CN113250157B - Agricultural irrigation prevention of seepage channel structure - Google Patents

Abstract

The utility model relates to an agricultural irrigation prevention of seepage channel structure relates to irrigation's field, and it includes the channel body, establish the support base on the channel body, establish the water pump on supporting the base, with the inlet tube of water pump intercommunication and with the outlet pipe of water pump intercommunication, support and leave the space between base and the channel body, the one end of inlet tube is passed the water inlet intercommunication that supports base, the other end and water pump, the one end of outlet pipe and the delivery port intercommunication of water pump, the other end and channel body intercommunication. The present application has the effect of reducing leakage of water.

Description

Agricultural irrigation prevention of seepage channel structure

Technical Field

The application relates to irrigation's field especially relates to an agricultural irrigation prevention of seepage channel structure.

Background

The irrigation channel is a water channel connecting an irrigation water source and an irrigation land. Water drawn from a water source is delivered and distributed to various parts of the irrigation area.

After the existing irrigation channel is used for a long time, the irrigation channel is aged, and further water leakage may occur. The water leaks into the ground to cause a waste of water.

Disclosure of Invention

In order to reduce the leakage of water, the application provides an agricultural irrigation seepage-proofing channel structure.

The application provides a pair of agricultural irrigation prevention of seepage channel structure adopts following technical scheme:

an agricultural irrigation seepage-proofing channel structure comprises a channel body, a support base arranged on the channel body, a water pump arranged on the support base, a water inlet pipe communicated with the water pump and a water outlet pipe communicated with the water pump; a gap is reserved between the supporting base and the channel body, one end of the water inlet pipe penetrates through the supporting base, and the other end of the water inlet pipe is communicated with a water inlet of the water pump; one end of the water outlet pipe is communicated with the water outlet of the water pump, and the other end of the water outlet pipe is communicated with the channel body.

By adopting the technical scheme, the plurality of channel bodies are connected to form the irrigation channel, the irrigation water flows along the channel bodies, when water leaks, the water flows to the supporting base from a gap between the adjacent channel bodies, a gap between the channel bodies and the supporting base is used for storing the water, the water pump pumps the water on the supporting base into the water inlet pipe, the water is re-conveyed into the channel bodies through the water outlet pipe, and the situation that the water permeates to the position below the ground surface is reduced.

Optionally, a support column is arranged on the support base; the one end and the support base fixed connection, the other end and the channel body fixed connection of support column, the support column is arranged in the space between channel body and the support base.

Through adopting above-mentioned technical scheme, the support column plays the support and accepts the effect to supporting base and channel body, makes the channel body be difficult to take place to collapse after long-time the use.

Optionally, a plurality of first grooves are formed in the supporting base; the water inlet pipe is positioned at the bottom of the first groove.

Through adopting above-mentioned technical scheme, water flows to first basin in, and more percolating water can be stored to first basin.

Optionally, a first waterproof layer is laid on the supporting base; the first waterproof layer is located in the first groove.

Through adopting above-mentioned technical scheme, first waterproof layer separates water and support base, makes water be difficult to with supporting the base contact, and then makes water be difficult to the seepage below the earth's surface.

Optionally, the channel body is provided with a butt joint part, and the channel body is provided with a butt joint groove; the abutting part of the adjacent channel body is positioned in the abutting groove.

By adopting the technical scheme, when two adjacent channel bodies are connected, the butt joint part is inserted into the butt joint groove and then sealed by mortar and the like, so that the gap between the channel bodies is reduced, and water is further prevented from leaking into the gap between the channel bodies and the supporting base.

Optionally, the channel body is provided with a connecting part, the connecting part is located between the channel body and the support base, and the connecting parts of adjacent channel bodies are abutted; the connecting part is provided with a first sliding chute, the connecting part is connected with a connecting plate in a sliding manner, and the connecting plate is provided with a first convex strip; the first protruding strip is located in the first sliding groove.

Through adopting above-mentioned technical scheme, when two adjacent channel body coupling, the connecting portion butt of two channel bodies, then in injecting first spout with the connecting plate, further reduced the gap between the channel body, and then reduced the seepage of water.

Optionally, a slope portion is arranged on the supporting base; the slope part is positioned between the channel body and the support base, and the slope parts on the adjacent support bases are abutted; the slope surface part is provided with a second sliding groove, the slope surface part is connected with a cover plate in a sliding mode, the cover plate is provided with a second raised line, and the second raised line is located in the second sliding groove.

Through adopting above-mentioned technical scheme, the domatic portion butt of two channel bodies, then inject the apron in the second spout to reduce the gap between the domatic portion, when taking place the seepage, water flows to the support base along domatic portion on, domatic portion plays the guide effect to water, and the apron makes water be difficult to the seepage below the earth's surface.

Optionally, a second groove is formed in the channel body, and the second grooves adjacent to the channel body are communicated; and a second waterproof layer is arranged in the second groove.

Through adopting above-mentioned technical scheme, when two channel noumenons were connected, the staff injects the second waterproof layer in the second recess to make water be difficult to follow the side seepage of channel noumenon to the below-ground.

Optionally, a third water-proofing layer is paved on the channel body.

Through adopting above-mentioned technical scheme, the third prevention water layer is laid on the channel body, has further reduced the seepage of water.

Optionally, a liquid level sensor is arranged on the support base, a signal output end of the liquid level sensor is connected with a controller, and a signal output end of the controller is connected with a WIFI wireless transmitting device;

the liquid level sensor detects the height of the water level and outputs a liquid level signal, and the controller responds to the liquid level signal and sends the height information of the water level to the data center through the WIFI wireless transmitting device.

Through adopting above-mentioned technical scheme, level sensor is used for detecting the height of channel body and support water level between the base and exports the liquid level signal, and the controller responds the liquid level signal and transmits the water level height information in the liquid level signal to WIFI wireless transmitting device, and water level height information sends to data center through WIFI wireless transmitting device to make things convenient for the staff to monitor.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the irrigation channels are formed by connecting the channel bodies, irrigation water flows along the channel bodies, when water leaks, the water flows onto the supporting base from a gap between the adjacent channel bodies, a gap between the channel bodies and the supporting base is used for storing the water, the water pump pumps the water on the supporting base into the water inlet pipe and delivers the water into the channel bodies again through the water outlet pipe, and the situation that the water permeates below the ground surface is reduced;

2. the liquid level sensor is used for detecting the height of the water level between the channel body and the supporting base and outputting a liquid level signal, the controller responds to the liquid level signal and transmits water level height information in the liquid level signal to the WIFI wireless transmitting device, and the water level height information is transmitted to the data center through the WIFI wireless transmitting device, so that monitoring of workers is facilitated.

Drawings

Fig. 1 is an isometric view of an agricultural irrigation impervious canal structure according to an embodiment of the present application.

Fig. 2 is an enlarged view of a portion a in fig. 1.

Fig. 3 is a partial sectional view of the agricultural irrigation impermeable channel structure shown in fig. 1.

Fig. 4 is an enlarged view of a portion B in fig. 3.

Fig. 5 is an enlarged view of a portion C in fig. 3.

Fig. 6 is a schematic diagram of a liquid level sensor, a controller and a WIFI wireless transmission device in an embodiment of the present application.

Description of reference numerals: 11. a channel body; 111. a butt joint groove; 112. a second groove; 12. a support base; 121. a first groove; 2. a water pump; 31. a water inlet pipe; 32. a water outlet pipe; 4. a support pillar; 51. a first waterproof layer; 52. a second waterproof layer; 53. a third water layer; 6. a docking portion; 71. a connecting portion; 711. a first chute; 72. a connecting plate; 73. a first rib; 81. a slope surface portion; 811. a second chute; 82. a cover plate; 83. a second convex strip; 91. a liquid level sensor; 92. a controller; 93. WIFI wireless transmitting device.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses agricultural irrigation prevention of seepage channel structure.

Referring to fig. 1 and 2, an agricultural irrigation seepage-proofing channel structure includes a plurality of channel bodies 11, a plurality of support bases 12, a plurality of water inlet pipes 31, a plurality of water pumps 2, and a plurality of water outlet pipes 32. The channel body 11 is used for guiding water flow, and the supporting base 12 is fixedly connected with the channel body 11 and is positioned below the supporting base 12. A gap is reserved between the channel body 11 and the supporting base 12, and one end of the water inlet pipe 31 is communicated with a water inlet which penetrates through the supporting base 12 and the other end of the water inlet pipe and the water pump 2. One end of the water outlet pipe 32 is communicated with the water outlet of the water pump 2, and the other end of the water outlet pipe passes through the channel body 11. When a leakage situation occurs, water flows through the channel body 11 onto the support base 12, and the space between the channel body 11 and the support base 12 is used for storing the permeated water. The water pump 2 pumps water into the inlet pipe 31 and re-delivers the water into the channel body 11 through the outlet pipe 32, thereby reducing leakage of the water.

Referring to fig. 1 and 3, the longitudinal section of the channel body 11 is trapezoidal, the width of the bottom surface of the channel body 11 is smaller than that of the top surface of the channel body 11, a third water prevention layer 53 is paved on the bottom surface of the channel body 11, the third water prevention layer 53 can be a waterproof coiled material, after the irrigation channel is built by a worker, the waterproof coiled material is paved on the bottom surface of the channel body 11, and the waterproof coiled material reduces the water leakage condition. The supporting base 12 is fixedly connected with the bottom surface of the canal body 11. The supporting base 12 is provided with a first groove 121, the first groove 121 is located between the channel body 11 and the supporting base 12, and the first groove 121 is used for receiving and storing more leaked water. A channel body 11 and a support base 12 form a channel unit, which is prefabricated. Each channel unit is provided with a water inlet pipe 31, a water pump 2 and a water outlet pipe 32. One end of the water inlet pipe 31 penetrates out of the supporting base 12 at the bottom of the first groove 121, and the other end is communicated with the water pump 2. And (4) when the irrigation channel is built, the workers overlap a plurality of prefabricated channel units.

Referring to fig. 3, in order to prevent the water leaked into the first groove 121 from leaking again, a first waterproof layer 51 is fixedly connected to the support base 12 at the bottom of the first groove 121, the first waterproof layer 51 may be a waterproof roll or a waterproof paint, the first waterproof layer 51 separates water from the support base 12, and the water falls on the first waterproof layer 51, so that the water is not easily contacted with the support base 12, and the leakage of the water is reduced.

Referring to fig. 3, in order to enhance the firmness between the channel body 11 and the support base 12, a plurality of support pillars 4 are arranged on the support base 12, the plurality of support pillars 4 are uniformly distributed on the support base 12, the support pillars 4 are perpendicular to the support base 12, one end of each support pillar 4 is fixedly connected with the support base 12, and the other end of each support pillar 4 is fixedly connected with the channel body 11. The supporting columns 4 support the channel body 11, so that the channel body 11 is not easy to collapse, and the service lives of the channel body 11 and the supporting base 12 are prolonged.

Referring to fig. 3 and 4, in order to facilitate overlapping of the channel body 11, the channel body 11 is fixedly connected with the butting portion 6 and the butting groove 111, and the butting portion 6 and the butting groove 111 are located at both ends of the laying direction of the channel body 11. When two adjacent channel bodies 11 are lapped, the butt joint part 6 of one channel body 11 is inserted into the butt joint part 6 of the other channel body 11, so that the gap between the two adjacent channel bodies 11 is reduced, and after the butt joint part 6 is inserted into the butt joint groove 111, mortar is used for sealing, so that the gap is further reduced, and the channel bodies 11 are further not easy to leak.

Referring to fig. 1 and 2, a second groove 112 is formed in the channel body 11, the second grooves 112 are located on two sides of the laying direction of the channel body 11, the second grooves 112 extend to the supporting base 12, the second grooves 112 are located on the longitudinal section of the channel body 11, four second grooves 112 are formed in one channel unit, and two second grooves 112 are formed in two end faces of the laying direction of the channel unit. When two adjacent channel bodies 11 are connected in an overlapping manner, the second grooves 112 of the two adjacent channel bodies 11 are communicated, and a second waterproof layer 52 is arranged in the second groove 112. After the staff installs second waterproof layer 52 in second recess 112, use the mortar to carry out the shutoff to reduce the gap, made water be difficult to ooze from the lateral wall of channel body 11 and support base 12, and then reduced the condition of seepage.

Referring to fig. 3 and 4, in order to further reduce the gap at the connection between two adjacent channel bodies 11, a connection portion 71 is fixedly connected to each channel body 11, the connection portion 71 is located between each channel body 11 and the support base 12, the connection portion 71 is composed of a vertical plate and a transverse plate, one end of the vertical plate is fixedly connected to each channel body 11, and the other end of the vertical plate is fixedly connected to the transverse plate. The riser is perpendicular to the channel body 11, the diaphragm is perpendicular to the riser. Both ends of the laying direction of each channel body 11 are provided with a connecting portion 71.

When two adjacent channel units are connected in an overlapping manner, the connecting parts 71 on the two adjacent channel units are connected in an abutting manner, the transverse plates of the two connected connecting parts 71 are provided with first sliding grooves 711, and the opening direction of the first sliding grooves 711 is perpendicular to the laying direction of the channel body 11. A connecting plate 72 is slidably connected to a transverse plate of the connecting portion 71, two first protruding strips 73 are arranged on the connecting plate 72, and the two first protruding strips 73 are respectively located on the two abutted connecting portions 71. The connecting plate 72 and the first protruding strips 73 further reduce gaps between two adjacent channel bodies 11, and then workers pour materials such as mortar to plug the gaps so as to further reduce water leakage.

Referring to fig. 3 and 5, in order to reduce water leakage from between two adjacent channel bodies 11 to the channel bodies 11, a slope portion 81 is provided on the support base 12, and the slope portion 81 and the support base 12 are integrally formed at the time of prefabrication. Each supporting base 12 is provided with two slope parts 81, and the two slope parts 81 are respectively located at two ends of the laying direction of the channel body 11. When the irrigation channel is built, the two adjacent channel bodies 11 are abutted, so that the slope surface parts 81 on the two support bases 12 are abutted, the slope surface parts 81 are provided with second sliding grooves 811, the second sliding grooves 811 are perpendicular to the laying direction of the channel bodies 11, and the second sliding grooves 811 are located on the side, facing the cavity between the channel bodies 11 and the support bases 12, of the slope surface parts 81. The slope part 81 is further connected with a cover plate 82 in a sliding mode, the cover plate 82 is composed of two plates which are identical in shape and size, the two plates are fixedly connected, and an included angle formed between the two plates is identical to an included angle formed by the slope part 81 on the two adjacent channel bodies 11 after being abutted. Two second protruding strips 83 are fixedly connected to the cover plate 82, and the second protruding strips 83 are located at ends of the two plates far away from the fixed ends.

When the irrigation channel is built, after the slope parts 81 on two adjacent channel bodies 11 are abutted, the cover plate 82 is inserted into the channel bodies 11, and the second convex strip 83 on the cover plate 82 is positioned in the second sliding groove 811. The cover plate 82 reduces the gap between the slope parts 81 on the two adjacent channel bodies 11, and when water leaks from the gap between the channel bodies 11, the water flows to the surface of the slope parts 81 along the cover plate 82, so that the water is not easy to leak out of the channel bodies 11 from the gap between the slope parts 81.

Referring to fig. 2 and 6, in order to facilitate a person to observe the water level in the cavity between the channel body 11 and the support base 12, a liquid level sensor 91 is fixedly connected to the support base 12, the liquid level sensor 91 is perpendicular to the support base 12, and the liquid level sensor 91 is located in the first groove 121. When the water seepage occurs and water flows into the first groove 121, the liquid level sensor 91 detects the height of the water level in the first groove 121 and outputs a liquid level signal based on the detected height of the water level. The signal output end of the liquid level sensor 91 is further connected with a controller 92, the signal output end of the liquid level sensor 91 is connected with the signal input end of the controller 92, and the signal output end of the controller 92 is further connected with a WIFI wireless transmitting device 93.

After the controller 92 responds to the liquid level signal, the water level height information in the liquid level signal is transmitted to the WIFI wireless transmitting device 93, the WIFI wireless transmitting device 93 transmits the water level height information in a wireless mode, the WIFI wireless transmitting device 93 transmits the water level height information to the data center, and the water level height information received by the data center by a worker is convenient for detecting the water seepage condition of the channel body 11. In other embodiments, the WIFI wireless transmitting device 93 may also send the water level height information to an intelligent terminal of the staff, such as a mobile phone, a computer, etc., so that the staff can detect the water seepage situation conveniently.

The implementation principle of agricultural irrigation anti-seepage channel structure in the embodiment of the application is as follows: channel body 11 is used for drawing water, when the infiltration condition takes place for channel body 11, the water seepage is to supporting on the base 12, first recess 121 and cavity accept the storage to water, water pump 2 is taken out the water of storage to inlet tube 31 and is discharged the channel body 11 with the water through outlet pipe 32, thereby the seepage of water has been reduced, first waterproof layer 51 makes water be difficult to and support base 12 contact when first recess 121 is interior, and then make water be difficult to the seepage and support base 12, domatic portion 81 reduces the gap between two adjacent channel bodies 11 with apron 82, and water is along domatic flow supporting on the base 12, connecting portion 71 and connecting plate 72 have further reduced the gap between two adjacent channel bodies 11, thereby reduce the seepage of water. Liquid level sensor 91 detects the water level height in first recess 121 and the cavity and output liquid level signal, and controller 92 sends water level height information to data center through WIFI wireless transmitting device 93 after responding to liquid level signal to make the staff be convenient for monitor the water level.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (7)

1. The utility model provides an agricultural irrigation prevention of seepage channel structure which characterized in that: comprises a channel body (11), a supporting base (12) arranged on the channel body (11), a water pump (2) arranged on the supporting base (12), a water inlet pipe (31) communicated with the water pump (2) and a water outlet pipe (32) communicated with the water pump (2); a gap is reserved between the supporting base (12) and the channel body (11), one end of the water inlet pipe (31) penetrates through the supporting base (12), and the other end of the water inlet pipe is communicated with a water inlet of the water pump (2); one end of the water outlet pipe (32) is communicated with the water outlet of the water pump (2), and the other end of the water outlet pipe is communicated with the channel body (1);

the channel body (11) is provided with a connecting part (71), the connecting part is positioned between the channel body (11) and the supporting base (12), and the connecting parts (71) of the adjacent channel bodies (11) are abutted; a first sliding groove (711) is formed in the connecting portion (71), a connecting plate (72) is connected to the connecting portion (71) in a sliding mode, and a first protruding strip (73) is arranged on the connecting plate (72); the first protruding strip (73) is positioned in the first sliding groove (711);

a slope part (81) is arranged on the supporting base (12); the slope part (81) is positioned between the channel body (11) and the supporting base (12), and the slope parts (81) on the adjacent supporting bases (12) are abutted; a second sliding groove (811) is formed in the slope portion (81), a cover plate (82) is connected to the slope portion (81) in a sliding mode, a second protruding strip (83) is arranged on the cover plate (82), and the second protruding strip (83) is located in the second sliding groove (811);

the channel body (11) is provided with a butt joint part (6), and the channel body (11) is provided with a butt joint groove (111); the butt joint part (6) adjacent to the channel body (11) is positioned in the butt joint groove (111).

2. The agricultural irrigation seepage-proofing channel structure according to claim 1, wherein: a support column (4) is arranged on the support base (12); one end and support base (12) fixed connection, the other end and channel body (11) fixed connection of support column (4), support column (4) are arranged in the space between channel body (11) and support base (12).

3. The agricultural irrigation seepage-proofing channel structure according to claim 1, wherein: a plurality of first grooves (121) are formed in the supporting base (12); the water inlet pipe (31) is positioned at the bottom of the first groove (121).

4. An agricultural irrigation seepage-proofing channel structure according to claim 3, wherein: a first waterproof layer (51) is paved on the supporting base (12); the first waterproof layer (51) is positioned in the first groove (121).

5. The agricultural irrigation seepage-proofing channel structure according to claim 1, wherein: a second groove (112) is formed in the channel body (11), and the second grooves (112) of the adjacent channel bodies (11) are communicated; and a second waterproof layer (52) is arranged in the second groove (112).

6. An agricultural irrigation anti-seepage channel structure according to claim 1, characterized in that: and a third water-proofing layer (53) is paved on the channel body (11).

7. The agricultural irrigation seepage-proofing channel structure according to claim 1, wherein: a liquid level sensor (91) is arranged on the supporting base (12), a signal output end of the liquid level sensor (91) is connected with a controller (92), and a signal output end of the controller (92) is connected with a WIFI wireless transmitting device (93);

the liquid level sensor (91) detects the water level height and outputs a liquid level signal, and the controller (92) responds to the liquid level signal and sends the water level height information to the data center through the WIFI wireless transmitting device (93).

Images