BR102014008516A2 - INTEGRATED CLEAN WATER RECOVERY SYSTEM AND HEAT WATER PIPES THERMAL ENERGY - Google Patents

Abstract

INTEGRATED SYSTEM OF RECOVERY OF CLEAN WATER AND THERMAL ENERGY FROM HEATED WATER PIPES. This patent aims to recover water and thermal energy lost from central heating water pipes. It belongs to the technical field of the thermal energy conservation and water reuse sector in water pipes for fixed buildings. They are reservoirs that are inserted in the water supply flow, having an impeller for height below the maximum level of the reservoir, with the remaining space destined for the reintroduction of water. For water recovery, pipelines capture the water in regions close to their place of use and take it to these reservoirs where they will be introduced into the unheated water path. For the recovery of thermal energy, pipelines carry heated water to reservoirs that are upstream of the central heating system. In order to avoid the mixing of water of different temperatures between the pipes, other reservoirs were designed that are located in the path of the diversion ducts in order to accumulate water so as not to pass into unheated water pipes and to recover their thermal energy.

Description

DESCRIPTIVE REPORT INTEGRATED PATENT FOR INVENTING INTEGRATED CLEAN WATER RECOVERY AND HEATING WATER PIPES ”.

1 The present invention aims to save clean water and lost thermal energy in central heating systems, especially those powered by solar, gas, oil and electric. He belongs to the technical field of the thermal energy conservation and water reuse sector in water pipes of fixed dwellings and buildings. The invention consists of an integrated set of pipelines, reservoirs and flow switches that store water and thermal energy by properly conducting water through pre-established piping circuits. Its differential is the simplicity and no need for water pumps that use energy and increase the complexity and cost of installations.

2 In homes and buildings with central heating systems, there are usually two plumbing systems, one conducting unheated water and the other conducting heated water. Since these pipes drain into outlets such as taps and showers where water mixes from both systems to achieve the ideal temperature.

3 In central water heating systems, a situation occurs where considerable waste of water occurs. In piping conducting heated water, the flow of water is not constant, and the flow only occurs when heated water is requested. In the rest phase, when heated water is not required, there is no flow of water, and the water in the pipeline cools. When heated water is required, the cooled water in the pipes must be disposed of so that the heated water can reach the taps or showers. As heated water is used several times during the day, considerable volume of water is wasted.

4 Still in central water heating systems, there is another situation where waste of thermal energy occurs this time. In pipelines conducting heated water, the flow of water is not constant, and the temperature of the water that is stopped in the heated water pipelines decreases, losing thermal energy.

The use of thermal insulating material in hot water pipes is already known to reduce the loss of thermal energy, however, this measure is not efficient due to the insufficient insulating capacity of materials in narrow pipes, and the fact that insulating materials are very expensive to date.

6 Some people keep this cold water in containers. However, this procedure has the disadvantage that it is not practically available for everyday use. Even if one could conceive the placement of faucets in these containers, the use would still not be easy, as it would have to add one more outlet to the daily use which would be redundant, and would also require more space in sinks, besides that. flow would not be constant as it would depend on the need for the container to be always full. This arrangement does not allow it to be an automatic system whereby the water to be reused exits in the same everyday devices as in the same taps and showers that are normally used on a daily basis.

7 Even if alternative plumbing systems are designed to bring cooled or still heated water to other regions that can be reused, this requires the addition of an entire additional water outlet, such as more taps or showers, which would cause device redundancy. water outlet. 8 Other projects have systems that reintroduce previously used or rainwater, known as reuse water, but this water is not fully cleaned and only used in restricted areas such as sidewalk washing and garden irrigation.

For the sake of clarity, water will be described in this text and the claims in three situations: "Unheated water" from water pipes that do not receive water from the central heating system. "Heated water" from the water ducts receiving central heating water and the water at a high temperature. "Chilled water", which is water coming from the water ducts receiving central heating water and the water being at a low temperature due to the lowering of water temperature in the pipelines. Importantly, "chilled water" will also refer, in this report and the claims, to the flow of unheated water that can go to the heated water pipes by the thermal recovery system proposed in this invention. The same name has been retained because it exhibits exactly the same behavior and mix in the same space and way, this procedure is essential to facilitate understanding of the invention and does not compromise the meaning of the sentences.

Patent application Pl 1103718-0 A is known which relates to

a water saving system based on the need not to discard chilled water from the heated water pipes as it proposes hot water circulation in a cycle from the heated water reservoir to the hot water point coupled to a return by another pipeline running a water pump-driven water circulation that keeps the water always heated, thus avoiding the need for water disposal as there is no water cooling. This patent has the problem of not avoiding thermal energy loss while requiring water pump energy expenditure.

US Patent Deposit 7,490,373 B1 discloses a reservoir coupled to the shower pipe which receives a first volume of water at low temperature. The return is made by a venturi tube system during the bath. This system runs the risk of not promoting full water return.

Patent application Pl 0705556 refers to a water diversion in the chilled water pipeline path towards an additional reservoir. However, this patent application utilizes a water pump to return diverted water to the system's normal water consumption line. Also, it does not engage heat recapture system.

13 These proposals do not foresee difficulties intrinsic to a water circulation system. An example is the problem of accidentally passing heated water to the unheated water piping system which undermines the necessary difference between the water temperature of the hot water piping and the water temperature of the unheated water piping. required for optimal mixing of heated and unheated water to produce a suitable final temperature.

14 In view of these problems and the purpose of overcoming them, the INTEGRATED CLEAN WATER RECOVERY SYSTEM AND HEAT WATER HEAT RECOVERY SYSTEM comprised of an integrated set and composed of COOLED WATER REINTRODUCTION RESERVOIR, DUTY FLOWERS CONTROLLED, HEAT RECOVERY RESERVOIR and MINIMUM HOT WATER PASSAGE RESERVOIR AND LOSS OF THERMAL POWER. The solution for reclaiming chilled water is designed to provide a means for capturing chilled water from pipelines that conduct heated water in regions near their use as a heated water inlet for taps and showers and reintroduce that water for use in unheated water pipes without the need for pumping water.

16 The solution for recovering lost thermal energy in cooling water in the pipelines has been developed to return the piped heated water to a reservoir that will replenish the central heating system. The whole system is fully functional without the use of water pump.

The structures below represent the main components of the system.

18 COLD WATER REINTRODUCTION RESERVOIR is designed to reintroduce the cooled water from heated water pipes into unheated water pipes. Programmed to be placed in the unheated water stream by being positioned lower than the main unheated water tank and the heated water tank, and higher than the water use points. The reservoir has water inlet from the normal unheated waterway, inlet with regulating mechanism that prevents water from entering when the water level inside the reservoir is above the programmed level and this programmed level purposely placed below capacity. total reservoir so that it allows to reserve remaining space to receive additional water drawn from points near the heated water use site, resulting in a collection of water that is continuously available to unheated water use sites. In a complete system in which the thermal recovery system operates fully, this COLD WATER REINTRODUCTION RESERVOIR can also receive, in addition to the cooled water from heated water pipes, unheated water that can go to the water pipes heated by the recovery system. proposed in this invention.

19 THE HEAT RECOVERY RESERVOIR is inserted below and downstream of the main water reservoir or other source, a reservoir that has a water inlet with regulating mechanism that prevents water from coming in from the main reservoir or other source when The water inside the reservoir is above the programmed level, and this programmed level below the total reservoir capacity allows to reserve space to receive additional water from the reflux of the heated water pipes to be reused in the normal flow of heated water. water to the traditional heated water reservoir. This THERMAL ENERGY RECOVERY RESERVOIR has thermal insulating walls for better temperature preservation, and is located above and upstream of the main heated water reservoir. The use of a fishing float is intended to capture water from the surface of the reservoir.

CONTROLLED FLOW DIVIDERS provide key-controlled pathway to capture chilled water from heated water pipes at near points of use for storage in COLD WATER REINTRODUCTION RESERVOIRS. These same ducts also allow the creation of a new water circuit so that the heated water housed in the heated water pipes goes to the THERMAL LOSS MINIMUM RESERVOIR. Mainly connect cold water flow tap, hot water flow tap, heated water wall water outlet, unheated water wall water outlet, COLD WATER REINTRODUCTION RESERVOIR, MINIMUM WATER RESERVOIR PASSING HOT WATER AND LOSS OF THERMAL POWER and other devices in predetermined circuits for each function.

HOT WASTE AND THERMAL LOSS WASTE MINIMIZER RESERVOIR is a reservoir that enters the passage of CONTROLLED FLOW DRAINERS made to reduce the passage of heated water to the unheated waterways when cold water flows to o COOLDED WATER REINTRODUCTION RESERVOIR, reducing the passage of heated water through the storage of water inside the reservoir itself while storing heated water immediately after the diversion of cooled water so that it is available for the return phase of the water. hot water to the HEAT RECOVERY RESERVOIR.

These reservoirs have been carefully designed to allow height positioning and consequent pressure difference to allow flow for chilled water reuse and thermal energy recovery.

The accompanying drawings show, in schematic form, the arrangement of the INTEGRATED CLEAN WATER RECOVERY AND HEATING WATER PIPING SYSTEM and its provisions, object of this patent:

Fig. 1 shows a general arrangement of the described components working together.

Fig. 2 shows another general arrangement of the described components working together.

Fig. 3 shows alternative arrangement of part of the proposed components. Fig. 4 shows a schematic image of the water switching form.

Fig. 5 shows practical arrangement of the COLD WATER REINTRODUCTION RESERVOIR.

Fig. 6 shows a picture of how to prevent water overflow in the COLD WATER REINTRODUCTION RESERVOIR.

Fig. 7 shows an image of another way to prevent water overflow in COLD WATER REINTRODUCTION RESERVOIR.

31 As shown in Figures 1 and 2, some traditional structures are shown schematically, such as a traditional water tank 1 referred to in this text as an unheated water tank 1, a heated water tank 2 with its respective solar heater 3, pipelines. unheated water pipes 7 and heated water pipes 9, plus the traditional tap nozzle 4 with its unheated water tap 5 keys and heated water tap 6 keys. This is a schematic representation of a water use point serving as a reference for other use points such as showers. Important to note that the four branch tubular structure 30 is not a dirty water runoff system. In this structure 30 only clean water flows, being a coupler of the HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL LOSS 28 that communicates this reservoir 28 with the outlet of the tap switches 5 and 6 and with the pipe that connects tap nozzle 4 for the purpose of extracting accumulated air from reservoir 28, the controller key controlled system 29. Serves to remove air from the interior of reservoir 28 by opening switch 29 and draining water and air directly through the nozzle tube 32. Figures 1 and 2 show the main components of the INTEGRATED CLEAN WATER RECOVERY AND HEATING WATER PIPING SYSTEM, which are an integrated set and composed of COOLED WATER RESERVOIR 11, CONTROLLED FLOW DIVERS 14, 15, 20, 21, 36 and 41 THERMAL ENERGY RECOVERY RESERVOIR 24 and MINIMUM HOT WATER PASSAGE RESERVOIR AND LOSS OF THERMAL POWER 28.

33 As shown in figures 1 and 2, COLD WATER REFINERY RESERVOIR 11 designed to be positioned lower than the main unheated water reservoir 1 and heated water reservoir 2, and at a height greater than that of the water use points 4, the reservoir 11 having an internal space that fits into the normal unheated water path through water inlet 27 from the normal unheated waterway 7, inlet with regulating mechanism 12 which prevents water intake when the water level inside the reservoir is above the programmed level and said purposefully programmed level is below the total capacity of the reservoir 11 so that it allows to reserve remaining space to receive additional water drawn from nearby points 19 of the site. of heated water use 6, flow capture this released by key 26 and 37 which opens the cooled water circuit which will be channeled by arrangement into CONTROLLED FLOW DIVERS 20, 21 and 36, ducts designed to receive the flow of water from heated water pipes 9 and 10, conducted water which will be composed together with water already stored from pipes 7 of unheated water within the COLD WATER REINTRODUCTION RESERVOIR 11 a collection of water that is now available by arrangement in CONTROLLED FLOW DIVERS 14 and 36 which are interconnected to receivers of unheated water use sites 5.

As shown in Figures 1 and 2, the HEATED WATER THERMAL POWER RECOVERY circuit begins by closing the cooled water switch 26 and 37 and opening the water recovery switch 17 and 38. thermal energy causing heated water to rise through the hot water pipeline

9 to the HEAT RECOVERY RESERVOIR 24 which is below and downstream of the main reservoir 1 or other source, reservoir 24 having water inlet 32 with regulating mechanism 25 which prevents water from entering main reservoir 1 or from another source when the water level inside the reservoir 24 is above the programmed level, which said programmed level below the total capacity of the reservoir 24 allows to reserve remaining space to receive additional water from the reflux of the heated water pipes 9 to be reused in the normal flow of heated water in the water heating reservoir 2 below and downstream of the HEAT RECOVERY RESERVOIR 24, having flow programmers 33 directing water to the THERMAL ENERGY RECOVERY RESERVOIR 24 by specific way 23 or directly through the water tank itself 2, having controlled flow diverter ducts 15, 20 and 41 which communicate with higher pressure ducts 7 and 39.

As illustrated in Figures 1 and 2, the use of float taps 12 and 25 is provided for the use of float taps 12 and 25 to cool the height for water inlet for the COLD WATER RECOVERY RESERVOIR 11 and THERMAL ENERGY RECOVERY RESERVOIR 24. In order to prevent overflowing these reservoirs 11 and 24 have also been thought of float taps or vents that rise above the overflow height. Still in relation to the HEAT RECOVERY RESERVOIR 24, many variations can be foreseen, one of them is the inlet of reflux water from the pipes 9 to be made by an intermediate reservoir, not shown in drawings, inserted in the duct path 22 so that still heated water can be reused with priority.

36 As shown in figures 1 and 2, the HOT WATER PASSAGE MINIMIZER 28 is a reservoir that enters the passage of CONTROLLED FLOW DEVIATE DUCTS 15, 20, 21, 36 and 41 designed to reduce the passage of heated water to the unheated waterways 7 when the chilled water flows to the COLD WATER REINTRODUCTION RESERVOIR 11, the temporary storage of water in this passageway 28 is used as a method. time storing heated water just after chilled water diversion 19 so that it is available for the hot water return phase to the HEAT RECOVERY RESERVOIR 24.

37 Figure 1 illustrates one way in which the COLD WATER REINTRODUCTION RESERVOIR 11 is located downstream of the wall water outlets 8 and 10 and has water inlet in the COLD WATER REINTRODUCTION RESERVOIR 11 via the waterway. exit from the same reservoir 11. The COLD WATER REINTRODUCTION RESERVOIR 11 and the MINIMIZER OF HOT WATER PASSAGE AND THERMAL LOSS 28 are inside the environment of the house or building, the first, as shown in the figure, can be installed above the sink and the second below the sink through special fittings. Starting from an initial state in which all keys 5, 6, 17,

26 and 29 are closed, with the water from the hot water ducts 9 being cooled to a lower temperature by the natural cooling process, these waters are unsuitable for use by the hot water inlet part of the tap 6. So as not to waste this chilled water , the circuit starts by opening the switch 26 of the CONTROLLED FLOW DIVER 21 which opens a circuit in which the CONTROLLED FLOW DUIT 20 draws water from the wall water connector 10 through specific connection 18, bypasses the water by diversion 19 next to the water use device 6, for the HOT WATER PASSAGE MINIMUM AND HOT WASTE RESERVOIR 28 which will conduct the water to the COOL WATER REINTRODUCTION RESERVOIR 11 through the separate duct 21 having a float tap system 13 that prevents water overflow. Once hot water arrives at bypass point 19, flow can be interrupted by switch 26 and heated water use point 6 is ready for use, while unheated water use point 5 has reused water available from duct 14, and when this water runs out, there is still water that automatically enters reservoir 11 through inlet 27 which is a normal unheated waterway, and water continuously available for use in point 5 is supplied by the duct

14, including for other water-use devices 31. In the other cycle, when hot water is terminated, hot water is stagnant in the heated water pipes 9 which will cool if not used immediately. At this time, with the other keys closed, switch 17 may be opened which will have connection 16 via the CONTROLLED FLOW DIVER 15 to the wall water outlet 8 of unheated water pipes having higher pressure pushing water from return to the HOT WATER PASSAGE MINIMUM RESERVOIR 28 and then to the CONTROLLED FLOW DIVER

20 to provide return of hot water via lane 9 to the HEAT RECOVERY RESERVOIR 24 through a flow regulator which are illustrated as valves 33 which will direct the still heated water, specifically, to the THERMAL POWER RECOVERY RESERVOIR 24 which will then preserve the temperature of this water and then reintroduce it into the heated water reservoir 2. May have HEAT RECOVERY RESERVOIR 24 having heat insulating walls. This arrangement does not require the use of a water pump for its operation. This arrangement is also not limited to the use of water in bathroom or kitchen sinks, but also serves as a model for showers.

38 Figure 2 illustrates another alternative of the model of INTEGRATED CLEAN WATER RECOVERY SYSTEM AND HEATED WATER THERMAL ENERGY that has the differential of installing the COLD WATER RESERVOIR 11 in a more central position and upstream of the outlets. of water from the walls. In addition, the transport of chilled water is promoted by the return of water directly through the pipes 35 which supply the unheated wall outlets 40. In this way, this reservoir 11 supplies various water use points through pipelines 35 which traditionally feed the water use points of the house, also saving plumbing material and optimizing the possibility of providing diverted water.

39 In Figure 2, for the sake of ease of understanding flows only, it is noteworthy that the control 37 for triggering the chilled water recovery is to the left of the HOT WATER PASSAGE MINIMIZER 28, as opposed to the Figure 1, causing no difference in its operation. Although this arrangement, with COOLWATER REFINERY RESERVOIR 11 upstream better distributes reused water and saves pipelines, it does not produce enough pressure at outlet 40 to bring still-heated water to HEAT RECOVERY RESERVOIR 24. To resolve Therefore, it was envisaged to use another source of higher pressure water such as street water illustrated as plumbing 39.

Still in figure 2, the heated water recovery cycle begins

by opening the key 37 which promotes the passage of cooled water from the heated water pipeline 9 to the duct 20 through the bypass 19, going to the MINIMIZER OF HOT WATER PASSAGE AND THERMAL LOSS 28, proceeding to the duct 36 and to the COLD WATER REINTRODUCTION RESERVOIR 11 passing through the same outlet ducts 35 of this reservoir 11.0 another cycle, the thermal recovery starts, with the key

37 closed by opening key 38, with higher water pressure from duct 39 pushing water through duct 41, passing through the HOT WATER PASSAGE MINIMIZING RESERVOIR 28, duct 20 and duct 9 toward the HEAT RECOVERY RESERVOIR 24. The vertical tube protruding above reservoir 11 represents a breather extending above reservoir 1 to prevent water from overflowing and is one of the ways to prevent overflow while allowing water to escape. for ducts 35, but other ways to prevent this overflow can be designed as a float and associated valve system which will be illustrated in figures 6 and 7. 41 As shown in figure 3, arrangement in which the water outlet

the COLD WATER REINTRODUCTION RESERVOIR is not mixers of heated and unheated water; but rather an end point of use, and this same reservoir can receive water from other higher COOLDED WATER RESERVOIRS 11. Final fill points such as filters, dishwasher, washing machine, toilet flush tanks. The arrangement of the system is shown in which the water outlet of the COLD WATER REINTRODUCTION RESERVOIR 50 flows into toilet flush box 44 via duct 47, and that COOL WATER REINTRODUCTION RESERVOIR 50 may receive water from another RESERVOIR. COOLING WATER REINTRODUCTION 11 increasing the volume of water that can be reused or receiving water straight from the wall heated water outlet having flow control switches to trigger this passage. It has also been designed to have a bypass water receiving duct 46 from the shower center or hand shower hose. Where the diverter duct 46 is placed between the shower and the shower wall outlet, this segment must be rigid to maintain the stability of the shower. Temperature sensors 43 may be coupled to indicate the arrival of hot water at the site. Referring also to Figure 3, the procedure for storing rainwater or used for reuse for flushing toilets or for use in gardens and other less noble functions is known, and this function is integrated into the system through another level control mechanism. 48 with the highest height of all other inlets to allow preferential entry of reuse water from other reservoirs such as rainwater. Thus the order of priority of use of the water type is to first use the noblest and then the noblest waters as follows: First enter reused water, then cooled water and then normal track water 7 from the unheated water system. .

Fig. 4 illustrates flow opening switch arrangement comprising having, in place of flow controller switches 17, 26, 37 and 38, a diverter switch 51 which connects to the same ducts having predefined circuits having a position full-flow shut-off, a second water-saving position that passes the cooled water by opening downstream of the HOT-WASTE MINIMIZER 28 and a THERMAL LOSS-WATER RESERVOIR flow to the return of the heated water by opening upstream flow of the HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL LOSS 28. The ducts 52 and 53 represent these flow possibilities.

According to the various figures, if you choose independent control switches instead of switch 51, a better arrangement to enable the two water use circuits, the chilled water recovery and the thermal energy recovery circuits, to operate. position the flow opening and closing switches 26 and 37 downstream of the HOT WATER LOSS AND HOT WASTE MINIMIZER 28 when chilled water flows to the COOL WATER REINTRODUCTION RESERVOIR 11, and upstream 17 and 38 of the HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL LOSS 28 when thermal energy recapture flow occurs

Fig. 5 illustrates a practical device to be installed with respect to the arrangement shown in Fig. 1. As shown in Fig. 5, it is the COLD WATER REINTRODUCTION RESERVOIR 11 installed above the disposable bathroom and kitchen sinks 54 in which it is assumed wall mounting brackets and other mirrors to attach to their front face together with installation of shelves, doors, cabinets, light sources, switches, dials and system controls. The ducts 55 are representative of the ducts 14, 15 or 21 of figure 1.

Still in Figure 1 and 2 arrangement of HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL POWER LOSS 28 in the form of a two-room reservoir to minimize temperature equalization having the nearest part of the cooled water bypass 19 conical shape with heat insulating walls, and the distal part to this deviation 19 heat conductive walls. This form favors the function of the reservoir 28.

46 In any part of the system, the coupling of temperature and sensor meters, reservoir heights, water flow meters and presence locators, especially strategic points 9, 11, 19, 23, 24, 34, 40 and 43, interconnected to local or remote alarm or automatic flow control systems, the system having computerized control for a microcomputer, tablet, smartphone or smartwatch.

47 It is also envisaged that CONTROLLED FLOW DEVIATE DUCTS may be located externally or internally in relation to the walls of houses and buildings.

For a better description of the CONTROLLED FLOW DEVIATE DUCTS, a description of the communications of the ducts 14, 15, 20, 21, 22, 23, 36, 41, 46, 47, 55 and 59 may be provided, and may have additional routes to those described below containing or not open and close flow switches: duct 14 that connects output of COLD WATER REFLECTORY RESERVOIR 11 with cold water pass switch 5 having other ways 31 for connecting to other water use points; duct 15 which connects COLD WATER RESERVATORY INPUT 11 with unheated water wall water outlet 8 and with HOT WATER AND LOSS OF WATER MINIMUM RESERVOIR 28; conduit 20 connecting heated water wall water outlet 10 with hot-water switch 6 and with HOT WATER AND LOSS OF WATER MINIMUM RESERVOIR 28; duct 21 which connects water inlet to COLD WATER REINTRODUCTION RESERVOIR 11 with MINIMIZER OF HOT WATER PASSAGE AND THERMAL LOSS 28; duct 36 which connects cold water through switch 5 with HOT WATER PASSAGE MINIMUM RESERVOIR 28 and unheated water wall water outlet 40; duct 41 which connects MINIMUM OF HOT WATER PASSAGE AND THERMAL LOSS 28 with street water source or other source with higher water pressure than that of HEAT 24, duct 22 that communicates HEAT RECOVERY 24 with heated water reservoir 2 and duct 23 which connects water diversion system 33 with HEAT RECOVERY RESERVOIR 24. This list does not exclude other possibilities.

49 In situations where it is not possible to install the RESERVOIR

COLD WATER REINTRODUCTION 11 or HEAT RECOVERY RESERVOIR 24 at sufficient height differences to promote proper water circulation it is envisaged to alternatively introduce a downstream water pump from the HOT WATER AND LOSS WASTE MINIMUM RESERVOIR Thermal 28 in the case of water recovery flow, or upstream of that reservoir 28 in the case of thermal recovery flow. Another alternative is a two-way flow motor located in place of the key 51 of FIG. 4 further having the condition of closing the two-way flow to make normal use of the traditional water use devices 4, 5 and 6. Anyway Thus, this water pump is unnecessary in situations where reservoirs are positioned at adequate and sufficient height differences.

As illustrated in Figures 6 and 7, they illustrate solutions to the problem of preventing overfilling in COLD WATER REINTRODUCTION RESERVOIR 11 receiving water through the same water outlet 35 without interfering with or blocking the outlet of the water. same way.

51 Figure 6 shows COOLED WATER REFLECTION RESERVOIR 11 hermetically sealed, except for its water inlets and outlets, with control to prevent overflowing of water caused by reflux of chilled water by a float tap 58 that blocks the outlet venting above an upper limit. In Figure 2, the control to prevent overflow is by extending vent height 60 above overflow level with reservoir 11 also hermetically sealed except for its water inlets and outlets.

52 Figure 7 shows COLD WATER REINTRODUCTION RESERVOIR 11 with control to prevent water overflow caused by chilled water backflow being made by valve system 59 allowing water to escape from reservoir 11 but diverting water to another inlet in reservoir 11 which will prevent overflow by float tap mechanism 61.

Claims (15)

1. COLD WATER REINTRODUCTION RESERVOIR comprised of a water recovery component device of the "INTEGRATED CLEAN WATER AND HEATED WATER HEAT RECOVERY SYSTEM" characterized by reservoir 11 designed to be positioned at a lower height than the main unheated water reservoir 1 and the heated water reservoir 2, and at a height higher than the water use points 4, the reservoir 11 having an internal space that fits into the normal unheated water path through inlet 27 of water from the normal unheated waterway 7, inlet with regulating mechanism 12 that prevents water from entering when the water level inside the reservoir is above the programmed level and this programmed level purposely placed below the total capacity of the reservoir. reservoir 11 so that it allows to reserve remaining space to receive additional water c fit near points 19 of the heated water use site 6, this key-released flow capture 26 and 37 which opens the chilled water circuit which will be piped by arrangement in CONTROLLED FLOW DRAINER DUCTS 20, 21 and 36, ducts designed to receive the flow of water from heated water pipes 9 and 10, conducted water which will be composed together with the already stored water coming from the unheated water pipes 7 inside the COLD WATER REINTRODUCTION RESERVOIR11 a passing water collection to be available by arrangement in CONTROLLED FLOW DIVERS 14 and 36 which are interconnected to receivers of unheated water use sites 5. 2. THERMAL POWER RECOVERY RESERVOIR comprising device of the thermal recovery component of the "INTEGRATED CLEAN WATER AND HEATED WATER HEAT RECOVERY SYSTEM" characterized by reservoir 24 which is inserted below and main downstream of the reservoir 1 or other source, reservoir 24 having water inlet 32 with regulating mechanism 25 which prevents water from entering main reservoir 1 or another source when the water level inside reservoir 24 is above the programmed level, and This programmed level set below the total capacity of the reservoir 24 allows to reserve remaining space to receive additional water from the reflux of the heated water pipes 9 to be reused in the normal flow of heated water supplying water to the remaining water heating reservoir 2. below and downstream of the RECOVERY RESERVOIR THERMAL POWER SUPPLY 24, having flow programmers 33 which conduct water directly to the THERMAL POWER RECOVERY RESERVOIR 24 by specific route 23 or directly through the heated water reservoir 2 itself, having CONTROLLED FLOW DIVERS 15, 20 and 41 that communicate with higher pressure ducts 7 and 39. 3. MINIMIZER OF HOT WATER PASSAGE AND THERMAL LOSS OF WATER comprised of a device of the component of the “INTEGRATED CLEAN WATER RECOVERY AND HEATING WATER RECOVERY SYSTEM” characterized by reservoirs that are introduced into the vents that are introduced into the passageways. CONTROLLED "15, 20, 21, 36 and 41 designed to reduce the flow of heated water to the unheated waterways 7 when chilled water flows to the COLD WATER RESERVOIR 11, is used as method the temporary storage of water in this throughpass 28 while storing heated water just after the chilled water diversion 19 so that it is available for the hot water return phase to the THERMAL ENERGY RECOVERY RESERVOIR 24 . 4. "INTEGRATED CLEAN WATER RECOVERY SYSTEM AND HEATED WATER THERMAL ENERGY SYSTEM" according to claim 1, 2 and 3 characterized by the integration of the COLD WATER REINTRODUCTION RESERVOIR 11, CONTROLLED FLOW DRAINER DUCTS ENERGY RECOVERY 24 and HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL LOSS 28 in a system integrated by the sharing of structures which are HOT WATER PASSAGE MINIMUM RESERVOIR AND DERMAL 28 ENERGY LOSS CONTROLLED FLOW and flow control system. 5.WATER REINTRODUCTION RESERVOIR according to Claim 1, characterized in that the COLD WATER REINTRODUCTION RESERVOIR 11 is centrally positioned at a specific point of the house or building upstream of the water outlets of the walls of houses and buildings. water outlet to feed multiple water use points being fed by water reflux from their own water outlet 35. 6.WATER REINTRODUCTION RESERVOIR according to claim 1, characterized in that the COOLED WATER REINTRODUCTION RESERVOIR 11 is positioned downstream of the water outlets of the walls 8 and 10 of the house or building so that it can be installed in the environment. interior of houses and buildings. DEFINITION OF CONNECTIONS OF CONTROLLED FLOW DIVERS WITH OR WITHOUT KEYS according to any one of the preceding claims, characterized by duct 14 which connects COOL WATER RESERVOIR outlet 11 with cold water through switch 5 having other ways 31 to connect to other water use points; duct 15 which connects inlet of COOLED WATER REINTRODUCTION RESERVOIR 11 with water outlet from unheated water wall 8 and with HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL LOSS 28; conduit 20 connecting heated water wall water outlet 10 with hot-water switch 6 and with HOT WATER AND LOSS OF WATER MINIMUM RESERVOIR 28; duct 21 which connects water inlet to COLD WATER REINTRODUCTION RESERVOIR 11 with MINIMIZER OF HOT WATER PASSAGE AND THERMAL LOSS 28; duct 36 which connects cold water through switch 5 with HOT WATER PASSAGE MINIMUM RESERVOIR 28 and unheated water wall water outlet 40; duct41which connects HOT WATER PASSAGE MINIMIZER 28 and THERMAL LOSS WASTE RESERVOIR with street water source or other source with higher water pressure than that of HEAT 24 RESERVOIR, duct22 that reports ENERGY RESERVATION RESERVOIR THERMAL 24 with heated water reservoir 2 and duct 23 that connects water diversion system 33 with THERMAL ENERGY RECOVERY RESERVOIR 24. 8. CONTROLLED FLOW DRAINING CONTROL 17, 26, 37 and 38 control arrangement to coordinate "INTEGRATED CLEAN WATER RECOVERY AND HEATING WATER HEAT RECOVERY SYSTEM" according to any of the preceding claims characterized by locating the flow opening and closing switches 26 and 37 installed in the duct arm path downstream of the HOT WASTE MINIMUM WATER PASSAGE RESERVOIR and COOL 28 when chilled water flows to the WATER REPLACEMENT RESERVOIR COOL 11, and in the path of the upstream duct arms 17 and 38 of the HOT WATER AND LOSS OF HEAT MINIMUM RESERVOIR 28 when the thermal energy recapture flow occurs; or synthetic form with flow opening switch arrangement comprising having, in place of flow controller switches 17,26, 37 and 38, a diverter switch 51 that connects to the same ducts having predefined circuits having a position of full closure of all streams, a second water-saving position that passes the cooled water by opening downstream of the hot water and thermal energy loss mini- miser 28 and a third position that opens the flow for the return of the heated water by opening upstream the flow of the HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL LOSS 28. Practical installation arrangement of the HOT WATER PASSAGE MINIMUM RESERVOIR AND THERMAL POWER LOSS 28 according to claim 3, characterized in that it is installed below sinks, having mechanical support brackets on the wall or furniture adjacent to sinks such as sink cabinets having a key 29 on their top that connects via duct 30 to the water outlet 4 and to the outputs of the heated 6 and unheated waterway control switches 5, this key29 being the outlet for air accumulation of the reservoir. Practical installation arrangement of the COLD WATER REINTRODUCTION RESERVOIR 11 according to claim 6, characterized in that it is installed above the bathroom and kitchen sinks having wall-mounting brackets and other holders for coupling a mirror on its face. along with the installation of shelves, doors, cabinets, light sources, switches, dials, system controls and hooks and restraints to hold bathroom and kitchen utensils. Alternative arrangement of the COLD WATER REINTRODUCTION RESERVOIR according to claim 1, characterized by an arrangement for supplying toilet flush box or other non-potable water outlet into which it receives water direct from the wall-mounted heated water outlet having flow control switches to trigger this passage, which can be from a sink, shower water supply, by deviation from the central shower head or hand shower hose, or from outside the building, with the possibility of to add another inlet with water level control mechanism 48 to allow reuse inlet from other reservoirs being the reuse inlet height limit 48 higher than the chilled water inlet height limit 49 so that the less noble, reused water inlet is the first to be used when the reservoir 50 empties. Arrangement of the COLD WATER REINTRODUCTION RESERVOIR 11 according to claim 5, characterized in that the reservoir 11 is hermetically sealed, except in relation to its water inlets and outlets, with control to prevent water overflow caused by water reflux. cooled by a breather pipe water blocking system 60 extending the height above the overflow level or by a float tap 58 blocking the breather from leaking water above an upper limit. Arrangement of the COLD WATER REINTRODUCTION RESERVOIR 11 according to claim 5, characterized in that the reservoir 11 has the control to prevent water overflow caused by the reflux of chilled water being made by valve system 59 which allows water to escape from the reservoir. 11 but divert water rise to another inlet port 11 which will prevent overflow by float tap mechanism 61. Water height adjustment arrangement of the COLD WATER REINTRODUCTION RESERVOIR 11 and THERMAL ENERGY RECOVERY RESERVOIR 24 according to claims 1, 2, 4, 5, 6,10,11,12 or 13 characterized by: use water height regulating mechanism 12, 13, 25, 34, 42, 48, 49, 58 and 61 in the form of float taps. Monitoring and control system according to any one of the preceding claims, characterized in that it has coupling of meters and sensors for temperature, reservoir height, water flow meters and presence indicators at strategic points 9, 11, 19, 23, 24, 34 and 40, interconnected to local or remote alarm or automatic flow control systems, the system having computerized control for a microcomputer, tablet, smartphone or smartwatch.