| CPC E02B 3/02 (2013.01) [A01G 22/22 (2018.02); E02B 8/02 (2013.01)] | 5 Claims |
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1. A construction method for a flood storage area ecological wetland oriented to multi-target collaborative promotion, comprising the following steps:
a) carrying out ecological wetland construction on a flood storage area by taking promotion of agricultural production as a goal:
b) determining a land type in the flood storage area and determining a basic farmland area of the flood storage area;
c) determining a planting object of the basic farmland area;
d) carrying out a wetland engineering layout on the flood storage area by following a principle of minimum engineering quantity according to a landform, a land type and a regional status quo of the flood storage area, the wetland engineering layout comprising: performing functional zoning on the flood storage area and transforming the basic farmland area into a terraced wetland; the regional status quo comprising original river system distribution, planted vegetation, and building conditions of the flood storage area;
the step of performing the functional zoning on the flood storage area in step d) comprises:
taking a low-lying area where rice is planted as a multi-paddy-field wetland area, a low-lying area being a water surface as a small and micro wetland, and a high-lying area as a forest and grass wetland area;
the step of transforming the basic farmland area into the terraced wetland in step d) comprises: combining small fields into a large field, carrying out land leveling on a field with a land elevation difference of more than 20 cm, disposing nested ditches at preset intervals on an individual field with a length of more than 200 m, and dredging original ditches in the field, wherein the ditches are spaced at intervals of 100 m to 200 m, and a water intake canal and a water exhaust canal are separated from each other;
disposing gabion boxes on two sides of the nested ditch; and inside the nested ditch, laying a first zeolite with a size of 4 cm to 6 cm on two sides, and laying a second zeolite with a size of 1 cm to 3 cm in a middle;
e) constructing a water inlet and outlet system of the flood storage area ecological wetland based on an intake and drainage separation principle;
the step of constructing the water inlet and outlet system of the flood storage area ecological wetland in step e) comprises:
constructing an overall water inlet and outlet system by: using a total wetland water intake gate and a built river gate in the flood storage area for self-flow diversion of water, causing water to first enter a dike and settle and be purified in a stabilization pond, and then enter a wetland water distribution main canal to dispense water for each wetland unit from top to bottom, and finally, pumping and discharging purified river water back to an original river through a water drainage station; and
constructing a water inlet and outlet system inside the flood storage area: dredging a current water intake canal and a current water exhaust canal of the flood storage area, and distinguishing a water intake ditch from a water drain ditch; for an area where a water system fails to be communicated, connecting the ditches by means of excavation; providing a water inlet control sluice gate at a water inlet; and providing a water outlet control sluice gate at a water outlet end of a water outlet branch canal;
f) constructing the flood storage area ecological wetland when the flood storage area does not reach the water purification target at present according to a water purification target of the flood storage area of the flood storage area ecological wetland and a current pollution condition in the flood storage area:
g) investigating a pollution source inside the flood storage area, and analyzing and determining a main pollution load;
h) choosing at least one of the following measures for implementation according to the main pollution load: adopting an ecological agriculture planting mode, transforming a water surface of a current pit-pond to form a small and micro wetland, building an island with silt and treating polluted sediment using an ecological infiltration technology; and
h) carrying out ecological planting and breeding in the multi-paddy-field wetland area;
i) carrying out the following ecological wetland construction on the flood storage area in order to improve biodiversity:
j) in conjunction with the water inlet and outlet system constructed in step e) and based on the wetland engineering layout obtained in step d), further transforming the flood storage area into multiple types of wetland habitats having a water purification function, comprising a paddy field wetland, a marsh wetland, a forest and grass wetland, a river wetland and a small and micro wetland; and increasing a species and a quantity of organisms in the flood storage area by using habitat restoration and food web structure adjustment and control technologies;
the step of further transforming the flood storage area into the multiple types of wetland habitats having the water purification function comprises:
restoring a paddy field wetland and a small and micro wetland in the multi-paddy-field wetland area; restoring a paddy field wetland and a small and micro wetland in the marsh wetland; and restoring a paddy field wetland, a corn field, a small and micro wetland and a forest land in the forest and grass wetland area; wherein
the small and micro wetland is obtained by transforming the water surface of the original pit-pond, a percolation weir is disposed in the small and micro wetland, and a substrate in the percolation weir comprises zeolite with a size of 1 cm to 3 cm and limestone gravel with a size of 10 cm to 20 cm.
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