CN116097937A - Ridge for returning and recycling water and manufacturing method thereof - Google Patents

Abstract

The invention discloses a returned water recycling ridge and a manufacturing method thereof, belongs to the technical field of agricultural engineering, and solves the problems of arbitrary discharge of polluted environmental water and fertilizer waste of farmland returned water in the prior art. The return water recycling ridge comprises a stem body and a return water ditch positioned on at least one side of the stem body, farmland return water flows into the return water ditch, and a water outlet of the return water ditch is connected with a water inlet of farmland irrigation equipment. The returned water recycling ridge and the manufacturing method thereof can avoid any discharge of farmland wastewater to pollute the environment water body, and improve the utilization rate of fertilizer and water resources.

Description

Ridge for returning and recycling water and manufacturing method thereof

Technical Field

The invention belongs to the technical field of agricultural engineering, and particularly relates to a returned water recycling ridge and a manufacturing method thereof.

Background

In the irrigation process of farmlands, irrigation water cannot fully permeate into the farmlands, and part of irrigation water which does not permeate into the farmlands is called farmland water withdrawal. The water is contacted with fertilizer in farm field, which contains rich nutrients such as nitrogen and phosphorus.

Any discharge of farmland water withdrawal not only can pollute the environment water body, but also can cause fertilizer waste.

Disclosure of Invention

In view of the analysis, the invention aims to provide a returned water recycling ridge and a manufacturing method thereof, which solve the problems of any discharge of returned water in farmlands, pollution of environmental water and fertilizer waste in the prior art.

The aim of the invention is mainly realized by the following technical scheme:

the invention provides a return water recycling ridge, which comprises a stem body and a return water ditch positioned on at least one side of the stem body, wherein farmland return water flows into the return water ditch, and a water outlet of the return water ditch is connected with a water inlet of farmland irrigation equipment.

Further, the thickness of the stem is 300 to 400mm (e.g., 300mm, 320mm, 350mm, 380mm, or 400 mm).

Further, the stem comprises the following raw materials in percentage by mass: 10-14 parts of cement, 10-14 parts of soil liquid curing agent, 22-27 parts of yellow sand and 45-60 parts of clay.

Further, the width of the water drain groove is 450-550 mm (for example, 450mm, 480mm, 520mm or 550 mm), and the depth is 250-350 mm (for example, 250mm, 280mm, 320mm or 350 mm).

Further, the returned water recycling ridge further comprises a vegetation layer arranged on the slope of the stalk body.

Further, a road plate (e.g., stone plate) is laid on the upper surface of the stem.

Further, the above-mentioned return water recycling ridge further includes a plurality of circular arc-shaped supporting members, and illustratively, the central angle of the supporting members is 90 °, and the plurality of supporting members have a guardrail state, a long corridor state and a guardrail long corridor compound state.

Further, the plurality of supporting pieces are in a guardrail state, two supporting pieces form a group, the plurality of supporting pieces are respectively arranged at two sides of the peduncles in two rows, and one end of one supporting piece is overlapped with the circle center of the other supporting piece in the adjacent two groups of supporting pieces, that is, the distance between the circle centers of the two adjacent groups of supporting pieces is equal to the radius of each group of supporting pieces.

Further, the supporting pieces are in a gallery state, four supporting pieces form a group, multiple groups of supporting pieces are axially arranged, two ends of each group of supporting pieces are respectively located at two sides of the stalk body, and the multiple groups of supporting pieces cover the upper portion of the stalk body.

Further, the plurality of support members are in a guardrail-corridor composite state, and the plurality of support members are divided into a plurality of guardrail support members and a plurality of corridor support members. The two guardrail supports form a group, the plurality of groups of guardrail supports are respectively arranged on two sides of the stem in two rows, and one end of one group of guardrail supports coincides with the circle center of the other group of guardrail supports in the adjacent two groups of guardrail supports, namely, the distance between the circle centers of the two adjacent groups of guardrail supports is equal to the radius of each group of guardrail supports; four gallery support members constitute a set of, multiunit gallery support member is arranged along the axial, and every group long gallery support member's both ends divide into and are located the both sides of the stalk body, multiunit gallery support member cover in the top of the stalk body.

Further, the supporting pieces are detachably connected with the ground and two adjacent supporting pieces in each adjacent group, so that the supporting pieces can be freely switched among the guardrail state, the long corridor state and the guardrail long corridor compound state.

Further, the cross section shape of the upper surface of the stalk body is an arc shape protruding outwards.

Further, the water return recycling ridge further comprises a water guide component, a side ditch with an opening at the top and a plant planting container with an opening at the bottom, wherein the side ditch is arranged on two sides of the stalk body, the water guide component is arranged at the opening of the side ditch, the plant planting container is arranged on the water guide component, and the side wall of the plant planting container and the water guide component form a cavity for accommodating plants.

Further, the water guiding assembly includes a plurality of layers of support nets and a water guiding layer (e.g., a sponge layer) disposed between two adjacent layers of support nets.

Further, the returned water recycling ridge further comprises a reinforcing net arranged between the side slope of the stalk body and the vegetation layer, and plant roots of the vegetation layer penetrate through the reinforcing net and grow in the side slope of the stalk body.

Further, the mesh shape of the reinforcing net is diamond, and the long diagonal line of the diamond is the same as the inclination direction of the side slope of the peduncle.

The invention also provides a manufacturing method of the returned water recycling ridge, which comprises the following steps:

cleaning the position of a ridge to be built;

compacting the in-situ plain soil;

mixing and shaping the stem raw materials in proportion, and repeatedly beating until the stem raw materials are overtime to obtain a stem;

and digging water return ditches on two sides of the stalk body to obtain a returned water recycling ridge.

Compared with the prior art, the invention has at least one of the following beneficial effects:

a) The invention provides a return water recycling ridge, which is additionally provided with a return water ditch special for collecting farmland return water, and a water outlet of the return water ditch is connected with a water inlet of farmland irrigation equipment. On one hand, the water return ditch can collect farmland water return, so that the farmland wastewater is prevented from being discharged randomly to pollute the environment water body; on the other hand, the water outlet of the water return ditch is connected with the water inlet of the farmland irrigation equipment, so that the farmland wastewater collected by the water return ditch can be reused for farmland irrigation, and the utilization rate of fertilizer and water resources can be improved.

b) According to the returned water recycling ridge, the stem slope can be effectively fixed through the growth of plant root systems in the vegetation layer, and the growth of vegetation is sustainable, so that the service time of the stem slope can be ensured.

c) The invention provides a returned water recycling ridge, which comprises a plurality of arc-shaped supporting pieces, wherein the plurality of supporting pieces are in a guardrail state, a long corridor state and a guardrail long corridor composite state; the support members are detachably connected with the ground and two adjacent support members in each adjacent group, so that the support members 5 can be freely switched among the guardrail state, the long corridor state and the guardrail long corridor compound state.

d) When the support pieces are switched from the guardrail state to the long corridor state, the two groups of support pieces with opposite positions on two sides of the peduncles are taken as examples, namely the first group of support pieces and the second group of support pieces, one ends of the first group of support pieces and the second group of support pieces, which correspond to each other, can be separated from the ground, and then the ends of the first group of support pieces and the second group of support pieces, which are separated from the ground, are connected, so that the first group of support pieces and the second group of support pieces form a group of four support pieces in total, and the four support pieces cover the upper part of the peduncles, and the support pieces are switched from the guardrail state to the long corridor state.

e) In the invention, in rainy days, rainwater in the stems flows into the side ditches and is stored in the side ditches, and at the moment, the water in the plant planting container is sufficient, so that the rainwater in the side ditches basically cannot diffuse into the plant planting container through the water guide component, and conversely, the redundant rainwater in the plant planting container can also flow into the side ditches through the water guide component and is stored; when sunny days, the water in the plant planting container is lack, and the rainwater in the side ditch can diffuse into the plant planting container through the water guide component, so that the humidity in the plant planting container can be improved.

f) According to the returned water recycling ridge and the reinforcing net, on one hand, the returned water recycling ridge can fix the side slope of the stem, and on the other hand, rainwater in the side ditch can uniformly flow through the vegetation layer along the reinforcing net, so that the situation that the vegetation layer is damaged due to too concentrated rainwater can be reduced.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

The drawings are only for purposes of illustrating particular embodiments and are not to be construed as limiting the invention, like reference numerals being used to refer to like parts throughout the several views.

Fig. 1 is a schematic structural view of a returned water recycling ridge according to an embodiment of the present invention;

fig. 2 is a longitudinal sectional view of a returned water reclamation ridge provided in the first embodiment of the present invention;

fig. 3 is a schematic structural view of a support member in a guardrail state in a returned water recycling ridge according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a support member in a gallery state in a returned water recycling ridge according to an embodiment of the present invention.

Reference numerals:

1-peduncles; 2-a vegetation layer; 3-reinforcing mesh; 4-a plant growing container; 5-a support; 6-a water guiding component; 7-side ditches; 8-road board.

Detailed Description

Preferred embodiments of the present invention are described in detail below with reference to the attached drawing figures, which form a part of the present invention and are used in conjunction with the embodiments of the present invention to illustrate the principles of the present invention.

Example 1

The invention provides a return water recycling ridge, which is shown in figures 1 to 4, and comprises a stalk body 1 and a return water ditch positioned on at least one side of the stalk body 1, wherein farmland return water flows into the return water ditch, and a water outlet of the return water ditch is connected with a water inlet of farmland irrigation equipment.

Illustratively, two sides of the stalk body 1 are provided with water-withdrawal ditches, wherein one side is a first water drainage ditch, the other side is a second water drainage ditch, and the horizontal heights, the widths and the depths of the first water drainage ditch and the second water drainage ditch are different.

Compared with the prior art, the return water recycling ridge provided by the embodiment is additionally provided with the return water ditch special for collecting farmland return water, and the water outlet of the return water ditch is connected with the water inlet of the farmland irrigation equipment. On one hand, the water return ditch can collect farmland water return, so that the farmland wastewater is prevented from being discharged randomly to pollute the environment water body; on the other hand, the water outlet of the water return ditch is connected with the water inlet of the farmland irrigation equipment, so that the farmland wastewater collected by the water return ditch can be reused for farmland irrigation, and the utilization rate of fertilizer and water resources can be improved.

The returned water recycling ridge can be used for terraces or plain fields.

To secure a farmland drainage capacity of the drainage ditch, the drainage ditch is, for example, 450 to 550mm (for example, 450mm, 480mm, 520mm or 550 mm) in width and 250 to 350mm (for example, 250mm, 280mm, 320mm or 350 mm) in depth.

For the stem 1, the thickness of the stem 1 is 300-400 mm (for example, 300mm, 320mm, 350mm, 380mm or 400 mm), and the mass percentage of the raw materials of the stem 1 comprises: 10-14 parts of cement, 10-14 parts of soil liquid curing agent, 22-27 parts of yellow sand and 45-60 parts of clay.

Considering that the existing ridge is usually obtained by ridging soil in the field, collapse, deformation or damage are very easy, the water return recycling ridge further comprises a vegetation layer 2 arranged on the slope of the stalk body 1, and therefore the slope of the stalk body 1 can be effectively fixed through growth of plant roots in the vegetation layer 2, and growth of vegetation is sustainable, so that the service time of the slope of the stalk body 1 can be ensured.

It will be appreciated that, in order to facilitate the user's walking on the ridge, the upper surface of the stem 1 is paved with a road plate 8 (for example, a stone plate). Thus, because the strength of the road plate 8 is greater than that of the stalk body 1, a user can walk on the road plate 8, and the use comfort of the user is improved.

In order to improve the beauty of the above-mentioned returned water reclamation ridge, it also includes a plurality of convex support pieces 5, and illustratively, the central angle of support piece 5 is 90, and a plurality of support pieces 5 have guardrail state, long corridor state and guardrail long corridor complex state.

The supporting pieces 5 are in a guardrail state, two supporting pieces 5 form a group, the supporting pieces 5 are respectively arranged at two sides of the stem body 1 in two rows, and one end of one supporting piece 5 in two adjacent supporting pieces 5 is overlapped with the circle center of the other supporting piece 5, that is, the distance between the circle centers of the two adjacent supporting pieces 5 is equal to the radius of each supporting piece 5.

The support pieces 5 are in a gallery state, four support pieces 5 form a group, the support pieces 5 are axially arranged, two ends of each support piece 5 are respectively located at two sides of the stalk body 1, the support pieces 5 can form a gallery shape, the support pieces 5 cover the upper side of the stalk body 1, the support pieces can be used for supporting growth of vine plants to form a landscape gallery, and attractiveness of the water return ridge is improved.

The plurality of supporting members 5 are in a guardrail-long corridor composite state, and the plurality of supporting members 5 may be divided into a plurality of guardrail supporting members and a plurality of long corridor supporting members. Two guardrail supporting pieces form a group, a plurality of groups of guardrail supporting pieces are respectively arranged on two sides of the stem body 1 in two rows, and one end of one group of guardrail supporting pieces coincides with the circle center of the other group of guardrail supporting pieces in the adjacent two groups of guardrail supporting pieces, namely, the distance between the circle centers of the two adjacent groups of guardrail supporting pieces is equal to the radius of each group of guardrail supporting pieces; four long corridor support pieces constitute a set of, and multiunit long corridor support piece is arranged along the axial, and every long corridor support piece's of group both ends divide into and are located the both sides of stalk body 1 for multiunit long corridor support piece can form long corridor shape, multiunit long corridor support piece covers in the top of stalk body 1.

It should be noted that, the support members 5 are detachably connected with the ground and two adjacent support members 5 in each adjacent group, so that the plurality of support members 5 can be freely switched among the guardrail state, the long corridor state and the guardrail long corridor composite state.

For example, when the supporting members 5 are switched from the guardrail state to the gallery state, taking two groups of supporting members 5 with opposite positions on two sides of the stem 1 as an example, namely a first group of supporting members 5 and a second group of supporting members 5, one ends of the first group of supporting members 5 and the second group of supporting members 5 corresponding to each other can be separated from the ground, and then the ends of the first group of supporting members 5 and the second group of supporting members 5 separated from the ground are connected, so that the first group of supporting members 5 and the second group of supporting members form a group of four supporting members 5 in total and cover the upper portion of the stem 1, thereby completing the switching of the supporting members 5 from the guardrail state to the gallery state.

When the supporting pieces 5 are switched from the guardrail state to the guardrail gallery state, taking four groups of supporting pieces 5 with opposite positions on two sides of the peduncle 1 as examples, namely a first group of supporting pieces 5, a second group of supporting pieces 5, a third group of supporting pieces 5 and a fourth group of supporting pieces 5, wherein the first group of supporting pieces 5 and the third group of supporting pieces 5 are positioned on one side of the peduncle 1, the second group of supporting pieces 5 and the fourth group of supporting pieces 5 are positioned on the other side of the peduncle 1, one ends corresponding to the first group of supporting pieces 5 and the second group of supporting pieces 5 can be separated from the ground, then, the first group of supporting pieces 5 and the second group of supporting pieces 5 are connected with the end separated from the ground, so that the first group of supporting pieces 5 and the second group of supporting pieces form a group of supporting pieces 5, the four supporting pieces 5 are covered above the peduncle 1, the structures of the first group of supporting pieces 5 and the second group of supporting pieces 5 are used as the long gallery supporting pieces, the structures of the third group of supporting pieces 5 and the fourth group of supporting pieces are unchanged, and the structures of the supporting pieces of the first group of supporting pieces 5 are used as guardrail supporting pieces, and then, the first group of supporting pieces 5 and the ends are separated from the guardrail gallery state are switched from the guardrail state to the guardrail gallery state. It should be noted that, when the supporting members 5 are in the guardrail state, the distance between the centers of the two adjacent groups of supporting members 5 is equal to the radius of each group of supporting members 5, and when the guardrail is switched from the guardrail state to the guardrail gallery state, the distance between the centers of the two adjacent groups of supporting members is equal to the radius of each group of supporting members, that is, the distance between the supporting members 5 of each group is increased, but the formed guardrail is still in a continuous state.

In order to avoid serious water accumulation in the stem 1 in rainy days, an outwardly convex arc shape may be used for the cross-sectional shape of the upper surface of the stem 1, for example. Like this, adopt the curved stalk body 1 of evagination, can be convenient for rainwater from stalk body 1 central authorities to stalk body 1 both sides to can avoid rainy day stalk body 1 water accumulation seriously.

Considering that the rainwater is abundant water resource, in order to effectively utilize the rainwater, the water return recycling ridge further comprises a water guide component 6, a side ditch 7 with an open top and a plant planting container 4 with an open bottom, wherein the side ditch 7 is arranged on two sides of the stalk body 1, the water guide component 6 is arranged at the opening of the side ditch 7, the plant planting container 4 is arranged on the water guide component 6, and the side wall of the plant planting container 4 and the water guide component 6 form a cavity for accommodating plants. In rainy days, rainwater in the stem body 1 flows into the side ditch 7 and is stored in the side ditch 7, and at the moment, the water in the plant planting container 4 is sufficient, so that the rainwater in the side ditch 7 basically cannot diffuse into the plant planting container 4 through the water guide component 6, and conversely, the excessive rainwater in the plant planting container 4 can also flow into the side ditch 7 through the water guide component 6 and be stored; on sunny days, the water in the plant planting container 4 is lack, and the rainwater in the side ditch 7 can diffuse into the plant planting container 4 through the water guide component 6, so that the humidity in the plant planting container 4 can be improved.

The structure of the water guide assembly 6 specifically includes a plurality of support nets and a water guide layer (e.g., a sponge layer) provided between two adjacent support nets. This is because, on the one hand, the provision of the support net can improve the overall structural strength of the water guide assembly 6, and on the other hand, the water guide layer provided between the adjacent two support nets can realize the rainwater circulation between the side ditch 7 and the plant growing container 4.

It should be noted that, when the rainfall is large, rainwater may overflow from the side ditch 7 and flow into the water-withdrawal ditch through the vegetation layer 2, in order to avoid damage to the vegetation layer 2 caused by too concentrated rainwater, the water-withdrawal and recycling ridge further includes a reinforcing net 3 disposed between the side slope of the stalk body 1 and the vegetation layer 2, and the plant root system of the vegetation layer 2 passes through the reinforcing net 3 and grows in the side slope of the stalk body 1. The setting of reinforcing net 3, on the one hand, it can play fixed action to the side slope of the stalk body 1, and on the other hand, the rainwater in the side ditch 7 can evenly flow through vegetation layer 2 along reinforcing net 3 to can reduce the condition emergence that the rainwater is too concentrated and causes the destruction to vegetation layer 2.

In order to improve the distribution uniformity of the rainwater flowing through the reinforcing net 3, the mesh shape of the reinforcing net 3 may be diamond, and the long diagonal line of the diamond is the same as the inclination direction of the side slope of the stem 1. Like this, when the rainwater flows through reinforcing net 3 and with reinforcing net 3 contact, owing to reinforcing net 3 slope setting, under the effect of gravity, the rainwater can flow down along reinforcing net 3, simultaneously, under the effect of rainwater tension, the rainwater can be along one of them acute angle downwardly diffused of diamond, forms comparatively even water film to can the rainwater at reinforcing net 3's distribution homogeneity, avoid the rainwater to flow through vegetation layer 2 too intensively.

Example two

The embodiment provides a manufacturing method of a returned water recycling ridge, which comprises the following steps:

cleaning the position of a ridge to be built;

compacting the in-situ plain soil;

mixing and shaping the stem raw materials in proportion, and repeatedly beating until the stem raw materials are overtime to obtain a stem;

and digging water return ditches on two sides of the stalk body to obtain a returned water recycling ridge.

Compared with the prior art, the beneficial effects of the manufacturing method of the returned water recycling ridge provided by the embodiment are basically the same as those of the returned water recycling ridge provided by the embodiment one, and are not repeated here.

The present invention is not limited to the above-mentioned embodiments, and any changes or substitutions that can be easily understood by those skilled in the art within the technical scope of the present invention are intended to be included in the scope of the present invention.

Claims (10)

1. The returned water recycling ridge is characterized by comprising a stalk body and a returned water ditch positioned on at least one side of the stalk body, wherein a water outlet of the returned water ditch is connected with a water inlet of farm irrigation equipment.

2. The returned water reclamation ridge as recited in claim 1, wherein the thickness of the stems is 300-400 mm.

3. The returned water reclamation ridge as recited in claim 1, wherein the raw materials of the stems comprise the following mass percentages: 10-14 parts of cement, 10-14 parts of soil liquid curing agent, 22-27 parts of yellow sand and 45-60 parts of clay.

4. The return water reclamation ridge as recited in claim 1, wherein the width of the return water channel is 450-550 mm and the depth is 250-350 mm.

5. The returned water reclamation ridge as recited in claim 1, wherein a road plate is laid on the upper surface of the stalk body.

6. The returned water reclamation ridge as recited in claim 1, wherein the cross-sectional shape of the upper surface of the stalk body is a convex pattern.

7. The returned water reclamation ridge of claim 1, further comprising a water guide assembly, a side ditch with an open top and a plant planting container with an open bottom, wherein the side ditch is arranged on two sides of the stalk body, the water guide assembly is arranged at the opening of the side ditch, the plant planting container is arranged on the water guide assembly, and the side wall of the plant planting container and the water guide assembly form a cavity for accommodating plants.

8. The returned water reclamation ridge of claim 7, wherein the water guide assembly comprises a plurality of layers of support screens and a water guide layer disposed between adjacent two layers of support screens.

9. The returned water reclamation ridge of claim 7, further comprising a reinforcing mesh disposed between the stalk side slope and the vegetation layer, the plant roots of the vegetation layer passing through the reinforcing mesh and growing in the stalk side slope.

10. A method for manufacturing a returned water recycling ridge according to claims 1 to 9, comprising the steps of:

cleaning the position of a ridge to be built;

compacting the in-situ plain soil;

mixing and shaping the stem raw materials in proportion, and repeatedly beating until the stem raw materials are overtime to obtain a stem;

and digging water return ditches on two sides of the stalk body to obtain a returned water recycling ridge.

Images