This invention was not made pursuant to any federally-sponsored research and/or development.
The system, device and method of the present invention relate to a device, system and method for improving the safety of residential and commercial hot water and steam boilers, primarily those burning natural gas, commonly used for heating, hot water, and other purposes, and for all other water and steam boilers using combustible liquids and fuels, such as oil and liquefied gas, as well as sewerage and drainage systems. Hot water and water heated to steam have many residential and commercial uses. Hot water and steam are used for cooking, cleaning, bathing, and space heating, to name just a few.
Natural gas has been used for hot water and heating for a very long time in the United States. When natural gas is mixed with air in the right proportions, the air of course containing oxygen necessary for burning, natural gas is a clean-burning, efficient, and safe way for hot water and heating purposes. Hot water and heat account for a large portion of the residential energy bill because, according to the U.S. Department of Energy statistics, 14% of the home energy usage is for heating water and 44% is for heating and air conditioning. Thus, the system, device, and method of the present invention have the tremendous potential to improve the safety of the water and heating systems of millions of households.
Numerous devices and systems exist to use the natural gas for hot water and heating. The devices that burn fuel to provide hot water or steam are commonly referred to as water heaters, hot water heaters, hot water tanks, boilers, steam boilers, heat exchangers, and other names known in the art. Some of these devices use electric power instead of fossil fuels, with the possibility of all or some of the electricity being provided by solar power or other renewable energy source. Indeed, a very large industry exists to manufacture, distribute, and service the boilers and steam boilers using natural gas.
The devices and systems using natural gas are constantly improved to increase their safety and efficiency. However, such improvements are usually directed as the devices and systems themselves (i.e., to prevent fires and gas explosions, which are dangerous to the life and safety of individuals using these devices, and are also dangerous to the property. However, no device or method exists to improve the safety of the boilers and steam boilers in terms of water leakage, dripping, and water and steam explosions, either one of which can flood a basement, causing massive damage to the basement and anything in it, further causing secondary damage from mold, short circuits, fires and other issued caused by flooding.
Indeed, natural gas boilers and steam boilers typically have a pressure and/or temperature sensor or sensors. The sensors are sometimes adjustable and sometimes preprogrammed to a certain limit of safe pressure and/or temperature. If the safe pressure and/or temperature is exceeded, a limit switch will typically end the operation of the boiler or heating system by shutting off the gas valve and/or the burner.
The limit stitches are used on both residential and commercial boiler and heating systems. The limit switches are essentially water temperature and/or pressure controllers, which shut off the gas valve or otherwise turn off the operation of a water or steam boiler, used for hot water or heat. A limit switch is typically an electromechanical device that consists of an actuator mechanically linked to a set of contacts. When an object comes into contact with the actuator, the device operates the contacts to make or break an electrical connection. The boiler temperature control usually has an adjustable temperature sensing for limit control to address different applications. The limit switch can be made to open on temperature rise and/or open or close on temperature fall. For example, a Single Acting Boiler Temperature Control will incorporate a high limit function that acts like an on/off switch. The high limit setting is the maximum temperature the boiler can attain. When the high limit point is reached, the switch turns off the burner. There are numerous other types of limit switches, having double limit controls, differential controls, and the like, but the system, device and method of the present invention works with all types of limit switches equally well, without regard to the actual limiting method used.
Additionally, no device of method exists to improve the safety of sewerage and water drainage systems, which have a similar problem. If left unattended, such systems may cause water and sewage spills, such as in cases of sewer backup, which not only creates a water and/or sewage spill, causing damage, but is also unsanitary and potentially dangerous because sewage and drainage water may contain dangerous and harmful bacteria and other pathogens hazardous to human health and life. Organic materials in sewage decompose quickly, creating breeding grounds for bacteria and emitting odorous gases, which can also be harmful to people. Sewage poses a serious health risk to any people and animals living in the home, and sewage backups are, therefore, very dangerous. Cleaning up a sewage backup and water in the basement can be dangerous for these reasons, and can expose people to bacterial and other infections if they are not careful, making them sick.
Ordinary back water valves that exist for sewerage and water drainage systems are designed to close if the main sewer backs up. However, if the user is unaware of the problem, the water and waste will continue to be flushed into the line, creating a flood of sewage because there is no warning or alarm. Such back water valves often fail in the closed position, leaving the sewer line blocked off even if there is no stoppage, and for this reason such valves are not permitted in many jurisdictions.
What is needed is a system, device and method that can be used in residential and commercial boiler and heating systems, improving the safety of these system by shutting them down if the pressure relief valve is leaking and notifying the owner of the problem, including in boilers and hot water heaters and sewerage and water drainage systems.
The present invention solves this problem by providing a system, device and method for disconnecting the gas valve or the burner and notifying the owner of the leak, caused by excessive pressure or temperature of the heating system or boiler, or alternatively shutting off water to stop the sewage or drainage water backup and alerting the owner of the backup of the sewerage or drainage system.
It is an object of the present invention to provide a system, device and method to improve the safety of heating systems and boilers, as well as sewerage and drainage system. The present invention (Overflow Preventer) is an inexpensive to manufacture, easy to install, commercial and residential safety device for heating systems and boilers burning natural gas and liquid/solid fuels (i.e., all combustible gases and liquids), and for sewerage and drainage system. The present invention may be used for applications of varying scope, such as a single residential boiler (small) to industrial applications such as a building or factory heating system (large), and from individual house sewerage and water drainage system to a commercial installation.
The preferred embodiment of the present invention achieves this goal with a system, device and method that includes at least one hollow pipe, with one plugged end and a fitting on the opposite end for connecting the pipe to the pressure relief valve, and at least one water-activated switch, disposed inside the hollow pipe. This water-activated switch is preferably a float switch, but it may be an air pressure switch activated when sufficient pressure builds up inside the device after the water accumulates. The pipe is preferably mounted in a substantially vertical configuration and is adopted to be filled with water from leaking pressure relief valve, so that the switch is activated when the pipe fills with water and shuts off the heating system or boiler by being wired in series with a limit switch of the heating system or boiler. Additionally, the same water-activated switch may activate the visual and/or audible alarm for the owner that there is an issue. Alternatively, there may be two separate switches disposed in the hollow pipe, one activating the alarm for the owner and one deactivating the heating system or boiler.
During the operation of a Hot Water Generator (also called a hot water boiler), a steam boiler or a hot water tank, if the pressure exceeds the rated relief pressure of the pressure relief valve (or the working pressure of the system) the spillage will enter the Overflow Preventer. As soon as the Overflow Preventer senses the spilled water (by the float switch) from a hot water boiler or hot water tank, or the condensed water from the steam exiting the pressure relief valve on a steam boiler, the Overflow Preventer shuts the Hot Water Generator down to prevent further pressure build up that may present a danger to life and/or property, and to prevent the massive water spill that will result if the system continues to run unchecked.
Also, the city water supply to the unit may be shut off by the solenoid valve in addition to shutting down the Hot Water Generator. The solenoid valve is located remotely from, but is electrically wired into the system and device of the present invention. On a steam system, a stand-alone or redundant Overflow Preventer may be configured high enough on the return line in order to stop inadvertent overfilling of the system.
The general operation of the Overflow Preventer is as follows:
The air vent allows for full water flow throughout the respective water ways in the overflow preventer and on the tapped return line on a steam system. The relay, which houses the coil, normally closed and normally open contacts and the electrical terminals for the internal factory connections are located on the printed circuit board. The junction block, on the outside of the overflow preventer, provides the terminals for the external field wiring.
This design of the preferred embodiment is simple and elegant, having a compact size and being inexpensive to manufacture and simple to install, providing maximum safety and economic benefit for a minimal investment of labor and materials. The system and device are easy to assemble, and the method is easy to follow according to the disclosure of the present application. No special skills are required, so this invention is usable by anyone. The assembly for users can be conducted at the factor assembling the heating system or boiler, or at the location the heating system or boiler is installed, at any time before or during the exploitation.
Many configurations may be used for the system, device and method of the present invention within the spirit and scope of the present invention. Although the examples and the preferred embodiments are shown primarily with natural gas boilers and heating systems, as well as with sewerage and water drainage system, the system, device and method of the present invention are equally applicable to liquid and solid fuels (combustible liquids and solids) and other application where fluid backup or overflow may be an issue. The anticipated service life of the embodiments of the present invention is at least five years.
A system, device and method to improve the safety of natural gas burning heating systems, boilers and steam boilers, and sewerage and water drainage system of the present invention will now be described by way of example with reference to the accompanying drawings in which:
Boiler pressure relief valve (commonly called blow off valve) is a safety valve that protects the heating system or a boiler from building up to much pressure and possibly blowing up. Sometimes the relief valve or blow off valve will leak. The leaks may be called by a number of reasons, two of which are excessive water pressure or excessive operating temperature, generating steam and, once again, excessive pressure on the system.
The boiler pressure typically varies from 12 psi to 18 psi (12 psi for a boiler and 15 psi for a steam boiler for example). The temperature should typically be between 160 and 180 degrees F. The pressure relief valve for a regular water boiler is set to only allow 12 psi in the boiler. If this valve fails, it will allow the pressure in the boiler to reach 30 psi or higher, causing the relief valve to leak. If the pressure goes over 30 psi and the relief valve does not leak, it may cause a very dangerous situation from overpressure, such as an exploding boiler, exploding pipes, blown off water expansion tank, or blown off relief valve (separated from the boiler). Needless to say, either of these could be hazardous to life and health of any individual in the immediate vicinity due to the explosion and hot water, and it could cause severe water damage from the leaking water.
Temperatures of the heating system or boiler that elevates above the safe operating temperature can also cause the buildup of steam and pressure and an explosion or water leak. The standard recommendation when a pressure relief valve is leaking is to turn off the boiler and to call a specialist to address the problem. However, the owner of the heating system of boiler must be aware of the problem and must be present to do so. If the owner does not see or hear the leaking pressure relief valve somewhere in the basement, or if the owner is simply not home when this happens, the results can be disastrous. The system, device and method of the present invention address these issues of notifying the owner of the problem, as well as improve the general safety of the heating and boiler systems.
Pressure relief valves come in a number of standard sizes known in the art, such as ¾″ and ½″ valves. The system, device, and method of the present invention can be adopted by those skilled in the art to accommodate all sizes of the pressure relief valves. The pressure relief valves are typically made from bronze, cast iron, stainless steel, and other corrosion-resistant metals that can withstand the specified pressure. The pressure relief valves usually have threading on the ends so that additional pipes may be connected by cooperating male-female connectors.
A novel system, device and method to improve the safety of natural gas burning boilers and steam boilers are provided. With reference to
There is at least one float switch 150 disposed, positioned or mounted inside the hollow pipe 120. The height of the mounting of the float switch 150 inside the hollow pipe 120 determines how early the switch is activated. Although the float switch 150 may be permanently or semi-permanently mounted, it is preferably mounted in a semi-permanent (detachable) way, so that the float switch 150 may be easily replaced. Additionally, the position of the float switch 150 inside the hollow pipe 120 may be adjustable, so that the user or the installer may vary how soon the switch is activated by selectively installing the float switch 150 higher or lower inside the hollow pipe 120.
The float switch 150 is electrically connected to one of the limit switches of the boiler, as illustrated in
In operation, the open top end 124 is threaded into the pressure relief valve 5 as illustrated in
In another modification of this preferred embodiment illustrated in
Another preferred embodiment of the present invention is shown in
The float switches 150 and 160 are connected to the limit switch and/or the alarm module 10 by electrical wiring 155 and 165 respectively, which passes through apertures 157 and 167 in the hollow pipe 120 respectively and come out of the aperture 117 in the housing 110. The wiring 155 and 165 is connected to the terminal block 180, which uses terminal block screws 190 to secure, connect and disconnect the wiring. The electrical connections to and from the terminal block 180 are illustrated in
The entire electrical circuit, including limit switch, float switch, alarm, and water valve shut off is illustrated in
The housing 110 is connected to a cap 80, which may be made from the same or a different material than the housing 110 a locknut 100, having a washer 90 between the locknut 100 and the cap 80. The locknut 100 is preferably a ¾″ diameter brass, and the washer 90 is preferably rubber, but other suitable materials may be used. the cap is preferably the same diameter and the housing 110 (i.e., 1½″), The cap 80 is connected to an in-line arm of the threaded Tee 60 by the means of a threaded close nipple 70, which is preferably ¾″ diameter brass. The threaded Tee 60 is preferably a ¾″ diameter CPVC, and the transverse arm of the treaded Tee 60 it is connected to the transverse arm of another threaded Tee 40 by a threaded close nipple 50, which is also preferably ¾″ diameter brass. The threaded Tee 40 is also preferably a ¾″ diameter CPVC. There is an alarm module housing 20 connected to the threaded Tee 40 by the threaded bottom end 22 of the alarm module housing 20. The alarm module 10 is held in place in the alarm module housing 20 by the set screw 30. The alarm module 10 is electrically connected to one or more of the float switches 150 and 160, and the alarm module contains a light source, such as a lamp, LED, or strobe light 14, and/or a sound transducer 16 such as a speaker, piezo buzzer, or another type of audible alarm. The alarm module may also contain electrical, electronic, and/or communications circuitry 18 to communicate with the owner of the operator of the boiler that the water is leaking from the pressure relief valve when one or more of the float switches 150 and 160 are activated. The communications may be by connecting into the home network or Wi-Fi wireless signal, or by initiating a landline or cellular telephone call, email or text message.
The terminal block 180 is preferably attached to the housing 110 as illustrated in
The particular embodiment illustrated in
For occasions when various codes, such as city plumbing codes or local ordinances, do not permit attaching the system and device of the present invention directly to the pressure relief valve (for example, when it is prohibited to restrict or obstruct the water flow from the pressure relief valve), several other embodiments of the present invention are provided.
One such embodiment is illustrated in
Yet another embodiment for when the system and device of the present invention cannot be connected directly to the pressure relief valve is illustrated in
There is at least one float switch 150 disposed inside the hollow pipe 120, but preferably there is another float switch 160 as illustrated in
The float switch 150 is electrically connected to one of the limit switches of the boiler, as illustrated in
The container 250 preferably has a bottom part 252, which is a regular container of any shape, preferably cylindrical, and a top part 254 that connects or attaches to the bottom part 252. The top part 254 has an attachment means 258 for the threaded top end 124 of the hollow pipe 120, so that the top part 254 may be taken off or disconnected from the bottom part 252, the top end 124 connected to the top part 254 by the attachment means 258, which are preferably reciprocal threading, and the top part 254 is then placed back onto or attached to the bottom part 252 so that the hollow pipe 120 is substantially vertical and disposed inside the container 250. The container 250 may be freestanding or it may be attached to the side wall of the boiler 15 under the pressure relief valve 5. Likewise, the hollow pipe 120 may be attached to or secured in the container 250 by using methods other than the treaded top end 124.
In operation, the container 250 is placed or mounted under the pressure relief valve 5, and the container 250 will collect the water leaking or dripping from the pressure relief valve 5. The water will fill up the container 250 and the hollow pipe 120 through the open bottom end 122 and eventually reach the level of the float switch 150, which will activate and open or close the electrical circuit of the limit switch as illustrated in
The diameter of the hollow pipe 120 is preferably ¾″ or 1″, but other sizes may be utilized depending on the desired application. The preferred length of the hollow pipe 120 is between 4″ and 6″, but the length may be varied depending on the application, the sizes of the float switches and the desired speed with which the heating system or boiler is shut off. In yet another improvement of the system, device, and method of the present invention, a warning light and/or sound is used to alert the owners to the problem with the pressure relief valve, contemporaneously with shutting off the boiler or the heating system. In this embodiment, a light, preferably an LED or fiber optic light, and/or a sound emitter (such as a speaker or piezo- or electric buzzer) are built into the device 10 of the present invention, together with control electronics 18 and wiring 168 to activate them, and an interior or exterior power source to power them, which is preferably a replaceable battery.
The pressure relief valve is typically mounted on top of the boiler tank. The hollow pipe 120 is mounted into the pressure relief valve 5 with a fitting on one end of the hollow pipe 120 or a threaded top end 124 as illustrated in
The hollow pipe 120 is preferably made of copper, where the cross-section of the hollow pipe 120 is preferably substantially the same along its entire length. However, the hollow pipe 120 may be made from stainless steel, cast iron, brass, and other materials commonly used for gas or water pipes.
With reference to
The bottom end 122 of the hollow pipe 120 is capped with a cap 130 to allow the accumulation of water inside the hollow pipe 120. There may also be a downward-pointed pipe 420 attached to the hollow pipe 120 above the top end 124 to channel excess water away from the device. An additional downward-pointed pipe 430 may be attached to the hollow pipe 120 below the top end 124 to allow the runoff of excess water and/or air from the housing (hollow pipe) 120 itself. Thus, the downward-pointed pipe 430 essentially serves as a water and/or air vent, which can be automatic. Using one or both pipes ensures that no excess pressure builds inside the hollow pipe 120, but still enables sufficient water amounts to be collected for the proper operation of the device.
There is at least one float switch 150 disposed, positioned or mounted inside the hollow pipe 120. The height of the mounting of the float switch 150 inside the hollow pipe 120 determines how early the switch is activated. Although the float switch 150 may be permanently or semi-permanently mounted, it is preferably mounted in a semi-permanent (detachable) way, preferably to the connector block 410, so that the float switch 150 may be easily replaced. The connector block 410 has one or more apertures 412 cooperating in size and positioning with the respective one or more apertures 416 in the hollow pipe 120. For removable mounting, the apertures 412 and 416 are aligned, and the connector block 410 holding the float switch 150 is secured to the hollow pipe 120 by screws 419 of appropriate size. The connector block 410 also preferably has an aperture 415 aligned with the aperture in the hollow pipe 417, through which apertures wiring from the float switch 150 is connected to the terminal block 180. Additionally, the position of the float switch 150 inside the hollow pipe 120 may be adjustable, so that the user or the installer may vary how soon the switch is activated by selectively installing the float switch 150 higher or lower inside the hollow pipe 120. The bracket 210 attached to the hollow pipe 120 secures the device to the wall of a boiler.
The float switch 150 is electrically connected to one of the limit switches of the boiler, as illustrated in
In operation, the device should be connected to or positioned under the pressure relief valve 5 (with a funnel 200) the so that the hollow pipe 120 is substantially vertical. The water leaking or dripping from the pressure relief valve 5 will accumulated in the hollow pipe 120 and eventually reach the level of the float switch 150, which will activate and open or close the electrical circuit of the limit switch, and thus will shut off the boiler 15 when the water level reaches the float switch 150 and activates it. Thus, the user or the installer may vary the amount of water that leaks or drips from the pressure relief valve 5 before the float switch 150 is activated and the boiler is shut off.
As illustrated in
The relay can be a single pole single throw or a double pole double throw relay, and the preferred embodiment uses the double pole double throw relay 390 (a single coil-double contact points relay), the printed circuit board and contacts of which are illustrated in
Specifically with reference to
With reference to
The terminal block 180 in the Overflow Preventer is wired to the hot water boiler 15 limits through the electrical wiring 155, is wired to the hot and neutral 24 V power, and is wired to the solenoid valve 370 by the electric wiring 175. The terminal screws 190 on the terminal block 180 are used to connect the electrical wiring. The solenoid valve 370 is also connected to the manual water shut off 372 on the city water in pipe 8, a backflow preventer 376 and a pressure regulating valve 374. The size and length of the bracket 210 are selected so as to enable the system and device of the present invention 5 to be positioned substantially under the water runoff from the pressure relief valve 7. In operation, the funnel 200 collects the water runoff and directs it into the hollow pipe 120, where the water activates a float switch or switches, shutting off the solenoid valve 370.
The operation of the system and device 5 of the present invention with a steam boiler is similar. With reference to
The terminal block 180 in the Over flow Preventer is wired to the steam boiler 25 limits through the electrical wiring 155, is wired to the hot and neutral 24 V power, and is wired to the solenoid valve 370 by the electric wiring 175. The terminal screws 190 on the terminal block 180 are used to connect the electrical wiring. The solenoid valve 370 is also connected to the manual water shut off 372 on the city water in pipe 8 and a backflow preventer 376. The size and length of the bracket 210 are selected so as to enable the system and device of the present invention 5 to be positioned substantially under the water runoff from the pressure relief valve 7. In operation, the funnel 200 collects the condensed water from the steam exiting the pressure relief valve 7 on a steam boiler 25 and directs it into the hollow pipe 120, where the water activates a float switch or switches, shutting off the solenoid valve 370.
The terminal block 180 in the Over flow Preventer is wired to the hot water tank 35 limits through the electrical wiring 155, is wired to the hot and neutral 24 V power, and is wired to the solenoid valve 370 by the electric wiring 175. The terminal screws 190 on the terminal block 180 are used to connect the electrical wiring. The solenoid valve 370 is also connected to the manual water shut off 372 on the city water in pipe 8. The size and length of the bracket 210 are selected so as to enable the system and device of the present invention 5 to be positioned substantially under the water runoff from the pressure relief valve 7. In operation, the funnel 200 collects the water runoff and directs it into the hollow pipe 120, where the water activates a float switch or switches, shutting off the solenoid valve 370 and/or the burner assembly 17.
A secondary or standalone Overflow Preventer may be configured on a steam boiler return. With reference to
The terminal block 180 in the Over flow Preventer is wired to the steam boiler 25 limits through the electrical wiring 155, is wired to the hot and neutral 24 V power, and is wired to the solenoid valve 370 by the electric wiring 175. The terminal screws 190 on the terminal block 180 are used to connect the electrical wiring. The solenoid valve 370 is also connected to the manual water shut off 372 and a backflow preventer 376. In operation, the hollow pipe 120 collects the condensed water from the steam exiting condensate return pipe 13 on the steam boiler 25, where (in the hollow pipe 120) the water activates a float switch or switches, shutting off the solenoid valve 370.
With reference to
Specifically with reference to
Although the preferred and alternative embodiments previously described use float switches to illustrate the operation of the system and device of the present invention, all of the embodiments may be assembled and used with an air pressure switch instead of a float switch. For example, with reference to
Although not necessary to the operation of the system and device of the present invention, to improve the safety of heating systems, boilers and steam boilers burning natural gas, and sewer systems, the system and device may include electrical and/or electronic control and/or monitoring circuits and mechanisms, monitoring the water flow through the pipe, using various optical, electrical, mechanical, and other sensors positions in or about the system and device.
Two other alternative embodiments of the present invention are illustrated in
With reference to
For example, the nipple 134 may have male thread on both ends and the cleanout plug 135 and the cap 130 reciprocal female threads to enable a secure connection as illustrated in
The cleanout plug 135 is cooperatively sized to fit into a cleanout aperture that is otherwise plugged by a common cleanout plug, also called a sewer cleanout cap. Such plugs or caps are typically installed in the street-side and house-side cleanout apertures of the main sewer trap. The size of such plugs or caps is typically 4 inches in diameter, but they can also be 3 inches or 6 inches, so cleanout plugs 135 may be sized appropriately and threaded as needed to be mounted into the cleanout aperture. The envisioned method of installation of this embodiment of the device and system of the present invention is into the house-side cleanout aperture, but the device and system of the present invention may also be installed on the street side.
Threading is the preferred installation method, by the cleanout plugs 135 may also be installed using snaps, latches, rails, friction installations, Luer Lock connection or another connection method known in the art. The nipple 134 is connected to the female adapter 130 at its bottom end 132 by reciprocal threading or other methods known in the art (i.e., the nipple 134 may be a common NPT nipple with male threading on both ends: one end is connected into the bottom end 132 of the cap 130 and the other end into the cleanout plug 135. Alternatively, the female adapter 130 may be integrally formed with the nipple 134 as a one-piece part using suitable materials such as PVC, copper, brass, steel, or other suitable materials, with the PVC being the preferred material due to the ease with which such a female adapter 130 may be formed from PVC versus various metals.
The female adapter 130 is preferably connected to the bottom end 112 of the housing 110 by the close nipple 140, but it may be connected to the bottom end 112 via reciprocal threading as illustrated in
The float switches 150 and 160 are connected to the water valve and/or the optional alarm module 10 by electrical wiring 155 and 165 respectively, which passes through apertures 157 and 167 in the hollow pipe 120 respectively and come out of the aperture 117 in the housing 110. The wiring 155 and 165 is connected to the terminal block 180, which uses terminal block screws 190 to secure, connect and disconnect the wiring. The electrical connections to and from the terminal block 180 are illustrated in
The entire electrical circuit, including float switch, alarm, and water valve shut off is illustrated in
The housing 110 is connected to a cap 80, which may be made from the same or a different material than the housing 110 a locknut 100, having a washer 90 between the locknut 100 and the cap 80. The locknut 100 is preferably a ¾″ diameter brass, and the washer 90 is preferably rubber, but other suitable materials may be used. the cap is preferably the same diameter and the housing 110 (i.e., 1½″), The cap 80 is connected to the downward in-line arm of the threaded Tee 60 by the means of a threaded close nipple 70, which is preferably ¾″ diameter brass. The threaded Tee 60 is preferably a ¾″ diameter CPVC, and the transverse arm of the treaded Tee 60 it is connected to the transverse arm of another threaded Tee 40 by a threaded close nipple 50, which is also preferably ¾″ diameter brass. The threaded Tee 40 is also preferably a ¾″ diameter CPVC. There is an alarm module housing 20 connected to the threaded Tee 40 by the threaded bottom end 22 of the alarm module housing 20. The alarm module 10 is held in place in the alarm module housing 20 by the set screw 30. The alarm module 10 is electrically connected to one or more of the float switches 150 and 160, and the alarm module contains a light source, such as a lamp, LED, or strobe light 14, and/or a sound transducer 16 such as a speaker, piezo buzzer, or another type of audible alarm. The alarm module may also contain electrical, electronic, and/or communications circuitry 18 to communicate with the owner of the operator of the boiler that the water is leaking from the pressure relief valve when one or more of the float switches 150 and 160 are activated. The communications may be by connecting into the home network or Wi-Fi wireless signal, or by initiating a landline or cellular telephone call, email or text message.
The terminal block 180 is preferably attached to the housing 110 as illustrated in
The transverse arms of the threaded Tee 40 and the threaded Tee 60 are connected, preferably via a threaded close nipple 50. The upward in-line arm of the threaded Tee 40 supports the alarm module housing 20 and the alarm module 10, held by the set screw 30, on a separate “branch” of the system and device, so they are not affected by the water or sewage flooding the housing 110 upwards from the sewerage or water drainage system, where the fluid accumulates because the female adapter 130 caps the housing 110. The water fills the housing 110 and the hollow pipe 120 through the plug 135 and the nipple 134, and triggers the float switches 150 and 160 illustrated in
The wiring 157 and 167, passing through the aperture 117 in the housing 110 enables the float switches 150 and 160 to open or close the electrical circuits of the water valve (or two water valves for local and main lines) or perform other functions, such as activating a visual or sound alarm, or by initiating a landline or cellular telephone call, email or text message to the owner, possibly over the Wi-Fi home network.
The alarm housing 20 and the alarm module 10 are on a separate branch, parallel to the main device, so they do not take up any vertical space, which is useful when installing the overflow preventer in a pit below floor level with limited vertical clearance. In this configuration, the housing 110 with the hollow pipe 120 and the float switches 150 and 160 would rise above the line, mounted over the cleanout plug.
The overflow preventer for sewerage and water drainage systems typically connects to the sewer trap plug or cleanout plug as illustrated in
Yes another alternative embodiment of the Overflow Preventer for sewerage and drainage systems is illustrated in
The bottom end 122 of the hollow pipe 120 is capped with a cap 130 to allow the accumulation of water inside the hollow pipe 120. The cap 130 has a bottom end 132 with a hollow nipple 134 in fluid communication with the housing 110. The nipple 134 is preferably directly connected to, and is in fluid communication with, the cleanout plug 135. The cleanout plug 135 has a longitudinal bore into which the nipple 134 is connected, preferably by reciprocating threading.
As described, the nipple 134 may have male thread on both ends and the cleanout plug 135 and the cap 130 reciprocal female threads to enable a secure connection as illustrated in
The cleanout plug 135 is cooperatively sized to fit into a cleanout aperture that is otherwise plugged by a common cleanout plug, also called a sewer cleanout cap. The size of such plugs or caps is typically 4 inches in diameter, but they can also be 3 inches or 6 inches, so cleanout plugs 135 may be sized appropriately. The nipple 134 is connected to the cap 130 at its bottom end 132 by reciprocal threading or other methods known in the art (i.e., the nipple 134 may be a common NPT nipple with male threading on both ends: one end is connected into the bottom end 132 and the other end into the cleanout plug 135. Alternatively, the cap 130 may be integrally formed with the nipple 134 as a one-piece part using suitable materials such as PVC, copper, brass, steel, or other suitable materials, with the PVC being the preferred material due to the ease with which such a cap 130 may be formed from PVC versus various metals.
There may also be a downward-pointed pipe 420 attached to the hollow pipe 120 above the top end 124 to channel excess fluid and/or air away from the device after it accumulates in the housing (hollow pipe) 120. The pipe 420 may be attached directly to the device or it may be attached by a diameter adapter 425 as illustrated in
There is at least one float switch 150 disposed, positioned or mounted inside the hollow pipe 120. The height of the mounting of the float switch 150 inside the hollow pipe 120 determines how early the switch is activated. Although the float switch 150 may be permanently or semi-permanently mounted, it is preferably mounted in a semi-permanent (detachable) way, preferably to the connector block 410, so that the float switch 150 may be easily replaced. The connector block 410 has one or more apertures 412 cooperating in size and positioning with the respective one or more apertures 416 in the hollow pipe 120. For removable mounting, the apertures 412 and 416 are aligned, and the connector block 410 holding the float switch 150 is secured to the hollow pipe 120 by screws 419 of appropriate size. The connector block 410 also preferably has an aperture 415 aligned with the aperture in the hollow pipe 417, through which apertures wiring from the float switch 150 is connected to the terminal block 180. Additionally, the position of the float switch 150 inside the hollow pipe 120 may be adjustable, so that the user or the installer may vary how soon the switch is activated by selectively installing the float switch 150 higher or lower inside the hollow pipe 120.
The float switch 150 is electrically connected to one or more valves of the sewerage or drainage system, such as by water-resistant or waterproof electrical wiring 155 that passes through apertures 415 in the connector block 410 and 417 in the hollow pipe 120 to connect to the terminal block 180 and from that to reach the valves. It should be noted that the end of the runoff pipe 420 should be positioned above the float switch 150 to ensure that the water does not leak out or drip before reaching the bottom end 132 of the cap 130, as illustrated in
As illustrated in
In operation of the sewerage and drainage overflow preventer, an alarm via the alarm module 10 is activated once the water reaches an unsafe level, causing the hollow pipe 120 of the device to fill with fluid (i.e., water or sewage) from the cleanout aperture and through the cleanout plug 135 and nipple 134. If the lever rises, the device send a message to shut off the main water supply so that the backup is not made worse by use of the showers, toilets, sinks, washing machines, or dishwashers. It should be noted that the order of these functions is interchangeable as desired (i.e., the alarm may be activated first and the water shut off second as the fluid level rises, or the water may be shut off first and the alarm activated second as the fluid level rises.
In an alternative embodiment, the system and device may include a controller or a programmable controller to further improve the efficiency of the system and device of the present invention. Such a controller may include a number of programs and/or settings that take into consideration the communications and warnings/alarms to the operator or owner via the alarm module or other communication means such as telephone or Wi-Fi. The controller may be an independent computer, a chip-based controller, or a different controller known in the art.
These configurations will enable the system and device disclosed in the specification of the present invention to improve the safety of the heating systems and boilers in any gas-burning system or device, as well as the safety of the sewerage and drainage systems.
Anyone can use the system and device of the present invention to improve the safety of boilers and steam boilers, as well as sewerage and drainage systems, providing additional safety, cost savings, and other benefits of safer, more efficient operation. The dimensioning and sizing of the system and device of the present invention to improve the safety of boilers and steam boilers burning natural gas (i.e., the sizing and shapes of the pipes, fittings, threading, and housings), as well as sewerage and drainage systems, may be easily determined by those skilled in the art, but the applicant envisions that the system and device may be made with varying sizes, height/length, width/diameter, and other parameters.
While the system and device to improve the safety of boilers and steam boilers burning natural gas, as well as sewerage and drainage systems, of the present invention have been shown and described in accordance with the preferred and practical embodiments thereof, it is recognized that departures from the instant disclosure are contemplated within the spirit and scope of the present invention. Therefore, the true scope of the invention should not be limited by the abovementioned description of the preferred embodiments since other modifications may become apparent to those skilled in the art upon a study of the drawings, description, explanations, and specifications herein. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the principles described herein can be applied to other embodiments without departing from the spirit or scope of the invention and the subject matter of the present invention.
Number | Name | Date | Kind |
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5920265 | Johnson, Jr. | Jul 1999 | A |
20110320140 | Butler | Dec 2011 | A1 |
20160289948 | Rasmus | Oct 2016 | A1 |
20180089981 | Walbert | Mar 2018 | A1 |
Number | Date | Country | |
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20220170647 A1 | Jun 2022 | US |
Number | Date | Country | |
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Parent | 16032116 | Jul 2018 | US |
Child | 17207630 | US | |
Parent | 15271061 | Sep 2016 | US |
Child | 16032116 | US |
Number | Date | Country | |
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Parent | 17207630 | Mar 2021 | US |
Child | 17670564 | US |