CN112314257A

CN112314257A - Seedling raising method and container for carya illinoensis

Info

Publication number: CN112314257A
Application number: CN202011203208.5A
Authority: CN
Inventors: 陈同政; 李婵颖; 周洋; 占柴锋; 杨重卫; 苏梦飞; 楼航杰
Original assignee: Hangzhou Chang Lin Gardening Co ltd
Current assignee: Hangzhou Chang Lin Gardening Co ltd
Priority date: 2020-11-02
Filing date: 2020-11-02
Publication date: 2021-02-05
Anticipated expiration: 2040-11-02
Also published as: CN112314257B

Abstract

The invention discloses a seedling raising method of carya illinoensis and a seedling raising container thereof, which comprise a non-woven fabric bag, wherein seedlings are planted in the non-woven fabric bag, a drip irrigation disc is arranged on nutrient soil of the non-woven fabric bag and surrounds the seedling stem base of the seedlings, the drip irrigation disc comprises a first disc body and a second disc body, a plurality of water outlet holes are formed in the bottoms of the first disc body and the second disc body, the first disc body is in an open ring shape, the second disc body is detachably fixed at the opening of the first disc body, a disc cover is arranged above the second disc body, a control valve is arranged on the disc cover, and 5-10g of water-retaining agent is uniformly mixed in the nutrient soil. The scheme mixes a proper amount of water-retaining agent in the nutrient soil of the large container to avoid the dehydration of the nutrient soil, and ensures that the nutrient soil is fluffy and has good air permeability, the drip irrigation disc is adopted to drip irrigation and has high water permeability, the drip irrigation is uniform, the water outlet hole is not easy to block, and the management is convenient.

Description

Seedling raising method and container for carya illinoensis

Technical Field

The invention belongs to the technical field of agricultural planting, and relates to a seedling raising method of carya illinoensis and a seedling raising container thereof.

Background

Apocarya (Carya illinoensis), also known as american hickory, is a deciduous tree of the genus hickory (Carya) of the family juglandaceae, one of the world's famous dry fruit oil tree species, and also a good tree species for lumber and yard greening. The pecan nuts have beautiful color, delicious taste, no astringent taste and rich nutrition, contain various amino acids beneficial to the human body, have higher content than olive, and are also rich in vitamin B1 and B2, so the pecan nuts are popular with people. The introduction of the apocarya in the end of the 19 th century in China is started, and the introduction and cultivation are carried out in 13 provinces (directly prefectured cities) such as Zhejiang, Yunnan, Anhui, Jiangsu and the like in China at present. In addition, the thin-shell hickory has straight trunks, tall and big tree bodies and beautiful tree postures, is also a better tree species for plain coastal greening, farmland forest nets and 'four-side' planting, and the wood of the thin-shell hickory is widely used for military industry, high-grade furniture and the like.

Although the carya illinoensis is introduced into China for hundreds of years, the development of the carya illinoensis industry in China is limited due to a plurality of factors such as long breeding period, slow progress of fine variety evaluation and breeding, relatively backward seedling propagation technology, insufficient high-yield cultivation measures and the like. Particularly, the seedling propagation technology is relatively weak although a small amount of fine varieties suitable for the development of China are bred at present. At present, the cultivation area of the carya illinoensis in China exceeds 70 ten thousand mu, and particularly large-area development is carried out in the provinces such as Zhejiang, Yunnan, Jiangsu, Anhui and the like, and due to insufficient supply of improved seedlings and uneven seedling culture, new afforestation of the carya illinoensis is low-efficiency forest, and cases of afforestation failure occur occasionally.

At present, the improved seedling in the carya illinoensis industry of China is cultivated by bare-rooted seedlings mostly, namely seeds of carya illinoensis are adopted and sowed in bare fields, and after the standard of grafting is achieved, improved scion strips of carya illinoensis are adopted for grafting so as to cultivate the improved seedling of carya illinoensis. The nursery stock cultivated by adopting the bare-rooted seedling cultivation method has fewer lateral fibrous roots, thereby not only affecting the quality of the nursery stock, but also affecting the survival rate and the preservation rate of the field planting of the nursery stock, and having a seedling revival stage; in addition, as the scion of the carya illinoensis is thick, the growth amount of the rootstock in the first year after sowing is small, grafting cannot be carried out in the current year, grafting can be carried out only in production after 2 years or more of cultivation, the cultivation period is long, the propagation period of fine variety seedlings of the carya illinoensis is directly influenced, and the development of the carya illinoensis industry is limited.

The container seedling culture is applied to cultivation of apocarya seedlings in a small amount at present, namely, apocarya seeds are adopted and directly sown in a container or sown in the container after germination acceleration, and after cultivation for 2 years reaches a grafting standard, improved apocarya scion strips are adopted for grafting, so that improved apocarya seedlings are cultivated. The root system of the apocarya seedlings cultivated by the container seedling cultivation method is better improved than that of bare-rooted seedlings, but the cultivation of the stocks still needs 2 years or more, the cultivation period of the improved apocarya seedlings is greatly influenced, the nursery land occupies time, and the seedling cultivation cost is high.

The publication number CN110122297A discloses a two-stage container seedling raising method for apocarya, which can greatly shorten the culture period of improved apocarya seedlings, improve the root quality of the seedlings and improve the afforestation survival rate and the preservation rate of the improved apocarya seedlings. The seedling raising method comprises a small container seedling raising stage and a large container seedling raising stage, wherein the small container seedling raising stage is that the carya illinoensis seeds are dibbled in a small container for seedling raising, the large container seedling raising stage is that leaves of carya illinoensis seedlings in the small container are spread, and when the height of the carya illinoensis seedlings grows to 15-20 cm, the whole small container is placed in the large container for seedling raising continuously. In the large-container seedling raising stage, 1 time of water permeation is respectively carried out by drip irrigation in the morning and at the evening in non-rainy days, 10 g-20 g of equal-proportion compound fertilizer (N: P: K is 15:15:15) is applied every 18 d-22 d in the growth period of 6 months-7 months, and 10 g-20 g of high-potassium organic-inorganic compound fertilizer (N: P: K is 15:5:20) is applied every 14 d-16 d in 8 months-9 months. In the prior art, 2 drop arrows are generally inserted into a large container for drip irrigation, but the flow guide grooves of the drop arrows are often blocked, the drop arrows need to be replaced in time through manual inspection, and the replacement cost is high due to large manual workload. And the large container is generally directly placed in an open-air nursery, and in hot summer, due to the factors of high environmental temperature, poor water storage capacity of the matrix soil of the large container, insufficient uniformity and sufficiency of drip irrigation of the drop arrow and the like, the matrix soil in the large container is easy to dehydrate to influence the growth of the carya illinoensis seedlings only by carrying out drip irrigation twice in the morning and evening.

Disclosure of Invention

In order to solve the technical problems, the invention aims to provide a carya illinoensis seedling raising method and a seedling raising container thereof, the seedling raising container is high in water permeation efficiency through drip irrigation, uniform in drip irrigation, not easy to block water outlet holes, convenient to manage, high in seedling growth speed and quality, thick and more in lateral roots, high in seedling emergence rate, and beneficial to improvement of afforestation survival rate and preservation rate.

In order to achieve the purpose, the invention adopts the following technical scheme:

a seedling culture container comprises a non-woven cloth bag (1), seedlings (3) are planted in the non-woven cloth bag (1), a drip irrigation disc (2) is installed on nutrient soil of the non-woven cloth bag (1), the drip irrigation disc (2) surrounds the periphery of a seedling stem base of the seedlings (3), the drip irrigation disc comprises a first disc body (11) and a second disc body (17), a plurality of water outlet holes are formed in the bottoms of the first disc body (11) and the second disc body (17), the first disc body (11) is in an open ring shape, the second disc body (17) is detachably fixed at an opening of the first disc body (11), a disc cover (13) is installed above the second disc body (17), a control valve (14) is installed on the disc cover (13), the control valve (14) comprises an upper valve body (141), a lower valve body (142) and a valve core (143), a water inlet (1) and at least one water outlet (1412) are formed in the upper valve body (141), a water outlet (1412) on the upper valve body (141) is connected to the first disc body (11) through a water pipe, the first disc body (11) is communicated with the second disc body (17) at a low water level, a conical inner cavity for accommodating the valve core (143) is arranged on the upper valve body (141), a water inlet (1411) is communicated with the water outlet (1412) through the conical inner cavity of the upper valve body (141), the lower valve body (142) is arranged below the upper valve body (141) and fixedly connected with the upper valve body (141) through threads, the valve core (143) is arranged in a space formed by the conical inner cavity of the upper valve body (141) and the inner cavity of the lower valve body (142) and can move up and down, a first through hole is formed at the bottom of the inner cavity of the lower valve body (142), the valve core (143) extends downwards to form a lower extension rod (1431), an installation barrel (131) for installing the control valve (14) is arranged on the disc cover (13), and the upper valve body (141) or the, the lower part of the mounting cylinder (131) is provided with a floating body (18), the upper part and the lower part of the mounting cylinder (131) are separated by a partition part (132), the partition part (132) is provided with a second through hole, the lower end of a lower extension rod (1431) of the valve core (143) penetrates through a first through hole on the lower valve body (142) and a second through hole on the partition part (132) and then is fixedly connected with the floating body (18), the lower extension rod (1431) of the valve core (143) is sleeved with an adjusting block (19) and a spring (20), the adjusting block (19) is in threaded connection with the lower extension rod (1431), the upper end of the spring (20) is abutted against the adjusting block (19), the lower end of the spring (20) is abutted against the partition part (132) of the mounting cylinder (131), so that the upper half part of the valve core (143) is matched and abutted against the conical surface of the conical cavity of the upper valve body (141), wherein the adjusting block (19) is fixedly connected with the mounting cylinder (131) in the circumferential direction, the floating body (18) is fixedly connected with the circumferential direction of the mounting cylinder (131) so as to move up and down but not rotate relatively; 5-10g of water-retaining agent is uniformly mixed in the nutrient soil.

Preferably, when water does not enter the water inlet (1411), the valve core (143) is pressed against the upper valve body (141) upwards under the action of the spring (20), and the control valve (14) is closed; when the water pressure of the water inlet (1411) exceeds the acting force of the spring (20), the water inlet (1411) moves downwards, the control valve (14) is opened, the water inlet (1411) is communicated with the water outlet (1412), water enters the first tray body (11) and the second tray body (13) and leaks into the large container nutrient soil through the water outlet holes (110 and 171) at the bottoms of the first tray body (11) and the second tray body (13), when the leakage speed is slower than the water inlet speed, water storage is generated in the first tray body (11) and the second tray body (13), the buoyancy borne by the floating body (18) is increased along with the rising of the water storage level, and the valve core (143) moves upwards under the action of the buoyancy and the spring (20) to limit the water inlet flow until the valve core (143) closes the water inlet (1411).

Preferably, the lower end of the lower extension rod (1431) of the valve core (143) is square, a square clamping hole is arranged on the floating body (18), and the lower extension rod (1431) of the valve core (143) and the floating body (18) are in clamping fixed connection through the square clamping hole and cannot rotate relatively.

Preferably, the side walls of the first disk body (11) and the second disk body (13) are connected through a connecting screw cylinder (16), two ends of the connecting screw cylinder (16) extend out of the side walls of the first disk body (11) and the second disk body (13) and are respectively in threaded connection with nuts (15), and the connecting screw cylinder (16) is arranged close to the bottoms of the first disk body (11) and the second disk body (13), so that the connecting holes in the screw cylinder (16) communicate the first disk body (11) with the second disk body (13) at a low water level.

Preferably, the upper opening of the first tray body (11) is covered with a steel wire mesh.

Preferably, the mounting tube (131) is integrally formed with or fixedly connected to the disk cover (13).

Preferably, a water inlet (1411) on the upper valve body (141) is arranged above the conical inner cavity, and the valve core (143) extends upwards to form an upper extension rod which is inserted into the water inlet (1411).

Preferably, the water outlet (1412) on the upper valve body (141) is arranged around the conical inner cavity of the upper valve body, the valve core (143) is in a spinning cone shape with upper and lower ends, the upper and lower extension rods are respectively positioned at the upper and lower ends of the spinning cone body, the upper half part of the valve core (143) is matched with the conical inner cavity of the upper valve body (141) through a conical surface, the lower half part of the valve core (143) is matched with the conical inner cavity of the lower valve body (142), certain gaps are formed between the lower extension rod (1431) and the first through hole and the second through hole, and when the water inlet pressure and the elastic force of the spring (20) are in a balanced state, and the valve core (143) does not completely close the conical inner cavity of the lower valve body (142), a water outlet channel is formed along.

Preferably, the upper and lower moving spaces of the valve core (143) are 1/4 to 1/2 of the aperture of the water inlet.

A seedling raising method of apocarya uses the seedling raising container.

By adopting the technical scheme, on the basis of the prior art, a proper amount of water-retaining agent is added into nutrient soil in a large container to prevent the nutrient soil from being dehydrated, and the nutrient soil is fluffy and has good air permeability (the water-retaining agent is super absorbent resin with extremely strong water absorption capacity, is non-toxic and harmless, and repeatedly releases and absorbs water, so people in agriculture compare the nutrient soil with a micro reservoir, and simultaneously can absorb fertilizer and pesticide and slowly release the fertilizer and the pesticide to increase the fertilizer efficiency and the pesticide effect), a drip irrigation disc is adopted to drip irrigation and has high water permeability, uniform drip irrigation and difficult blockage of water outlet holes, nursery stock growth is convenient to manage, the nursery stock growth speed is high, the lateral roots grow thick and much, the emergence rate is high, the diameter of the nursery stock in the same year can exceed 1 centimeter, the survival rate of mountain afforestation in the next year.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application.

FIG. 1 is a schematic structural view of a container for raising seedlings according to the present invention;

fig. 2 is a schematic structural view (plan view) of the drip irrigation pan;

FIG. 3 is a schematic view of the control valve structure of the drip irrigation pan;

fig. 4 is one of the schematic views of the operation of the drip irrigation pan (on state);

fig. 5 is one of the schematic views of the operation of the drip irrigation pan (closed state);

wherein, 1, a non-woven fabric bag; 2. a drip irrigation pan; 3. nursery stock; 4. drilling nursery stock holes; 11. a first tray body; 110. a water outlet of the first disc body; 12. a water pipe; 13. a plate cover; 131. mounting the cylinder; 132. a partition plate portion; 14. a control valve; 141. an upper valve body; 1411. a water inlet; 1412. a water outlet; 142. a lower valve body; 143. a valve core; 1431. a lower extension bar; 15. a nut; 16. connecting the screw cylinder; 161. connecting holes; 17. a second tray body; 171. a water outlet hole of the second tray body; 18. a float; 19. an adjusting block; 20. a spring.

Detailed Description

The invention is further described with reference to the following figures and examples.

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, the singular is also intended to include the plural unless the context clearly dictates otherwise, and it should be further understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of the features, steps, operations, devices, components, and/or combinations thereof.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

Example 1:

a method for raising seedlings of apocarya comprises the following steps:

1) centralized accelerating germination: in the middle and last ten days of 2 months, soaking seeds of apocarya in the greenhouse for 4 to 6 days, and accelerating germination on a sand bed in the greenhouse;

2) hatching in a small container: building a seedbed in the greenhouse, and paving fine sand or screening fine soil at the bottom of the bed; arranging the small containers on a seedbed, and watering the small containers thoroughly in times; cutting off root tips of the seeds of the carya illinoensis which just expose white and germinate, transversely placing the seeds into a small container, and covering fine soil on the seeds; when the seedlings have 5 to 6 leaves, the seedlings are outplanted;

3) and (3) large-container light-matrix water-fertilizer integrated cultivation of strong seedlings: filling the large container with nutrient soil, taking out the small container, removing the main root tip, planting in the large container, watering thoroughly, and placing a drip irrigation disc on the top of the large container; supplementing water at regular time every day, and performing drip irrigation for 1 time in the morning and at the evening in non-rainy days according to the soil moisture content of the nutrient soil in the large container; topdressing and promoting seedlings according to the growth vigor of the seedlings; budding is carried out when the stem of the seedling is more than 0.8 cm from the middle and late ten days of 8 months to the middle and early ten days of 9 months; when the buds sprout in 4 months next year, the upper end stem of the grafted live seedling is cut off to promote the grafted bud to sprout, and the original solid bud and the redundant grafted bud are continuously removed to keep the grafted main bud healthy and strong and grow upwards; leaves fall in 12 months and then can be transplanted out of the nursery in 4 months in the next year;

wherein, the large container nutrient soil comprises the following components in percentage by weight: 50-60% of fine loam, 15-20% of decomposed organic fertilizer and 25-30% of agricultural and forestry waste, uniformly mixing and composting for 3-6 months; when the nutrient soil is filled into a large container, 5-10g of water-retaining agent is added into each bag of nutrient soil and mixed evenly.

The seedling raising method of the carya illinoensis adopts centralized germination acceleration, small container incubation, large container light matrix water and fertilizer integrated management, current-year sowing, current-year grafting and next-year outplanting, and the seedling is changed from the original 2+1 seedling to 1+1 seedling, and the time is advanced by one year. The main root tips of the small container seedlings are removed to promote the growth of lateral roots, a proper amount of water-retaining agent is added into the large container nutrient soil to prevent the nutrient soil from being dehydrated, the nutrient soil is fluffy and has good air permeability (the water-retaining agent is super absorbent resin with extremely strong water absorption capacity, is non-toxic and harmless, and repeatedly releases and absorbs water, so that people in agriculture compare the nutrient soil with a micro reservoir, and meanwhile, the water-retaining agent can absorb fertilizers and pesticides and slowly release the fertilizers and the pesticide effect to increase the fertilizer efficiency and the pesticide effect), a drip irrigation disc is adopted to drip irrigation, the water permeability is high, the drip irrigation is uniform, water outlet holes are not easy to block, the nursery stock growth is convenient to manage, the quality is high, the lateral roots grow thick and much, the emergence rate is high, the seedling diameter can exceed 1 centimeter in the year, the. In addition, the drip irrigation disc is adopted to cover the nutrient soil, so that the service life of the water-retaining agent can be prolonged, and the rapid dehydration caused by overhigh temperature of the soil in summer can be avoided.

In the embodiment, in the step 2), the temperature in the greenhouse is kept at 35 degrees +/-2 degrees, water is supplemented in due time, ventilation is noticed after seedling emergence, and high-temperature seedling burning is prevented. The small container is a non-woven bag or a plastic mesh container with the diameter of 6 centimeters and the height of 10 centimeters; the large container is a non-woven bag with the diameter of 25 cm and the height of 30 cm. The agricultural and forestry waste is a mixture of straw, pine tree and mushroom dregs or one of the straw, the pine tree and the mushroom dregs. In the step 3), during topdressing, the water-soluble fertilizer with a certain concentration can be mixed into water for fertilizing, and a certain amount of fertilizer can also be applied singly. In the step 3), the seedlings grow to about 80 centimeters, and according to the growth vigor, inserting rods, binding seedlings and supporting seedlings for a part of seedlings in time so as to keep the seedlings to grow straight.

A seedling raising container (large container) as shown in figure 1 comprises a non-woven fabric bag 1, seedlings 3 are planted in the non-woven fabric bag 1, a drip irrigation disc 2 is installed on nutrient soil of the non-woven fabric bag 1, and the drip irrigation disc 2 surrounds the periphery of a seedling stem base part of the seedlings 3 and is matched with the bag mouth of the non-woven fabric bag 1 in size.

As shown in fig. 2 and 3, the drip irrigation pan comprises a first pan body 11 and a second pan body 17, a plurality of water outlet holes are arranged at the bottoms of the first pan body 11 and the second pan body 17, the first pan body 11 is in an open ring shape, the second pan body 17 is detachably fixed at the opening of the first pan body 11, a pan cover 13 is arranged above the second pan body 17, a control valve 14 is arranged on the pan cover 13, the control valve 14 comprises an upper valve body 141, a lower valve body 142 and a valve core 143, the upper valve body 141 is provided with a water inlet 1411 and two water outlets 1412, the water outlet 1412 on the upper valve body 141 is connected to the first pan body 11 through a water pipe 12, the first pan body 11 and the second pan body 17 are in low water level communication, the upper valve body 141 is provided with a conical inner cavity for accommodating the valve core 143, the water inlet 1411 is communicated with the water outlet 1412 through the conical inner cavity of the upper valve body 141, the lower valve body 142 is arranged below, the valve core 143 is installed in the space formed by the conical inner cavity of the upper valve body 141 and the inner cavity of the lower valve body 142 and can move up and down, the bottom of the inner cavity of the lower valve body 142 is a first through hole, the valve core 143 extends downward to form a lower extension rod 1431, the disk cover 13 is provided with an installation cylinder 131 for installing the control valve 14, the upper valve body 141 or the lower valve body 142 is fixedly connected with the upper part of the installation cylinder 131 through threads, the lower part of the installation cylinder 131 is provided with a floating body 18, the upper part and the lower part of the installation cylinder 131 are separated through a partition plate 132, the partition plate 132 is provided with a second through hole, the lower end of the lower extension rod 1431 of the valve core 143 passes through the first through hole of the lower valve body 142 and the second through hole of the partition plate 132 and is fixedly connected with the floating body 18, the lower extension rod 1431 of the valve core 143 is sleeved with an adjustment block 19 and a spring 20, the adjustment block 19 is in threaded connection with the lower extension rod 1431, the, thereby urging the upper half of the valve core 143 to be fitted against the tapered inner cavity of the upper valve body 141, wherein the adjusting block 19 is circumferentially fixedly connected to the mounting cylinder 131 so as to be movable up and down but not rotatable relative thereto, and the floating body 18 is circumferentially fixedly connected to the mounting cylinder 131 so as to be movable up and down but not rotatable relative thereto.

As shown in fig. 3, when water is not fed into the water inlet 1411, the valve core 143 abuts against the upper valve body 141 upwards under the action of the spring 20, and the control valve 14 is closed; as shown in fig. 4, when the water pressure at the water inlet 1411 exceeds the acting force of the spring 20, the water inlet 1411 moves downwards, the control valve 14 is opened, the water inlet 1411 is communicated with the water outlet 1412, water enters the first tray 11 and the second tray 13 and leaks into the large container nutrient soil through the water outlet holes 110 and 171 at the bottom of the first tray 11 and the second tray 13, when the leakage speed is slower than the water inlet speed, water is stored in the first tray 11 and the second tray 13, as the water level of the stored water rises, the buoyancy force applied to the floating body 18 becomes larger and larger, the valve core 143 moves upwards under the action of the buoyancy force and the spring 20 to limit the water inlet flow, until the valve core 143 closes the water inlet 1411 as shown in fig. 5. Therefore, the water pressure of the water conveying pipeline can be guaranteed to realize long-distance water conveying and large-range drip irrigation, the irrigation is uniform and efficient, and water resource waste is avoided. The adjusting block 19 is in threaded connection with the lower extension rod 1431, and the adjusting block 19 is circumferentially and fixedly connected with the mounting cylinder 131 so as to move up and down but not rotate relatively, so that the spring force of the spring 20 can be adjusted by rotating the lower extension rod 1431 to achieve the purpose of adjusting the water pressure of the inlet water. Lower extension pole 1431 and body 18 fixed connection, thereby body 18 can reciprocate but can not rotate relatively with installation section of thick bamboo 131 circumference fixed connection, like this, adjust at spring 20 and can remain stable, avoid lower extension pole 1431 to rotate to simple structure is ingenious, low cost. In a preferred embodiment, the lower end of the lower extension rod 1431 of the valve core 143 is square, a square fastening hole is formed on the float 18, and the lower extension rod 1431 of the valve core 143 and the float 18 are in a snap-fit connection through the square fastening hole and cannot rotate relatively.

In this embodiment, the side walls of the first disk body 11 and the second disk body 13 are connected through a connecting screw cylinder 16, two ends of the connecting screw cylinder 16 extend out of the side walls of the first disk body 11 and the second disk body 13 and are respectively in threaded connection with nuts 15, and the connecting screw cylinder 16 is arranged near the bottoms of the first disk body 11 and the second disk body 13, so that the connecting holes in the screw cylinder 16 communicate the first disk body 11 and the second disk body 13 at a low water level. The mounting cylinder 131 is integrally formed with or fixedly connected to the cover 13.

In a preferred embodiment, the upper opening of the first tray body 11 is covered with a steel wire mesh to prevent leaves and the like from falling into the drip irrigation. The aperture, the number and the distribution of the water outlet holes of the first tray body 11 and the second tray body 13 can be designed according to the irrigation requirements such as actual size and soil quality.

In this embodiment, the water inlet 1411 of the upper valve body 141 is disposed above the conical cavity, and the valve element 143 extends upward to form an upper extension rod, which is inserted into the water inlet 1411. Therefore, the upper extension rod can limit the moving range of the valve core and is beneficial to water inlet flow splitting to limit the water inlet flow and flow speed. The water outlets 1412 on the upper valve body 141 are respectively arranged around the conical inner cavity, the valve core 143 is in a spinning cone shape with upper and lower ends, the upper and lower extension rods are respectively positioned at the upper and lower ends of the spinning cone body, thus, the upper half part of the valve core 143 is matched with the conical inner cavity of the upper valve body 141 through a conical surface, a better flow dividing and pressure reducing effect can be achieved, the lower half part of the valve core 143 is matched with the conical inner cavity of the lower valve body 142, certain gaps are formed between the lower extension rod 1431 and the first and second through holes, when the water inlet pressure and the elastic force of the spring 20 are in a balanced state, the valve core 143 does not completely close the conical inner cavity of the lower valve body 142, and a water outlet channel can be formed along the lower extension rod 1431, so that. The up-down moving space of the valve core 143 can be limited to 1/4-1/2 of the aperture of the water inlet, so that the control precision of the water inlet pressure of the control valve is provided, the water outlet channel between the valve core 143 and the inner cavity of the lower valve body 142 is closed in time, the water pressure of a water conveying pipeline is kept conveniently, and long-distance water conveying and uniform irrigation of a large number of drip irrigation plates connected at the same time are realized.

In the description herein, reference to the description of the terms "one embodiment," "some embodiments," "one implementation," "a specific implementation," "other implementations," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment, implementation, or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described above may also be combined in any suitable manner in any one or more of the embodiments, examples, or examples. The invention also includes any one or more of the specific features, structures, materials, or characteristics described above, taken alone or in combination.

Although the embodiments of the present invention have been shown and described, it is understood that the embodiments are illustrative and not restrictive, and that those skilled in the art can make changes, modifications, substitutions, variations, deletions, additions or rearrangements of features and elements within the scope of the invention without departing from the spirit and scope of the invention.

Claims

1. A seedling culture container comprises a non-woven cloth bag (1), wherein seedlings (3) are planted in the non-woven cloth bag (1), and is characterized in that a drip irrigation disc (2) is installed on nutrient soil of the non-woven cloth bag (1), the drip irrigation disc (2) surrounds the seedling stem base of the seedlings (3), the drip irrigation disc comprises a first disc body (11) and a second disc body (17), a plurality of water outlet holes are formed in the bottoms of the first disc body (11) and the second disc body (17), the first disc body (11) is in an open ring shape, the second disc body (17) is detachably fixed at an opening of the first disc body (11), a disc cover (13) is installed above the second disc body (17), a control valve (14) is installed on the disc cover (13), the control valve (14) comprises an upper valve body (141), a lower valve body (142) and a valve core (143), a water inlet (1411) and at least one water outlet (1412) are formed in the upper valve body (141), a water outlet (1412) on the upper valve body (141) is connected to the first disc body (11) through a water pipe, the first disc body (11) is communicated with the second disc body (17) at a low water level, a conical inner cavity for accommodating the valve core (143) is arranged on the upper valve body (141), a water inlet (1411) is communicated with the water outlet (1412) through the conical inner cavity of the upper valve body (141), the lower valve body (142) is arranged below the upper valve body (141) and fixedly connected with the upper valve body (141) through threads, the valve core (143) is arranged in a space formed by the conical inner cavity of the upper valve body (141) and the inner cavity of the lower valve body (142) and can move up and down, a first through hole is formed at the bottom of the inner cavity of the lower valve body (142), the valve core (143) extends downwards to form a lower extension rod (1431), an installation barrel (131) for installing the control valve (14) is arranged on the disc cover (13), and the upper valve body (141) or the, the lower part of the mounting cylinder (131) is provided with a floating body (18), the upper part and the lower part of the mounting cylinder (131) are separated by a partition part (132), the partition part (132) is provided with a second through hole, the lower end of a lower extension rod (1431) of the valve core (143) penetrates through a first through hole on the lower valve body (142) and a second through hole on the partition part (132) and then is fixedly connected with the floating body (18), the lower extension rod (1431) of the valve core (143) is sleeved with an adjusting block (19) and a spring (20), the adjusting block (19) is in threaded connection with the lower extension rod (1431), the upper end of the spring (20) is abutted against the adjusting block (19), the lower end of the spring (20) is abutted against the partition part (132) of the mounting cylinder (131), so that the upper half part of the valve core (143) is matched and abutted against the conical surface of the conical cavity of the upper valve body (141), wherein the adjusting block (19) is fixedly connected with the mounting cylinder (131) in the circumferential direction, the floating body (18) is fixedly connected with the circumferential direction of the mounting cylinder (131) so as to move up and down but not rotate relatively; 5-10g of water-retaining agent is uniformly mixed in the nutrient soil.

2. A container for growing seedlings according to claim 1, characterized in that when the water inlet (1411) is not filled with water, the valve core (143) is pressed against the upper valve body (141) upwards under the action of the spring (20), and the control valve (14) is closed; when the water pressure of the water inlet (1411) exceeds the acting force of the spring (20), the water inlet (1411) moves downwards, the control valve (14) is opened, the water inlet (1411) is communicated with the water outlet (1412), water enters the first tray body (11) and the second tray body (13) and leaks into the large container nutrient soil through the water outlet holes (110 and 171) at the bottoms of the first tray body (11) and the second tray body (13), when the leakage speed is slower than the water inlet speed, water storage is generated in the first tray body (11) and the second tray body (13), the buoyancy borne by the floating body (18) is increased along with the rising of the water storage level, and the valve core (143) moves upwards under the action of the buoyancy and the spring (20) to limit the water inlet flow until the valve core (143) closes the water inlet (1411).

3. A container for growing seedlings according to claim 1, characterized in that the lower end of the lower extension rod (1431) of the valve core (143) is square, the float (18) is provided with a square fastening hole, and the lower extension rod (1431) of the valve core (143) and the float (18) are in snap-fit connection through the square fastening hole and can not rotate relatively.

4. A container for plant growth as claimed in claim 1, wherein the side walls of the first tray body (11) and the second tray body (13) are connected by a connecting screw (16), the two ends of the connecting screw (16) extend out of the side walls of the first tray body (11) and the second tray body (13) and are respectively in threaded connection with nuts (15), and the connecting screw (16) is arranged close to the bottoms of the first tray body (11) and the second tray body (13), so that the connecting holes on the screw (16) communicate the first tray body (11) with the second tray body (13) at a low water level.

5. A container for plant growth as claimed in claim 1, wherein the first tray (11) is covered with a wire mesh over the opening.

6. A container for plant growth as claimed in claim 1, characterised in that the mounting cylinder (131) is integrally formed with or fixedly connected to the tray cover (13).

7. A container for plant growth as claimed in claim 1, characterized in that the inlet (1411) of the upper valve body (141) is disposed above the conical chamber, and the valve core (143) is upwardly extended to form an upper extension rod inserted into the inlet (1411).

8. The container for plant growth according to claim 7, wherein the water outlet (1412) of the upper valve body (141) is arranged around the conical cavity, the valve core (143) is in a spinning cone shape with upper and lower ends, the upper and lower extension rods are respectively arranged at the upper and lower ends of the spinning cone, the upper half part of the valve core (143) is matched with the conical cavity of the upper valve body (141) through a conical surface, the lower half part of the valve core (143) is matched with the conical cavity of the lower valve body (142), certain gaps are formed between the lower extension rod (1431) and the first and second through holes, and when the water inlet pressure and the elastic force of the spring (20) are balanced, and the valve core (143) does not completely close the conical cavity of the lower valve body (142), a water outlet channel is formed along the lower extension rod (1431).

9. A container for plant growth as claimed in claim 1, wherein the space for the valve core (143) to move up and down is 1/4 to 1/2 of the diameter of the water inlet.

10. A method for raising seedlings of carya illinoensis, characterized in that a container for raising seedlings as claimed in any one of claims 1 to 9 is used.