초록 ▼

Embodiments disclosed herein provide systems and methods for an in-ground sprinkler to controller a liquid flow rate through a chamber, while reducing or eliminating leakage. Embodiments may utilize a flat, external surface that is configured to be flush with a ground surface to control the liquid f

Embodiments disclosed herein provide systems and methods for an in-ground sprinkler to controller a liquid flow rate through a chamber, while reducing or eliminating leakage. Embodiments may utilize a flat, external surface that is configured to be flush with a ground surface to control the liquid flow rate through the in-ground sprinkler. In embodiments, a permanent magnet may be positioned on the flat, external surface to control an internal patch system. Responsive to the permanent magnet controlling the internal patch, liquid flowing through the chamber may be controlled.

대표청구항 ▼

1. A non-invasive in-ground sprinkler system comprising: a plurality of chambers configured to hold a liquid;each of the plurality of chambers including; an inlet port configured to feed the liquid into the chamber;outlet port configured to receive the liquid from the chamber, the outlet port includ

1. A non-invasive in-ground sprinkler system comprising: a plurality of chambers configured to hold a liquid;each of the plurality of chambers including; an inlet port configured to feed the liquid into the chamber;outlet port configured to receive the liquid from the chamber, the outlet port including a sealing surface disposed internally within the chamber;a fulcrum;a shaft extending across the fulcrum;a metal element coupled to a first end of the shaft and positioned above the outlet port;an internal patch system coupled to a second end of the shaft configured to be disposed within the chamber, the internal patch system including a patch being configured to cover the sealing surface; anda removable magnet configured to be disposed on a top surface of the plurality of chambers, the top surface of the plurality of chambers being positioned planar with a ground surface, the removable magnet being configured to control a flow rate of the liquid through the plurality of chambers, and the removable magnet being configured to move the patch from a first position covering the sealing surface to a second position away from the sealing surface based on a placement location of the removable magnet on the top surface of the plurality of chambers, wherein the removable magnet is configured to be removed from the top surface of the plurality of chambers while the non-invasive in-ground sprinkler system is operating. 2. The in-ground sprinkler system of claim 1, wherein the chamber includes:a first sidewall, wherein the inlet port is positioned on the first sidewall, and the first sidewall is positioned adjacent to the ground surface and below the top surface;a second sidewall, wherein the outlet port is positioned on the second sidewall, the second sidewall is positioned adjacent to the ground surface and below the top surface, and the first sidewall is positioned on an opposite side of the chamber as the second sidewall. 3. The in-ground sprinkler system of claim 1, wherein the internal patch system comprises: the metal element configured to be moved responsive to the placement of the removable magnet on the top surface of the chamber, wherein the metal element is positioned above the inlet port when in the first position and the second position;wherein a movement of the patch counters a movement of the metal element;the shaft configured to couple the metal element and the patch, wherein the shaft extends in a direction perpendicular to the ground surface;the fulcrum configured to be coupled to a sidewall of the chamber and the shaft, wherein the fulcrum is configured to provide a pivot point for the shaft within the chamber, wherein the metal element is positioned above the fulcrum when in the first position and the second position, and the patch is positioned below the fulcrum when in the first position and the second position. 4. The in-ground sprinkler system of claim 3, wherein the patch is configured to move in a direction substantially in parallel to the top surface of the chamber. 5. The in-ground sprinkler system of claim 1, wherein the top surface of the chamber is configured to be flush with the ground surface, wherein the top surface extends from a first side of the chamber to a second side of the chamber and does not include depressions or indentations. 6. A non-invasive in-ground sprinkler system comprising: a plurality of chambers configured to hold a liquid, the plurality of chambers including a first sidewall and a second sidewall, the first sidewall and the second sidewall are positioned adjacent to a ground surface and below a top surface of the plurality of chambers being; the top surface of the plurality of chambers being positioned flush with the ground surface, wherein the top surface extends from a first sidewall of a first of the plurality of chambers to a second sidewall of the first of the plurality of chambers;each of the plurality of chambers including;an inlet port configured to feed the liquid into the chamber, wherein the inlet port is positioned on the first sidewall, and;outlet port configured to receive the liquid from the chamber, the outlet port including a sealing surface disposed internally within the chamber, wherein the outlet port is positioned on the second sidewall, and;an internal patch system configured to be disposed within the plurality of chambers, the internal patch system including a metal element configured to be moved responsive to the placement of a removable magnet on the top surface of the plurality of chambers, wherein the metal element is positioned above the inlet port when in a first position and a second position, a patch being configured to cover the sealing surface, a shaft configured to couple the metal element and the patch, and a fulcrum configured to be coupled to a sidewall of the plurality of chambers and the shaft, the fulcrum being positioned below the inlet port and above the outlet port; wherein the fulcrum is configured to provide a pivot point for the shaft within the plurality of chambers, the shaft extending across the fulcrum, wherein the metal element is positioned above the fulcrum when in the first position and the second position, and the patch is positioned below the fulcrum when in the first position and the second position, wherein a movement of the patch counters a movement of the metal element, wherein the metal element is coupled to a first end of the shaft and positioned above the outlet port, and the internal patch system is coupled to a second end of the shaft; andthe removable magnet configured to be disposed on the top surface of the plurality of chambers, the top surface of the plurality of chambers being positioned planar with the ground surface, the removable magnet being configured to control a flow rate of the liquid through the plurality of chambers, and the removable magnet being configured to move the patch from the first position covering the sealing surface to the second position away from the sealing surface based on a placement location of the removable magnet on the top surface of the plurality of chambers, wherein the patch is positioned below the inlet port when in the first position and the second position, wherein the removable magnet is configured to be removed from the top surface of the plurality of chambers while the non-invasive in-ground sprinkler system is operating.