A basement system includes a concrete basement and a drain channel. The concrete basement includes a basement slab and a basement wall. The basement slab presents a floor surface, with the basement wall extending about the floor surface. The basement slab and basement wall cooperatively define a trench that extends along the basement wall and below the floor surface to receive water in the basement. The drain channel is located at least partly in the trench to collect water therein. The drain channel includes an elongated channel tube and an upright riser integrally formed with the channel tube. The channel tube includes axially-extending opposite side walls that at least partly define an interior to receive water, with at least one of the side walls presenting openings that permit water ingress from the trench to the interior. The riser extends upwardly from one of the side walls and engages the basement wall.

A drainage device for use under the floor of a building to facilitate drainage of water along a foundation of the building under the floor. A bridge drainage device permits more rapid installation of the drainage devices. The bridge device can be used to bridge between two drainage devices so that it is not necessary to cut the drainage devices precisely to fit on a footing of any selected length.

A construction method of reclaiming land from the sea based on the basement utilization, which implementation steps are as follows: a. installing a dike along the coastline, enclosing a central reclamation area by the dike and the coastline; b. installing crisscross enclosures in the central reclamation area, dividing the central reclamation area into a mesh area by the enclosure and the dike; c, pumping drainage of seawater in a block area in the mesh area, forming land in the block area; d. constructing the enclosure in the mesh reclamation area, using the enclosure and subsidiary roads to form road arteriality; the block area being lower than the height of the enclosure, constituting a grid-like high-road/low-land land supply mode; e. developing the block area into an underground space area.

The present disclosure provides a water drainage system comprising: a plurality of lengths of drain pipe comprising a channel and a vertical wall, wherein (i) the vertical wall comprises one or more standoffs extending horizontally from the vertical wall and (ii) wherein the drain pipe comprises a top edge and a bottom edge, each of the top and bottom edges being bifurcated by a v-shaped notch.

A sump system includes a catch basin and a sump pump. The catch basin is configured to receive runoff water. The catch basin has an upper end and a bottom surface. The catch basin defines a vertical chamber and a horizontal chamber. The vertical chamber extends downward in a vertical direction from the upper end to a first portion of the bottom surface. The horizontal chamber intersects the first chamber to form an intersecting region. The horizontal chamber is defined by an upper surface and a second portion the bottom surface. The horizontal chamber extends outwardly in a horizontal direction from an outer periphery of the first chamber and has a vertical dimension that extends upward from the bottom surface to the upper surface. The upper surface is positioned below the upper end. The sump pump is disposed within the catch basin.

A water drainage edging segment includes a horizontally-extending bottom portion, a vertically extending top portion, and an angled intermediate section spanning between the bottom and top portions. The bottom portion defines a plurality of longitudinally spaced bottom channels that are oriented at one or both of a perpendicular angle and an oblique angle to the longitudinal axis of the edging segment. Each of the plurality of bottom channels are raised above a lowermost plane of the bottom portion to define an open passageway from a backside of the edging segment and laterally through the edging segment. The top portion defines a longitudinally extending upper rib portion that projects rearwardly from a front plane of the top portion to define a forward offset of the front plane and an upward facing contact surface.

A water drainage edging segment includes a horizontally-extending bottom portion, a vertically extending top portion, and an angled intermediate section spanning between the bottom and top portions. The bottom portion defines a plurality of longitudinally spaced bottom channels that are oriented at one or both of a perpendicular angle and an oblique angle to the longitudinal axis of the edging segment. Each of the plurality of bottom channels are raised above a lowermost plane of the bottom portion to define an open passageway from a backside of the edging segment and laterally through the edging segment. The top portion defines a longitudinally extending upper rib portion that projects rearwardly from a front plane of the top portion to define a forward offset of the front plane and an upward facing contact surface.

Disclosed herein is a system for draining groundwater away from a substantially vertical foundation wall that extends beneath the surface of the ground, and which has an exterior surface in contact with the ground. The drainage system includes a drainage structure that extends longitudinally along an entire interior foundation wall footing. The drainage structure is fabricated from a plurality of foldable polypropylene panels that are secured to and are adjacent to the foundation footing. The drainage structure forms a drainage channel that facilitates the flow of infiltration water to a sump pump or other means for ejecting water, and extracted radon, from proximate the foundation.

A drainage device for use under the floor of a building to facilitate drainage of water along a foundation of the building under the floor. The drainage device can include a corner drainage device that is capable of assuming a number of near 90 degree shapes so that the drainage device can be easily fitted to the corner of the foundation. A bridge drainage device permits more rapid installation of the drainage devices. The bridge device can be used to bridge between two drainage devices so that it is not necessary to cut the drainage devices precisely to fit on a footing of any selected length.

A negative-side waterproof shell (W-shell) is retrofitted onto a below ground preexisting building subject to water intrusion. The W-shell includes a high density polyethylene (HDPE) membrane adhered to the building's sidewalls and floor. The HDPE membrane has a metal core (usually aluminum). The W-shell includes a concrete shell formed on an inboard side of the HDPE membrane. Typically, the W-shell's concrete typically includes rebar and supplemental vertical columns which are thicker than the W-shell. The HDPE membrane has overlapped seams at the vertical to horizontal transition regions. The core may be non-continuous, in strips, or may be ferrous or non-ferrous metals, alloys or aluminum alloys. The W-shell covers the building's interior concrete-formed structures. To seal high tide salt water intrusion, the W-shell extends above the high tide water line. Also, drain piping, leading to a sump, may be laid between the membrane and the floor.