阅读说明：本技术 一种大黄鱼仔稚鱼饲料及其加工工艺 (Feed for pseudosciaena crocea larvae and juvenile fish and processing technology thereof ) 是由 艾庆辉 王震 张璐 薛敏 麦康森 徐玮 万敏 张彦娇 周慧慧 于 2021-01-18 设计创作，主要内容包括：本发明提供一种大黄鱼仔稚鱼饲料,其颗粒是由壁材包裹由饲料主要成分制备而成的芯材构成,所述壁材主要由鱼油和硬脂酸构成。本发明还提供大黄鱼仔稚鱼饲料的加工工艺。该大黄鱼仔稚鱼饲料以鱼油和硬脂酸为主要成分为壁材对饲料颗粒进行包被,在饲料颗粒表面形成不溶于水且具备诱食性包膜,既提高饲料在水中的稳定性,又促进大黄鱼仔对饲料的摄取,而且又具有良好的体内消化性,有利于大黄鱼仔对饲料的吸收利用。(The invention provides a pseudosciaena crocea fry and young fish feed, wherein particles of the pseudosciaena crocea fry and young fish feed are formed by wrapping a core material prepared from main feed components by a wall material, and the wall material mainly comprises fish oil and stearic acid. The invention also provides a processing technology of the pseudosciaena crocea larvae feed. The feed for the pseudosciaena crocea larvae is prepared by coating feed particles by taking fish oil and stearic acid as main components as wall materials, forming a water-insoluble and food-attracting coating on the surface of the feed particles, improving the stability of the feed in water, promoting the feed intake of the pseudosciaena crocea larvae, having good in-vivo digestibility and being beneficial to the absorption and utilization of the pseudosciaena crocea larvae on the feed.)

1. The pseudosciaena crocea fry and young fish feed is characterized in that particles of the pseudosciaena crocea fry and young fish feed are formed by wrapping a core material prepared from main feed components by a wall material, wherein the wall material mainly comprises fish oil and stearic acid.

2. The feed for pseudosciaena crocea larvae as claimed in claim 1, wherein the core material and the wall material both contain fish oil, wherein the content of the fish oil in the core material is greater than that in the wall material.

3. The feed for the larval and young large yellow croakers as claimed in claim 2, wherein the sum of the mass fractions of the fish oil in the core material and the wall material accounts for 6-7% of the total mass of the main components of the feed.

4. The feed for the pseudosciaena crocea larvae and juveniles as claimed in claim 1, 2 or 3, wherein the core material is prepared from the following main feed components in percentage by mass: fish oil, 40-50% of white fish meal, 20-30% of low-temperature krill powder, 3-4% of low-temperature wall-broken yeast powder, 2-4% of dried internal organ powder of cuttlefish, 4-6% of strong flour, 2-4% of alpha-starch, 1-3% of sodium alginate, 4-6% of soybean lecithin powder, 0.1-0.3% of choline chloride, 0.1-0.3% of L-ascorbic acid-2 phosphate, 1-3% of monocalcium phosphate, 1-2% of vitamin premix, 0.5-1% of mineral premix, 0.01-0.05% of mildew inhibitor and 0.01-0.05% of antioxidant; wherein the sum of the mass fractions of the fish oil and the wall material is 6-7% of the total mass of the main components of the feed, and the mass fraction of the core material is greater than that of the wall material.

5. The feed for the pseudosciaena crocea larvae and juveniles as claimed in claim 1, 2 or 3, wherein the core material is prepared from the following main feed components in percentage by mass: fish oil, 45% of white fish meal, 22% of low-temperature krill meal, 3.5% of low-temperature wall-broken yeast powder, 3% of dried squid viscera powder, 5% of strong flour, 3% of alpha-starch, 2% of sodium alginate, 5% of soybean lecithin powder, 0.2% of choline chloride, 0.2% of L-ascorbic acid-2 phosphate, 2% of monocalcium phosphate, 1.5% of vitamin premix, 1% of mineral premix, 0.05% of mildew preventive and 0.05% of antioxidant; wherein the sum of the mass fractions of the fish oil and the wall material is 6.5 percent of the total mass of the main components of the feed, and the mass fraction of the core material is greater than that of the wall material.

6. The feed for pseudosciaena crocea larvae according to any one of claims 2 to 5, wherein the mass ratio of the fish oil in the core material and the wall material is 1-3: 1.

7. The feed for pseudosciaena crocea larvae and juveniles as claimed in any one of claims 2 to 5, wherein the amount of stearic acid is 0.5 to 1% of the total mass of the coated feed particles.

8. The process for preparing feed of pseudosciaena crocea larvae and juveniles as claimed in any one of claims 2 to 7, wherein the fish oil and stearic acid are heated and melted, coated on the outer surface of a core material prepared from the main ingredients of the feed, and dried to obtain the finished feed.

9. The processing technology of the pseudosciaena crocea larvae feed as claimed in claim 8, wherein the preparation process of the core material is as follows:

(1) weighing dry cuttlefish viscera powder, choline chloride, white fish meal, low-temperature krill powder and low-temperature wall-broken yeast powder according to a certain proportion, uniformly mixing, and granulating to obtain premix 1 for later use;

(2) dissolving sodium alginate in water according to a certain proportion, adding strong flour, alpha-starch, soybean lecithin powder, L-ascorbic acid-2 phosphate, monocalcium phosphate, vitamin premix, mineral premix, mildew preventive and antioxidant according to a certain proportion, and mixing uniformly to obtain premix 2 for later use;

(3) and (3) mixing the premix 1 in the step (1) and the premix 2 in the step (2) with fish oil, curing, and granulating to obtain core particles.

10. The processing technology of the feed for pseudosciaena crocea larvae as claimed in claim 9, wherein in the step (1), the particle fineness of the premix 1 is 100-200 meshes; in the step (2), the mass of the water is 9-12 times of that of the sodium alginate; in the step (3), the mixing time of the premix 1 and the premix 2 with the fish oil is 200-250 s; in the step (3), the curing temperature is 80-90 ℃, and the curing time is 20-30 min; in the step (3), wet granulation is adopted to prepare micro-granular feed with the grain diameter of 0.2mm, and hot air drying is carried out for 30-45min at the temperature of 50-60 ℃; in the step (4), the fluidized bed coating process is uniformly sprayed on the surface of the feed.

Technical Field

The invention belongs to aquatic feed, and particularly relates to pseudosciaena crocea fry and young fish feed. Meanwhile, the invention also relates to a processing technology of the pseudosciaena crocea larvae feed.

Background

Not only is the feed formula influenced by the feed cultivation effect, but also the processing technology is an important link for controlling the feed quality. In the cultivation of the seawater fish larvae, besides the requirement of balanced nutrition and easy digestion and absorption of the feed, the requirement of proper particle size, good food calling property and stability in water is also required, and the physical properties are realized by proper processing technology.

The current processing technology of the feed for the fish larvae is mainly divided into the following 3 types: slightly sticky feed, micro-coated feed and micro-encapsulated feed. The slightly-sticky feed mainly uses an adhesive to bond the raw materials of the word and the material together, and is simple in manufacturing process, low in cost and free of potential toxic substances, so that the slightly-sticky feed is a process adopted by most manufacturers; but has the disadvantages of rough particle surface, easy water penetration and easy rapid loss of water-soluble substances. The microcapsule feed generally adopts a mode of spraying and embedding the raw materials after superfine grinding and mixing, and the sprayed homogeneous mucus is used for wrapping the raw materials inside, but the contradiction between the water solubility of wall materials and the digestibility of capsules is always an unsolved problem; in addition, the particle size of the resulting feed particles also varies widely. The micro-coated feed is prepared by wrapping a layer of wall material outside the micro-sticky feed, so that the stability of the feed in water can be improved, the process is relatively simple and stable, and the problem that the wall material has the stability in water and the digestibility of fish bodies needs to be solved.

The large yellow croaker is commonly called yellow croaker and is a main mariculture variety in China, the yield is over 20 ten thousand tons in 2019, and the economic value is huge. In the breeding industry of large yellow croakers, the breeding survival rate and the growth effect of the larvae are always one of the bottlenecks restricting the development of the industry, the feed is the only source for obtaining the nutrition required by the growth and survival of the larvae, and the quality of the feed directly influences the success rate of the fry. However, for a long time, the production of the feed for the larvae and the juveniles in China is still at a medium level, and the fry breeding process excessively depends on biological bait, which not only causes the waste of resources, but also restricts the expansion of the fry breeding scale. Therefore, how to produce the feed with balanced nutrition, good stability, low process difficulty and good digestion and absorption by utilizing the improvement of the process becomes a problem to be solved urgently in the pseudosciaena crocea larval and juvenile industry.

Disclosure of Invention

The invention aims to provide a pseudosciaena crocea fry and young fish feed. The feed takes fish oil and stearic acid as main components and is coated on feed particles, a water-insoluble and food-attracting coating is formed on the surface of the feed particles, the stability of the feed in water is improved, the feed intake of large yellow croakers is promoted, the feed has good in-vivo digestibility, and the feed can be absorbed and utilized by the large yellow croakers.

One of the purposes of the invention is to provide a scheme as follows: a feed for the larvae and juveniles of pseudosciaena crocea is characterized in that particles of the feed are formed by wrapping a core material prepared from main feed components by a wall material, and the wall material mainly comprises fish oil and stearic acid.

Stearic acid is octadecanoic acid, is solid at normal temperature, is liquid after being heated and is insoluble in water, and can be sprayed on the surface of feed particles as a wall material to form a water-insoluble coating again at normal temperature, so that the stability of the feed in water is improved. The fish oil and the stearic acid are mutually soluble when heated and melted, and the fish oil has food calling performance on the fish, so that the feed can still have food calling performance even if the feed is coated with the stearic acid.

As an embodiment of the present invention, the core material and the wall material both contain fish oil, wherein the content of the fish oil in the core material is larger than that in the wall material. As an example, the total amount of the fish oil in the core material and the wall material accounts for 6-7% of the total mass of the main ingredients of the feed.

The core material is prepared from the following main feed components in percentage by mass: fish oil, 40-50% of white fish meal, 20-30% of low-temperature krill powder, 3-4% of low-temperature wall-broken yeast powder, 2-4% of dried internal organ powder of cuttlefish, 4-6% of strong flour, 2-4% of alpha-starch, 1-3% of sodium alginate, 4-6% of soybean lecithin powder, 0.1-0.3% of choline chloride, 0.1-0.3% of L-ascorbic acid-2 phosphate, 1-3% of monocalcium phosphate, 1-2% of vitamin premix, 0.5-1% of mineral premix, 0.01-0.05% of mildew inhibitor and 0.01-0.05% of antioxidant; wherein the sum of the mass fractions of the fish oil and the wall material is 6-7% of the total mass of the main components of the feed, and the mass fraction in the core material is distributed according to specific conditions and is larger than the content in the wall material.

Preferably, the core material is prepared from the following main feed ingredients in percentage by mass: fish oil, 45% of white fish meal, 22% of low-temperature krill meal, 3.5% of low-temperature wall-broken yeast powder, 3% of dried squid viscera powder, 5% of strong flour, 3% of alpha-starch, 2% of sodium alginate, 5% of soybean lecithin powder, 0.2% of choline chloride, 0.2% of L-ascorbic acid-2 phosphate, 2% of monocalcium phosphate, 1.5% of vitamin premix, 1% of mineral premix, 0.05% of mildew preventive and 0.05% of antioxidant; wherein the sum of the mass fractions of the fish oil and the wall material is 6.5 percent of the total mass of the main components of the feed, and the mass fraction in the core material is distributed according to specific conditions and is larger than the content in the wall material. The fish oil is refined fish oil.

According to one embodiment of the invention, the mass ratio of the fish oil in the core material and the wall material is 1-3: 1.

As an embodiment of the invention, the stearic acid is used in an amount of 0.5-1% of the total mass of the coated feed pellet.

The second purpose of the invention is to provide a processing technology of the pseudosciaena crocea larvae feed.

In order to achieve the purpose, the technical scheme provided by the invention is as follows: heating and melting fish oil and stearic acid, and coating the fish oil and stearic acid on the outer surface of a formed core material prepared from the main components of the feed.

In the invention, the wall material which takes the fish oil and the stearic acid in the molten state as the main components can be sprayed on the outer surface of the core material by a spraying process to complete the coating of the core material. As an example, the coating agent is uniformly sprayed on the surface of the feed by a fluidized bed coating process.

As an embodiment of the present invention, the preparation process of the core material is as follows:

(1) weighing dry cuttlefish viscera powder, choline chloride, white fish meal, low-temperature krill powder and low-temperature wall-broken yeast powder according to a certain proportion, uniformly mixing, and granulating to obtain premix 1 for later use;

(2) dissolving sodium alginate in water according to a certain proportion, adding strong flour, alpha-starch, soybean lecithin powder, L-ascorbic acid-2 phosphate, monocalcium phosphate, vitamin premix, mineral premix, mildew preventive and antioxidant according to a certain proportion, and mixing uniformly to obtain premix 2 for later use;

(3) and (3) mixing the premix 1 in the step (1) and the premix 2 in the step (2) with fish oil, curing and granulating to obtain core particles.

In the step (1), the particle fineness of the premix 1 is 100-200 meshes. In the step (2), the mass of the water is 9-12 times of that of the sodium alginate.

In the step (3), the mixing time of the premix 1 and the premix 2 with the fish oil is 200-250 s.

In the step (3), the curing temperature is 80-90 ℃, and the curing time is 20-30 min.

In the step (3), wet granulation is adopted to prepare the micro-particle feed with the particle size of 0.2mm, and hot air drying is carried out for 30-45min at the temperature of 50-60 ℃.

Compared with the prior art, the invention has the following beneficial effects:

1. the fish oil and stearic acid are used as main components of the wall material, the water-insoluble coating is formed on the surface of the core material, the stability of the feed in water is improved, and the feed has food calling property due to the fish oil, so that the utilization rate of the feed is improved to a great extent, and the loss of the feed is reduced in feeding.

2. The stearic acid is selected as the main component of the wall material, a water-insoluble coating is formed on the surface of the feed core material, and the stearic acid has good digestion performance in the fish body, so that the contradiction between the water solubility of the wall material and the feed digestion rate is solved.

3. The fish oil and the stearic acid are used as main components of the wall material, and after the fish oil and the stearic acid are heated and melted, the fish oil and the stearic acid are mutually dissolved and have better liquidity, so that the problems that the stearic acid is easy to condense in a flow guide pipe due to low external temperature when being used singly and is blocked and the stearic acid is remained after being dissolved by a fat-soluble diluent and then coated are solved.

4. The fish oil and stearic acid are mixed and sprayed, so that the stability of the coating is ensured, the food calling performance is achieved, high-quality raw materials are selected as feed ingredients, the nutrition balance is matched, the ingestion and the utilization of the pseudosciaena crocea are facilitated, and the growth of the pseudosciaena crocea is effectively promoted.

Detailed Description

Specific embodiments of the present application will be described in more detail below. These embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

Example 1 three different processes for preparing feed

1. Preparing a feed:

according to a basic feed formula, three processes are used for preparing the pseudosciaena crocea larvae feed, which respectively comprises the following steps:

the same process steps are as follows: premixing 3% of cuttlefish viscera dry powder and 0.2% of choline chloride (60%), mixing with 45% of white fish meal, 22% of low-temperature krill meal and 3.5% of low-temperature wall-broken yeast powder, removing impurities by primary cleaning and removing iron by using a permanent magnet cylinder, and mixing by using a single-shaft paddle type mixer for 180-220 s. The mixture is conveyed to a hammer type ultrafine pulverizer through an impeller type feeder with a wind net cover and a lifter to obtain a raw material with the pulverizing fineness of 200 meshes for standby, and the raw material is premix 1.

Feed 1: 2% sodium alginate is dissolved in water 10 times of the weight of the sodium alginate in advance; adding 5% of strong flour, 3% of alpha-starch, 5% of soybean lecithin powder, 0.2% of L-ascorbic acid-2 phosphate (35%), 2% of monocalcium phosphate (containing 22% of phosphorus), 1.5% of vitamin premix, 1% of mineral premix, 0.05% of mildew preventive and 0.05% of antioxidant, and premixing to obtain premix a. Uniformly mixing the premix a, the premix 1 and 6.5% fish oil, extruding into strips with the diameter of 0.2mm, preparing into particles with the particle diameter of 0.2mm in a rolling disc, drying by hot air at 60 ℃ for 40min, and externally spraying 0.5% sodium alginate solution according to the proportion of 1%.

And (3) feed 2: 2% sodium alginate is dissolved in water 10 times of the weight of the sodium alginate in advance; adding 5% of strong flour, 3% of alpha-starch, 5% of soybean lecithin powder, 0.2% of L-ascorbic acid-2 phosphate (35%), 2% of calcium dihydrogen phosphate (containing 22% of phosphorus), 1.5% of vitamin premix, 1% of mineral premix, 0.05% of mildew preventive and 0.05% of antioxidant, and premixing to obtain premix b. Uniformly mixing the premix b, the premix 1 and 6.5% of fish oil, aging at 80-90 deg.C for 25min, extruding into strips with diameter of 0.2mm, making into particles with particle diameter of 0.2mm in a rolling disc, drying with 60 deg.C hot air for 40min, and spraying 0.5% sodium alginate solution at a ratio of 1%.

And (3) feed: the invention is prepared by the processing technology. Specifically, 2% sodium alginate was dissolved in water 10 times its weight in advance; adding 5% of strong flour, 3% of alpha-starch, 5% of soybean lecithin powder, 0.2% of L-ascorbic acid-2 phosphate (35%), 2% of calcium dihydrogen phosphate (containing 22% of phosphorus), 1.5% of vitamin premix, 1% of mineral premix, 0.05% of mildew preventive and 0.05% of antioxidant, and premixing to obtain premix 2. Uniformly mixing premix 1, premix 2 and 4.5% fish oil, aging at 80-90 deg.C for 25min, extruding into strips with diameter of 0.2mm, making into granules with particle diameter of 0.2mm in a rolling disc, and hot air drying at 60 deg.C for 40 min. 2 percent of refined fish oil and stearic acid which is 0.5 percent of the weight of the particles to be coated are evenly mixed at the temperature of 60 ℃, and are evenly sprayed on the surface of the feed by a fluidized bed coating process. And drying with cold air for 20min to obtain the final product.

2. Comparing the loss rate in seawater and the volume weight of the feed prepared by the three processes

After 5g of each of the three feeds is immersed in 10ml of natural seawater (pH7.8, salinity of 24 per thousand) for 1 hour, a feed sample is drained, and the dissolution rate is measured. The feed is evenly put into a 1000ml measuring cylinder, the volume is adjusted by a spatula to reach 1000ml, and the sample is poured out of the measuring cylinder and weighed. Each feed was repeated 3 times. The results show that the dissolution rate of the prepared feed of the feed 2 and the feed 3 is obviously lower than that of the feed 1, and the unit weights of the three feeds are not different (Table 1). This shows that the invention can reduce the loss rate in sea water and does not affect the volume weight of feed.

TABLE 1 dissolution rate and volume weight of three feeds

Note: the superscript of different letters in the same row indicates significant difference (P <0.05)

3. Influence of feed prepared by three processes on growth performance of large yellow croaker

Selecting the pseudosciaena crocea larvae with the initial weight of 2.58 +/-0.30 mg, randomly dividing the pseudosciaena crocea larvae into three groups, repeating three groups in each group, repeating 2000 fish in each group, and performing a feeding growth experiment (the pH value is 7.8-8.2, the salinity is 21-24 per mill, and the temperature is 23-26 ℃) for 30 days. The results show that the terminal weight and specific growth rate of the pseudosciaena crocea larvae are obviously improved by feeding the feed obtained by the process (Table 2).

TABLE 2 Effect of three feeds on the growth Performance of Pseudosciaena crocea larvae

Note: the superscript of different letters in the same row indicates significant difference (P <0.05)

4. The growth promoting effect of the feed 3 on the pseudosciaena crocea larvae is compared with that of commercial feed

Selecting large yellow croaker larvae with initial weight of 2.58 +/-0.30 mg, randomly dividing the large yellow croaker larvae into 2 groups, repeating three groups in each group, repeating 2000 fish in each group, selecting feed 3 and commercial feed purchased in the market, and carrying out a feeding growth comparison experiment for 30 days (pH 7.8-8.2, salinity of 21-24 per mill, and temperature of 23-26 ℃). The results show that the terminal weight and specific growth rate of the pseudosciaena crocea larvae fed by the feed 3 are higher than those of the commercial feed (Table 3).

TABLE 3 comparison of growth promoting effect of feed 3 and commercial feed on Pseudosciaena crocea larvae

Note: the superscript of different letters in the same row indicates significant difference (P <0.05)

Example 2

(1) Premixing 4% of cuttlefish viscera dry powder and 0.3% of choline chloride (60%), mixing with 49% of white fish meal, 20% of low-temperature krill powder and 3% of low-temperature wall-broken yeast powder, removing impurities through a primary cleaning sieve, removing iron through a permanent magnet cylinder, and mixing by using a single-shaft paddle type mixer for 180-time period 220 s. The mixture is conveyed to a hammer type ultrafine pulverizer through an impeller type feeder with a wind net cover and a lifter to obtain a raw material with the pulverizing fineness of 200 meshes for standby, and the raw material is premix 1.

(2) Dissolving 3% sodium alginate in 12 times of water in advance; adding 6% of high gluten flour, 2% of alpha-starch, 4% of soybean lecithin powder, 0.1% of L-ascorbic acid-2 phosphate (35%), 1% of calcium dihydrogen phosphate (containing 22% of phosphorus), 1% of vitamin premix, 0.5% of mineral premix, 0.05% of mildew preventive and 0.05% of antioxidant, and premixing to obtain premix 2.

(3) Uniformly mixing premix 1, premix 2 and 4% fish oil, aging at 80-90 deg.C for 25min, extruding into strips with diameter of 0.2mm, making into particles with particle diameter of 0.2mm in a rolling disc, and hot air drying at 60 deg.C for 40min to obtain core material particles.

(4)2 percent of refined fish oil and stearic acid which is 0.5 percent of the weight of the particles to be coated are evenly mixed at the temperature of 60 ℃, and are evenly sprayed on the surface of the feed by a fluidized bed coating process. And drying with cold air for 20min to obtain the final product.

Example 3

(1) Premixing 2% of cuttlefish viscera dry powder and 0.1% of choline chloride (60%), mixing with 40% of white fish meal, 24% of low-temperature krill powder and 4% of low-temperature wall-broken yeast powder, removing impurities through a primary cleaning sieve, removing iron through a permanent magnet cylinder, and mixing by using a single-shaft paddle type mixer for 180-time period 220 s. The mixture is conveyed to a hammer type ultrafine pulverizer through an impeller type feeder with a wind net cover and a lifter to obtain a raw material with the pulverizing fineness of 200 meshes for standby, and the raw material is premix 1.

(2) Dissolving 1% sodium alginate in 9 times of water in advance; 4 percent of high gluten flour, 6 percent of alpha-starch, 5.5 percent of soybean lecithin powder, 0.3 percent of L-ascorbic acid-2 phosphate (35 percent), 3 percent of calcium dihydrogen phosphate (containing 22 percent of phosphorus), 2 percent of vitamin premix, 1 percent of mineral premix, 0.05 percent of mildew preventive and 0.05 percent of antioxidant are added for premixing to obtain premix 2.

(3) Uniformly mixing premix 1, premix 2 and 5% fish oil, aging at 80-90 deg.C for 25min, extruding into strips with diameter of 0.2mm, making into particles with particle diameter of 0.2mm in a rolling disc, and hot air drying at 60 deg.C for 40min to obtain core material particles.

(4)2 percent of refined fish oil and stearic acid which is 0.5 percent of the weight of the particles to be coated are evenly mixed at the temperature of 60 ℃, and are evenly sprayed on the surface of the feed by a fluidized bed coating process. And drying with cold air for 20min to obtain the final product.