A multi-port transition tee drain valve includes multiple ports that are positioned generally perpendicular to the body of the fitting that includes a drain valve. The drain valve includes a drain port positioned next to a valve member which can be opened to permit the draining of the multi-port transition tee drain valve and surrounding components through the drain port. The fittings on the ports and the fittings on the end(s) of the drain body can be different to permit the transition of one type or size of tubing/piping to another.

Cleanout conduit valve installations may include at least one cleanout housing having a cleanout housing interior and configured for placement in the cleanout conduit hole with the at least one cleanout conduit extending into the cleanout housing interior. A cleanout housing opening may overlie the cleanout housing interior. An openable cleanout housing door may be disposed in the cleanout housing opening. At least one cleanout conduit valve assembly may be configured to be disposed in fluid communication with the at least one cleanout conduit in the cleanout housing interior of the at least one cleanout housing. The at least one cleanout conduit valve assembly may include a valve housing configured for mounting on the at least one cleanout conduit. A valve mount may be carried by the valve housing. A valve may include a valve arm pivotally carried by the valve mount. A valve stop may extend from the valve arm. A valve body may be carried by the valve arm. The valve body may have a sealing surface. The valve may be positional between a closed valve position configured to seal the valve housing and a full open valve position configured to unseal the valve housing. The valve stop may engage the valve body in the full open valve position.

A method of using a water distribution system can include measuring a property of water in the system, the system including: a multi-port service saddle mountable on a water pipe and including main and secondary ports; and a water sensing assembly including: a housing received within the main port; a generator positioned inside the housing; a sensor coupled to the secondary port and configured to be exposed to water flow within the water pipe; and a turbine coupled to a generator shaft of the generator, the turbine movable from and between a first position and a second position, the turbine in fluid communication with the water flow within the water pipe in the first position but to be in fluid communication with the water flow within the water pipe in the second position; and moving the housing to one of the first position and the second position.

A drainage system (1) comprising: at least one water receiving unit (20) having: a water receptacle (22) for receiving water from an adjoining surface; a first neck piece (24) which can be connected to the water receptacle (22) and provided such that water can flow out of the water receiving unit (20) through an opening (26) of the first neck piece (24); and at least one water drainage unit (40) for draining the water, comprising: a pipe body (42); and a first opening (46b), provided on the pipe body (42), for receiving the water in said pipe body (42); wherein: the water drainage unit (40) can be provided and oriented under the surface such j that the opening (26) of the first neck piece (24) and the first opening (46b) of the pipe body (42) can be connected and the water flowing out of the water receiving unit (20) can flow into the water drainage unit (40). Also disclosed are drainage units and methods.

A drainage system (1) comprising: at least one water receiving unit (20) having: a water receptacle (22) for receiving water from an adjoining surface; a first neck piece (24) which can be connected to the water receptacle (22) and provided such that water can flow out of the water receiving unit (20) through an opening (26) of the first neck piece (24); and at least one water drainage unit (40) for draining the water, comprising: a pipe body (42); and a first opening (46b), provided on the pipe body (42), for receiving the water in said pipe body (42); wherein: the water drainage unit (40) can be provided and oriented under the surface such j that the opening (26) of the first neck piece (24) and the first opening (46b) of the pipe body (42) can be connected and the water flowing out of the water receiving unit (20) can flow into the water drainage unit (40). Also disclosed are drainage units and methods.

Cleanout conduit valve assemblies for a cleanout conduit may include a vertically oriented valve housing. The valve housing may include a valve inlet end configured to be disposed in fluid communication with the cleanout conduit and a valve discharge end opposite to and generally above the valve inlet end. The valve discharge end may be oriented within a valve discharge plane disposed at a discharge angle of greater than 0 degrees with respect to a horizontal plane. The valve discharge end may have an upper discharge opening side and a lower discharge opening side sloped downwardly from the upper discharge opening side. A valve body may be pivotally carried by the valve housing at the upper discharge opening side of the valve discharge end. Methods of preventing precipitation and runoff on a ground surface from entering a cleanout conduit connected to a sewer service line are also disclosed.

A catch basin comprising a circular collar with a first internal diameter, configured to receive a downwardly extending circular drain pipe. A sump for receiving downward water flow from the circular collar is integrally formed with the circular collar, the sump being shaped to include two differently shaped cylindrical portions. The shape of the sump facilitates both the ability to stack multiple units of the sump one upon another for packaging, shipping, and sale. The shape of the sump also facilitates the ability to remove an internal stub attached to the sump, to improve water flow in the remaining structure.

The present invention is directed broadly to a drainage channel support assembly 10 comprising a support member 12 adapted to support drainage channel 14, a pair of pegs 16a and 16b arranged to anchor the support member 12 to the ground, and a pair of coupling elements 18a and 18b mounted to respective of each of the pair of pegs 16a and 16b. The coupling arrangements 18a and 18b are configured where on anchoring of the support member 12 to the ground via respective of the pair of pegs 16a/b either: 1. in a first install mode, the coupling arrangement 18a contacts an upper surface of the support member 12 with the associated peg 16a penetrating the ground along substantially the full length of the peg 16a; or 2. in a second install mode, the coupling arrangement 18a couples to a fitting 22a which contacts the upper surface of the support member 12, the coupling arrangement 18a contacting a lower surface of the support member 12 for suspension of the drainage channel 14 above the ground.

A draining device, which can discharge permeated water and/or rainwater quickly, and adapt to different construction requirements is provided. The draining device may have a permeable wall body. The permeable wall body may have a plurality of ribs, where a cross section of the ribs in a first direction is wavy, and a wave amplitude of the cross section gradually changes, from a first side to a second side, in a second direction. Therefore, the ribs have alternating wave crest parts and wave trough parts at either side of the first direction. The wave crest part of one rib, among two adjacent ribs is opposite to the wave trough part of the other. The first direction intersects the second direction. The second direction is a thickness direction of the permeable wall body.

Systems and methods of installing a fixture into a material are provided. The fixture includes a body and a cover assembly that is removably coupled to the body and configured to move relative to the body once the body has been secured within the material. The cover assembly includes a movable component configured to aid removal of the cover assembly.