10 19 500 4 25 to 28 12 10 15 700 5 25 to 28 8 10 - 6 25 to 28 20 2 - 7 25 to 28 20 3 23 600 Table 3 continued Experimental parameters of the feed energy utilization group in Acidity Specific Upper Hydrolyzed number kcal / kg meat in area of hy- dry matter g acetic acid-drolyzed male equivalent / kg teriales g / g not as Dry matter in protein stick dm2 / g substance available- the nitrogen 8 25 to 28 20 10 15 300 9 25 to 28 20 21 20 400 10 25 to 28 20 8 14 200 11 25 to 28 20 10 14 800 Comparison or control group with a dem 12 19 670 Feeding appropriate to the nutritional needs Evaluation of table 3 Trial evaluation groups- number Symptoms as a result of the low acidity 1 ammonia poisoning, the experiment was canceled posed. Although ammonia poisoning did not occur, was 2 | the feed from the animals as a result of the behavior not particularly low acidity which is economically exploited. Although ammonia poisoning did not occur, was 3 | the feed from the animals as a result of the behavior moderately high acidity not particularly economically exploited. No ammonia poisoning, economical poisoning evaluation. As a result of the low specific surface 5 symptoms of ammonia poisoning, the trial it was turned off. Due to lack of hydrolyzed material 6 symptoms of ammonia poisoning, the trial was turned off. Although there was no ammonia poisoning, 7 poor feed conversion due to lack of hydrolyzed material. No ammonia poisoning, winter poisoning 8 Pure ammonia poisoning, economical evaluation.

Continuation of the evaluation of table 3 Trial evaluation groups- number Although there was no ammonia poisoning, 9 poor feed conversion due to over- shot of hydrolyzed material. No ammonia poisoning, economical poisoning 10 evaluation. No ammonia poisoning, economical poisoning 11 evaluation.

Example 9 Composition B was fed to dairy cows for 6 months administered. DiC results are compiled in Table 4 below.

Table 4 Experiment No. 1 Experiment No. 2 Number of animals in group 100 100 Acidity in 40 conventional g acetic acid equivalent / kg dry matter feeding (Corn lice according to Example 3) Specific surface conventional in 35 feeding dm2 / g Dry matter per g not conventional as protein nitrogen 8 present nitrogen feeding Average milking in kg 15 12 Milk fat in% 3.7 3.4 Energy recovery, expressed as energy consumption 828 1 127 in cal / kg milk Claims

Claims (3)

Claims 1.) Ensuring optimal feed energy utilization and 50 to 90%, preferably 60 to 70%, of its total nitrogen not as protein nitrogen containing monodietic feed from a food containing polysaccharides by acid hydrolysis Materials of vegetable origin obtained material and / or a mixture of those and a nitrogen not present as protein nitrogen Material, expediently urea, and possibly other types of feed, characterized in that the acid hydrolysis of polysaccharide-containing Material of vegetable origin obtained material or mixture of such one such as 1 or more pentosans, cellulose, lignin and / or carbon containing materials dissipative material, which has a specific surface of at least 10 dm2 / g and an acid content of 5 to 50 g acetic acid equivalent / kg Dry substance, preferably 10 to 45 g acetic acid equivalent / kg dry substance, in particular 20 to 30 g acetic acid equivalent / kg dry substance, is and the amount of dry matter of the acidic solid of vegetable origin per g Nitrogen not present as proton nitrogen 3 to 20 g, preferably 5 to 18 g, in particular 8 to 10 g. 2.) A method for producing the feed according to claim 1, characterized characterized in that one has a specific surface area of at least 10 dm2 / g, expediently by hydrolysis, crushed dry material of vegetable origin and / or a mixture of so lehen until the acid content of 5 to 50 is reached g acetic acid equivalent / kg dry matter acidified and the received Product with the nitrogen that is not present as protein nitrogen The material and, if necessary, the other types of feed are honed. 3.) The method according to claim 2, characterized in that the Acidification of the vegetable which has a specific surface area of at least 10 dm2 / g Material with an inorganic acid and / or a low molecular weight organic Acid, preferably with steam treatment.