ES2430765A1 - Procedure, system and tap to optimize the flow of tap water (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Procedure and system to optimize the flow of tap water. The present invention discloses a water saving system for installations that supply hot water from non-preheated water by means of at least one hot water pipe and at least one non-preheated water pipe, the system comprising: a first section for the inlet of hot water from at least one hot water pipe; a second section for the entry of unheated water of at least one water pipe not preheated; a third section for the water outlet; and water recirculation means from the first section to and through the second section without going through the third section allowing the reuse of water that is not at the desired temperature. The system can be completely housed in a tap for bathrooms, showers, kitchens or others. The present invention also discloses a tap that integrally comprises a water saving system. In addition, a method of redirecting water is disclosed, comprising at least the steps of detecting a demand for hot water; regularly check the current water temperature in the hot water pipe; and activate a water saving system according to need. (Machine-translation by Google Translate, not legally binding)

Description

PROCEDURE, SYSTEM AND TAP TO OPTIMIZE THE WATER FLOW OF TAP

TECHNICAL FIELD OF THE INVENTION

[001] The present invention relates to a system and method for optimizing the flow of water from a tap. In particular, the invention relates to a method that saves water while heating in the boiler and a system that implements this procedure. The invention also relates to a tap that fully comprises said system.

BACKGROUND

[002] Today, the control of drinking water consumption is very important. Drinking water is an essential asset in our world and its quantities are not infinite. Particularly in regions where there may be long periods of drought, it is necessary to pay attention to water consumption on a day-to-day basis. Therefore, it is required to save water to have it available to everyone.

[003] There are many techniques for treating water without which we would have much less drinking water available. There are systems to convert seawater into drinking water. On the other hand, the used water that leaves our homes and our factories is treated in sewage plants through chemical and biological processes to purify this water and convert it back into drinking water. These purification techniques are very expensive. Therefore, saving water at home indirectly reduces water treatment costs and increases the total availability of drinking water.

[004] There are devices and systems to save water at home. For example, there are economizing devices that work to reduce the flow or volume of outgoing water. Other devices incorporate timers that control the opening and closing of the tap only for a short interval to prevent the consumer from accidentally leaving the tap open for too long. Similarly, electronic devices work on a tap that use infrared rays to detect the presence of hands directly in front of the tap and only then activate the water outlet. When the hands are removed, said device detects its absence and the water flow stops.

[005] However, all these systems are either very complex, and therefore expensive, or they lack a device for not wasting water when particular hot water is needed. Normally, if the consumer wants hot water, he opens the corresponding tap and waits for some time until the hot water arrives. Meanwhile, the cold water existing in the part of the pipe that joins the hot water outlet of the heat source, for example a boiler, at the hot water outlet of the tap is usually allowed to run and therefore is lost. In this way a lot of water is spent unnecessarily, which also means an additional cost to the consumer because water has been consumed that has not been used.

[006] Depending on the performance of the heat source and its distance from the tap, the waiting time can be very long and amounts to a considerable amount of water being wasted. On the other hand, the hot water consumer has to wait a long time until hot water finally comes out. In particular, this waiting time in the shower in the morning is not pleasant for most people. Therefore, there is a need to have a system that prevents water loss during the period required to heat the water to a certain minimum temperature. It would also be useful for this system to indicate to the consumer when hot water is ready for use.

[007] Continuous water recirculation systems are known in the state of the art to prevent said water wastage. The disadvantage of these facilities is that they require works throughout the installation, needing to access different points of the pipe to adapt the existing pipe with valves, pumps and / or additional sensors. These works are very complex and expensive and can take many days until they are finished as they involve the temporary demolition of walls or ceilings, and then rebuild them at the end of the work.

[008] Therefore, there is a need to provide a water saving system so as not to waste it during heating which is simple and easy to install. In particular, there is a need for a water saving system that can be installed by the own

consumer without any professional help.

SUMMARY OF THE INVENTION

[009] All the aforementioned problems are solved by means of an optimized water saving system. In one embodiment, a water saving system (200) is disclosed for installations that provide hot water from non-preheated water by at least one hot water pipe and at least one non-preheated water pipe, the system comprising a first section for the hot water inlet of at least one hot water pipe; a second section for the non-preheated water inlet of at least one non-preheated water pipe; a third section for the water outlet; and water reconduction means from the first section to and through the second section without passing through the third section allowing the reuse of water that is not at the desired temperature. Said system can be mounted between the pipe and a tap or can be housed entirely in a tap.

[010] In another embodiment, a method for optimizing water reconduction using the water saving system is disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

[011] Fig. 1 illustrates a typical example piping system.

[012] Figs. 2A-2C illustrate a pipe with the system according to the present invention.

[013] Figs. 3A-3B illustrate the flow of water in the pipe depending on whether the system according to the invention is activated or not.

[014] Figs. 4A-4B illustrate in detail a system according to the present invention. This system can be fully housed in a tap in an embodiment of this invention.

[015] Fig. 5 is a flow chart illustrating the process of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[016] The system disclosed in the present invention solves one or more disadvantages of the prior art. The system comprises means to redirect the water in the existing pipe when hot water is required and thus prevents a loss of water during its heating. In addition, the system is configured so that it can be easily installed in both new construction home pipes and old home pipes. Preferably, the system is housed entirely in a tap or tap that can replace a conventional tap.

[017] FIG. 1 illustrates a typical example piping system. In each house there is a system of pipes 100, that is, the inner pipe, which gives access to the municipal water network. The system is connected to the municipal water supply network by the water inlet 101. The water inlet 101 typically comprises from the municipal network to the inner pipe a shut-off tap to disconnect the inner pipe from the municipal network, a meter of water to measure water consumption and a non-return valve that prevents water in the inner pipe from returning to the municipal network (not shown). Incoming water, which has not been previously heated, normally has an ambient temperature that the consumer feels cold. After the water inlet 101 there is a branching point 102 that separates the pipe into two first 103 and second 104 sections. The first section 103 corresponds to the hot water pipe and the second section 104 corresponds to the cold water pipe.

[018] The hot water pipe 103 can be divided into two parts first 103a and second 103b with a heat source 105 as a separation. The first part of hot water pipe 103a brings the still cold water to the heat source 105 where heating means heats the water. Hot water flows from the heat source 105 and passes through the second part of the hot water pipe 103b until it reaches a junction point 106 of the first two sections 103 and second 104 and the water outlet 107 representing a third stretch of water The junction point 106 may be, for example, a tap in a bathroom or kitchen. The cold water pipe 104 brings said cold water directly to the junction point 106 and to the water outlet 107.

[019] Heat source 105 comprises heating means for heating water. Said heating means may be selected from the group comprising a gas boiler, an electric boiler, a diesel boiler, a biomass boiler, solar panels or combinations thereof. The heat source 105 may additionally comprise at least one hot water tank configured for the accumulation of all the water that has been heated by the heat source 105. There may be a central tank for the accumulation of water from all the means of heating implemented in the piping system 100 or there may be an individual tank for each heating medium implemented in the piping system. For simplicity, hereinafter refers only to boiler without being limited to it. However, the person skilled in the art understands that any boiler or boiler system that combines different types of boiler can be used.

[020] The temperature of the hot water coming from the boiler 105 may depend on the performance of the boiler itself but also on the consumer if it can set a maximum temperature on the boiler 105. The temperature of the outgoing tap water may depend on the distance between the tap and boiler, that is to say the loss of heat during the passage through the pipe, or, in the case of a mixer tap, the amount of cold water added. In this invention, it is contemplated that the temperature of the hot water leaving the boiler 105 is between 40 ° C and 65 ° C to reach the consumer with a suitable temperature that can be between 25 ° C to 60 ° C, more preferably between 30 ° C and 50 ° C, and still more preferably between 30 ° C and 45 ° C.

[021] The junction point 106 is a point where the two hot water pipes 103b and cold water 104 join in the same area providing the consumer with hot, cold water

or warm as needed. It is not necessary for the two pipes 103b and 104 to be joined in a single pipe. It may also be that the two pipes 103b, 104 run the last section shortly before the water outlet 107 together in proximity but remain separate until the outlet 107 itself. It is then at the exit when you can mix hot water with cold water in case the consumer wanted it. The junction point 106 and the outlet 107 can be comprised in a single device such as a tap, a shower or the like.

[022] For example, there are still bathrooms or kitchens where there are taps with two separate outlets, one for each section of hot water 103 and cold 104, respectively. That is, there is a tap for hot water and a tap for cold water. Then, the junction point 106 would be the area constituted by the two faucets and there are effectively two exits 107. But most of the bathrooms and kitchens today have a single tap that can have two faucets, that is one for hot water and another one for cold water, or a single tap that, depending on its position, determines whether hot water or cold water comes out. In these cases, the junction point 106 would be the tap.

[023] In the case of faucets with two keys, the consumer can choose between hot and cold water. If you want water of a warm or warmer than hot temperature, you must open both keys and look for the water mixture that best resembles your desire. In the case of the tap with a single tap, the tap is normally a mixer tap that can mix hot and cold water through a valve shortly before outlet 107 and the consumer selects through the position of the tap what water temperature should exit the tap (not shown).

[024] However, this simple system illustrated in Fig. 1 presents the problems described above for saving water consumption. If the consumer wants hot water, he will open the hot water tap and until the water does not reach the proper temperature in the boiler 105, only the water already left at cold or warm temperature accumulated in the hot water pipe 103b, of so that a considerable amount of water is lost simply by waiting for hot water.

[025] The present invention solves these problems by the water saving system described below. Said system has the advantage that water is not wasted when the consumer wants hot water. It can be easily installed in kitchens, bathrooms, showers and the like where hot water is required. The system according to the present invention is housed entirely in a tap, which can replace a conventional existing tap. In another embodiment, the system between the inner pipe and the tap can also be installed given the characteristics of the system itself. The installation of the system according to the present invention, whether housed entirely in a tap or not, can be carried out by anyone without necessarily requiring professional help.

[026] In one aspect of this invention, the system together with a tap for bathrooms, kitchens or the like form a single unit, that is to say the system is entirely housed in a tap. This allows a very easy replacement of conventional taps that do not include any water saving system. Because it is only necessary to change the faucet, works in the pipe are not necessary either to hide or to embed said system in the wall. The consumer should only disassemble the existing tap and replace it with a tap that comprises the system of this invention.

[027] In Figs. 2A-2C shows the water saving system 200 according to the present invention in a simplified mode by way of example. The system of Figs. 2A-2C can be installed in a usual pipe like the one in Fig. 1. For installation they are only

necessary simple tools that each consumer has at home or his family

And it can be done in a short time.

[028] In a preferred aspect, a tap comprising the entire system 200 is a tap that has or two independent keys for hot and cold water, respectively,

or a mixer tap having a single key. In a more preferred aspect, the tap comprising the entire system 200 is a mixer tap with a single key. The tap has at least one outlet. However, in certain cases, such as for a bathtub with shower, at least two exits can be required. One of these outlets can also be coupled to other devices for the provision of jet water, such as hydro massage showers.

[029] System 200 of Figs. 2A-2C may form a single unit with a tap comprising said system 200 entirely in one aspect of this invention. In this case, it is understood that the tap comprises the entire installation from its connection to the inner pipe, that is to the hot water pipes 103b and cold water 104, to the point 107 where the water comes out. It is illustrated in more detail by way of example in Fig. 2B or 2C. If the faucet and the system 200 form a single unit, there is an advantage that the cost for its installation is reduced and presents a better aesthetic for its "all-in-one" model. However, the system 200 can also be a unit independent of the tap.

[030] Next, there is no difference between the appearance of two independent units or that of a single unit. It is understood that the features described below can also be implemented both in a system that is independent of a tap and in a system that is housed entirely in a tap forming a single unit.

[031] System 200 of Figs. 2B-2C is connected at two connection points first 210a and second 210b to the hot water pipe 103b and the cold water pipe 104, respectively. The connection between the system 200 and the first 103b and second 104 pipes at the first 210a and second 210b connection points is made by conventional fixing means. Furthermore, said first 210a and second 210b connection points comprise sealing means that can be part of said fixing means or can be independent of them.

[032] The system 200 comprises a first section 203 for the hot water inlet through which water flows from the hot water pipe 103b to the junction point 206 through which it will exit in a third section 107 of the tap. It also comprises a second section 204 for the cold water inlet through which water flows from the cold water pipe 104 to the junction point 206 through which said third section 107 will exit the tap. In Fig. 2B this water flow is illustrated by way of example by means of arrows indicating the direction of the water flow. The tap has at least one outlet. However, in certain cases, such as for a bathtub with shower, at least two exits can be required.

[033] In addition, system 200 also comprises water reconduction means and detection means (not shown). If hot water is required, the system 200 detects the hot water request by means of its detection means and activates said reconduction means. The detection means also controls the operation of the system 200 when it is operational and can notify the consumer that the water has been heated to the desired temperature. The detection means monitor and control at least the current water temperature in the first section 203.

[034] When activated, the reconduction means close the flow to the outlet of the tap 107 so that no water can be lost. This is illustrated by way of example in Fig. 2C. In addition, the reconduction means directs the water from the boiler 105 through the cold water pipes 104 and hot water 103a to the boiler 105, so that it again passes through the boiler. That is, the return of unwanted water to the boiler is forced through the cold water section in the opposite direction to the usual one. When the detection means of the system 200 observe that the temperature of the water coming from the boiler 105 is the desired one, the reconduction means are deactivated, the flow to the junction point 206 is reopened and the hot water can leave the tap.

[035] As can be seen in Figs. 2B and 2C, system 200 can be in two modes. The mode of Fig. 2B is the so-called standby or passive mode, that is, the system is not in active action but monitors the water present in the inner pipe for a possible demand for hot water. The mode of Fig. 2C is the action mode or active mode or activated mode, that is, apart from continuing to monitor certain water values in the inner pipe, it is also active in establishing and maintaining a closed water circuit in the inner pipe so that the water is heated to the desired temperature without wasting it. Closed circuit means that neither water can enter from the municipal network nor can water flow out of the circuit through a tap or the like until water reconduction stops.

[036] The closed-circuit water establishment means causes the water to pass through the cold water pipe 104 in the opposite direction. That is, the pressure necessary for the system 200 to function must be greater than the pressure established by the network. water municipal. Since there is an anti-return valve in the water inlet 101 (not shown), the overpressure established by the means of establishing a closed water circuit cannot return the water in the inner pipe to the municipal network but must pass from again by the boiler 105. Therefore, the system 200 establishes a closed water circuit in the inner pipe for a period until it reaches a predetermined temperature.

[037] The advantages of system 200 is that closing the outlet to the tap cannot waste water during heating. All water is redirected to boiler 105 instead of leaving. In addition, it is the same water that is heated again and again in the boiler

105. Each time the water passes through boiler 105 again, it has a current temperature higher than its last step. Therefore, it requires less energy for heating by reducing the energy consumption of the boiler 105 and thus reducing the economic cost.

[038] In Figs. 3A-3C shows by way of example a simple illustration of the possible water flows in the inner pipe. Fig. 3A is the inner pipe in standby state, that is, there is no open tap, or when only cold water is required. Water enters through the connection 101 to the municipal network and branches at point 102 in the hot water pipe 103 and the cold water pipe 104. System 200 is not activated but monitors the pipe for a possible demand for hot water . When the tap is opened for hot water to escape, the system 200 detects it and activates. A closed water circuit is then established as illustrated in Fig. 3B. Water cannot flow from the tap because the means of reconduction of the system 200 have closed the outlet 107. All the water is redirected to the boiler 105. While the direction of the water flow in the hot water pipe 103 is maintained, the system 200 reverse the direction of the water flow in the cold water pipe 104 as indicated by the arrows applying an overpressure. The water coming from the boiler 105 passes the system 200 and goes out to the cold water pipe 104 and goes to the water inlet 101. There it continues through the hot water pipe 103a and enters the boiler 105 again. This closed circuit of water is maintained until the water has the desired temperature. Then, the system 200 is deactivated and the water outlet 107 is reopened. As can be seen in Fig. 3C, then the direction of the water flow in the cold water pipe 104 is recovered and goes from inlet 101 to outlet 107.

[039] In one aspect of the invention, the closed-circuit water establishment means comprise at least one pump, at least one deviation to redirect the water and at least two valve systems that can close or open the water flow from the hot water pipes 103b and cold water pipes 104 towards the junction point 206. In another aspect of the invention, the detection means comprise at least one temperature sensor, at least one flow sensor and at least one safety means to interrupt the reconduction means allowing the flow of cold water through the tap water outlet. In another aspect of this invention, the detection means may further comprise at least one pressure sensor. In yet another aspect of the invention, the system 200 further comprises a control unit connected to the reconduction means and the detection means for controlling them.

[040] Next, the system 200 is described in more detail in relation to Figs. 4A and 4B that serve as an example. The system of Figs. 4A and 4B is connected to the hot water pipes 103b and cold water 104 at the first and second connection points 410 by conventional fixing means that can comprise sealing means. Fig. 4A illustrates system 200 when in standby mode. However, the system monitors on time or periodically whether hot water is required or not. On the contrary, Fig. 4B illustrates the system 200 activated to save water during heating.

[041] System 200 comprises two sections of water first 403 and second 404 that meet at connection points 410 with hot water pipes 103b and second 104. Water from the boiler 105 from the hot water pipe 103b enters thus, in the first section for the hot water inlet 403 and the water coming from the cold water pipe 104 enters the second section for the cold water inlet 404. Both sections first 403 and second 404 carry the water towards the point of junction 406 and the at least one outlet 107, representing a third section for the water outlet, when the system 200 is in standby mode. Although only a single inlet for hot water is shown as for cold water, it is not limited thereto, and there may be more than one inlet for hot water and / or cold water. For example, when more than one heating medium is used there may be an individual hot water inlet for each heating medium.

[042] Between the section for the hot water inlet 403 and the section for the cold water inlet 404 there is also a connecting pipe 420 that connects the first section 403 with the second section 404 in a position between the connection points first and second 410 and junction point 406. This connecting pipe 420 allows the system 200 to divert the water when it has to redirect the water. Said connecting pipe 420 may be perpendicular to the first 403 and second 404 sections as illustrated in Fig. 4A or 4B, but is not limited thereto. The pipe 420 may also have an inclination with respect to one or both first 403 and second 404 sections. In a preferred aspect of the invention, the connecting pipe 420 is located in a centered position between points 410 and 406.

[043] In one aspect of this invention, the system 200 further comprises in the first section 403 a flow sensor 421, a temperature sensor 422 and a valve system

423. In a particular aspect of this invention, the first section 403 of the system 200 further comprises a pressure sensor (not shown). In the second section 404, the system 200 comprises a valve system 424 and a safety means 425. The pipe 420 connecting the first sections 403 and the second 404 further contains means 426 to reverse the direction of water flow in the water pipe. cold water 104. Elements 420, 423, 424 and 426 represent the means of water reconduction, while elements 421, 422 and 425 represent the detection means. All these elements may be connected to a control unit 427 that controls the operation of the system 200 and / or may be connected to each other.

[044] The flow sensor 421 measures whether there is a water flow in the first section 403 or not, that is to say if there is a demand for hot water or not. The flow sensor 421 can be any means capable of detecting a flow of liquid such as the wheel of a water meter at the inlet 101. For example, the sensor 421 can comprise a winged wheel that moves only if there is a water flow. If there is no water flow in the hot water pipe 203, the flow sensor is not activated which signals to the system control unit 200 that it can remain in standby mode. However, if the consumer wants hot water, he will open the hot tap of the tap and water begins to flow in the first section 403. The wheel of the flow sensor 421 begins to move due to the flow of water. The movement of the sensor 421 indicates to the system 200 that the consumer needs hot water and that it is necessary to switch from standby to active mode. With or after this signal, the system 200 is activated. If the wheel of the flow sensor 421 slows down its movement and reaches a predetermined minimum speed, the system 200 is signaled to be stopped and returned to standby mode.

[045] According to one aspect of this invention, the flow sensor 421 may be located in any position in the first section 403, between points 410 and 406. In another aspect of this invention, the flow sensor 421 may be located at a position that is downstream of the connecting pipe 420 near the junction point 406. In a preferred aspect of this invention, the flow sensor 421 is located in a position that is upstream to the connecting pipe 420 near the connection point 410. If the flow sensor 421 is closer to the connection point 410, corresponding to a position as far as possible from the junction point 406, the system 200 can be activated quickly without wasting a single drop of water. However, if the flow sensor 421 is closer to the junction point 406, the reaction time between detecting a water flow in the section for the hot water inlet 403 and activating the system 200 may be very short and it is possible that water from unnecessarily comes out of the tap.

[046] Temperature sensor 422 detects the current water temperature in the first section 403 for hot water inlet. Any temperature sensor having the appropriate dimensions can be used to be implemented in the system 200. In one aspect of this invention, the sensor 422 can operate continuously, ie continuously monitor the current temperature in the first section 403. In another aspect of this invention, sensor 422 is only activated when it receives a signal that a water flow has been detected. During a water flow, the temperature sensor 422 periodically measures the current temperature until the end of the water flow is signaled. With or after this signal, the temperature sensor 422 stops detecting the current temperature and enters a standby mode again.

[047] The temperature sensor 422 may be located in any position in the first section 403, between the connection point 410 and the connecting pipe 420, preferably in proximity to the flow sensor 421. According to an aspect of this invention, due to that the water is to be diverted through the connecting pipe 420, the temperature sensor 422 is in a position upstream of said connecting pipe 420 in order to detect the moment when the water in the first section 403 has the desired temperature for water to flow out hot tap.

[048] The first 423 and second 424 valve systems regulate the direction of water flow. The first valve system 423 is located in a position close to the branch of the connecting pipe 420 in the first section 403, while the second valve system 424 is located in a position close to the branch of the connecting pipe 420 in the second section 404.

[049] The first valve system 423 is usually configured such that the hot water from the boiler 105 and the hot water pipe 103b passes through the first section 403 to the junction point 406 while accessing the pipe Connector 420 is closed. In the same way, the second valve system 424 is usually configured for the passage of cold water from the cold water pipe 104 through the second section 404 towards the junction point 406, while the access to the connecting pipe 420 is also closed. In this case, no water is redirected, that is, the first 423 and second 424 valve systems are closed for water reconduction and the system 200 is in standby mode.

[050] If system 200 is activated and water is required to be redirected through the boiler, then both valve systems first 423 and second 424 are switched synchronously. The water inlet from the hot water pipe 103b in the first valve system 423 is kept open as long as the outlet is closed to the junction point 406 and access to the connecting pipe 420 is opened instead. At the same time , the direction of the water flow in the second valve system 424 is reversed so that the outlet is closed towards the junction point 406, the access for the water coming from the connecting pipe 420 to the second section 404 and the inlet is opened The water from the cold water pipe 104 becomes the water outlet from the connecting pipe 420 and hot water pipe 103b. In this case, the water cannot flow through the tap since the tap is now disconnected from the pipe. Therefore, a closed water circuit is established, driven by the system 200 and the first 423 and second 424 valve systems.

[051] As mentioned above, both first 423 and second 424 valve systems are operated in a synchronized manner. If the first valve system 423 is closed for water reconduction, the second valve system 424 must also be closed for water reconduction. If not, it would not be possible for cold water to flow through the second section 404 to junction point 406 to mix with hot water as needed. In the same way, the second valve system 424 for water reconduction must be opened when the first valve system 423 for water reconduction is opened. If not, it would not be possible to reconduct water because it could not leave the connecting pipe 420 towards the cold water pipe 104.

[052] In a preferred aspect of this invention, both first and second valve systems comprise solenoid valves. In a preferred aspect of this invention, a three-way valve is used as the first 423 and second 424 valve system, that is a solenoid valve that not only can be opened or closed but a valve that allows water flow to pass through a one way or another. With the use of three-way solenoid valves it is sufficient to place a single first valve 423 at the branch point of the first section 403 with the pipe 420 and a single second valve 424 at the branch point of the pipe 420 with the second section 404.

[053] Normally, the water pressure in both hot water pipes 103b and cold water 104 or in both first 203 and second 204 sections, respectively, is the same. Therefore, in order to be able to redirect the water through the cold water pipe 104 towards the boiler, a means capable of exceeding the water pressure in the first section 404 and cold water pipe 104 is needed and thus reversing the direction of the water flow. Therefore, in one aspect of this invention, the system 200 further comprises in the connecting pipe 420 a pump 426 as a means of reversing the direction of the water flow in the cold water pipe 104. Said pump 426 is located between the two systems of valves 423 and second 424. The pump 426 can establish a higher pressure in the second section 404 and cold water pipe 104 than the existing pressure. In this way, the water to be redirected through the cold water pipe 104 is pressed and a closed water circuit can be established. The pump 426 is connected to the control unit 427 and receives from said unit 427 a signal when the first 423 and second 424 valve systems for water reconduction are opened. If both the first 423 and second 424 valve systems are closed for water reconduction, the pump 426 remains in standby mode so as not to waste energy.

[054] In addition, the system 200 has at least one safety means 425. In one aspect of this invention, said means 425 may be a sensor that is configured to detect when the consumer wants cold water while the system 200 is running, that is, while water is being redirected to the boiler. Said means may also be another element or device that detects the opening of cold water and notifies said event.

[055] For example, sensor 425 is able to detect when the cold water tap is opened. For example, the consumer has made a mistake and instead of cold water has opened the key for hot water. When opening said hot water tap, the system 200 is activated and until the water reaches the desired temperature, the system 200 will not stop the water reconduction.

[056] Then, when closing the hot water faucet and opening the cold water faucet, the system 200 requires a specific signal because, once activated, the system 200 no longer depends on what happens with the tap. For example, in the state of the art there is a problem that there is no safety means that can interrupt a water saving system when the cold water tap is opened. Therefore, state-of-the-art systems continue to heat and redirect water even if the cold water tap is open. This results in the fact that it keeps coming out, and non-cold water is wasted until the desired cold temperature is reached. Consequently, energy is wasted unnecessarily to heat water that is not required and already heated water is spent although cold water is required which can have negative effects for the consumer.

[057] Safety means 425 allows the consumer to interrupt the normal operation of the system simply through the cold water faucet. The sensor 425 detects a movement in the cold water faucet and can send a signal to stop the water reconduction and open the first 423 and second 424 valve systems so that water normally flows from the tap. For example, the safety sensor 425 can send a signal to the first 423 and second 424 valve systems and the pump 426 or it can send a signal to the control unit 427 which in turn stops water reconduction by deactivating the pump 426 and opening the valve systems first 423 and second 424 so that water normally flows from the tap. The safety element can be any sensor that can detect the movement of opening a tap. In one aspect of this invention, the safety sensor 425 is a micro switch. In another aspect of this invention, the safety sensor 425 is a pressure sensor.

[058] In one aspect of this invention, the system 200 comprises a control unit 427 for controlling its operation during water reconduction and for activating and deactivating it. The control unit 427 is connected to the flow sensors 421, temperature 422 and safety 425, the first 423 and second 424 valve systems and the pump 426. The unit 427 receives signals from these devices and transmits signals to them.

[059] The flow sensor 421 can transmit signals to the control unit 427 and receive signals from it. The sensor 421 can transmit a signal when a flow of water is initiated in the first section 203 from the hot water pipe 103b. In this way, control unit 427 knows that hot water is required. The sensor 421 can transmit this signal for as long as it takes to heat the water or for as long as there is a water flow. In another aspect of this invention, the sensor 421 only transmits a signal at the beginning and when the system 200 is activated, that is to say when the water reconduction is activated, the sensor 421 stops monitoring the water flow and returns to a standby mode. In a particular aspect, the sensor can monitor the water flow during the water reconduction without having communication with the control unit 427 and only by observing that the water flow has stopped, does it communicate with the control unit 427. Yes control unit 427 indicates that the temperature has reached its desired and / or programmed value, sensor 421 returns to standby mode. However, if the control unit 427 indicates that the water reconduction is still active, the sensor 421 can report the lack of water flow thus indicating a fault in the pipe.

[060] Temperature sensor 422 can send a signal indicating the current water temperature in the hot water pipe 103b. In one aspect of this invention, sensor 422 can transmit this signal continuously. In another aspect of this invention, the sensor 422 is in standby mode when the tap is closed, that is when there is no water flow through the first section 203, and is activated only by a signal from the control unit 427 indicating that the flow sensor 421 has detected a water flow. When the water reconduction is finished because the water has been heated to the desired and / or programmed temperature, the control unit 427 can transmit another signal to the temperature sensor 422 indicating that the temperature sensor 422 can stop monitoring the current temperature of the water and return to standby mode.

[061] The first 423 and second 424 valve systems can communicate with the control unit 427 to inform about their current configuration. The current configuration in this case means that the first 423 and second 424 valve systems can be in one of two modes: either in standby mode open to junction point 406 or in active mode for water reconduction, that is closing the passage towards the junction point 406. The control unit 427 can periodically check the current configuration of the first 423 and second 424 valve systems or only check it promptly after receiving a signal that requires changing the current configuration of the control systems. first 423 and second 424 valves. For example, a signal that requires changing said current configuration may be a signal notifying a hot water request, a temperature sensor notification 422 that the water has already been heated to the desired temperature or a 425 safety sensor signal indicating that the consumer wants cold water instead of hot water. Depending on the received signals, the control unit 427 can switch the first and second valve systems and thus change their current settings as needed.

[062] Also pump 426 can communicate with control unit 427. Control unit 427 can check periodically or promptly if pump 427 is in active mode

or in standby mode. The control unit 427 can switch the pump 426 between these two modes and change them as needed after receiving corresponding signals from the other devices of the system 200. Typically, the control unit 427 activates the pump 426 if it receives signals indicating a water request. , and for pump 426 when it receives signals indicating that it is necessary to stop the water reconduction for water to come out of the tap.

[063] Safety sensor 425 can also communicate with control unit 427. The control unit can check periodically or promptly if the cold water tap has been opened. The control unit 427 only consults the sensor 425 when the water reconduction is active. However, the safety sensor 425 can be activated when the cold water tap is opened and sends a corresponding signal to the control unit 427. The control unit 427 then checks if the system 200 is activated or not. If system 200 is activated, then control unit 427 will stop it so that cold water can escape.

[064] Apart from being connected to all the devices of the system 200, the control unit 427 may comprise additional devices that improve the comfort of the system 200 for the consumer in an aspect of this invention. In another aspect of this invention, the control unit 427 may be connected to said additional devices by being located in a different location from the control unit 427.

[065] These additional devices may comprise a wireless controller to control the system 200 remotely, at least one push button to activate the system 200 directly, at least one signaling element to signal that the water has reached its desired temperature or for other circumstances such as pipeline breakdowns, at least one timer to specify a certain time for water reconduction, a means to incorporate a computer-readable medium containing instructions executable by a hardware and / or software and / or firmware system that they indicate different ways to redirect water, a thermostat to manually control a desired temperature and the like. The additional devices mentioned above can be implemented individually or can be combined in any way. In addition, the additional devices can be connected to the control unit 427 and can communicate with it.

[066] In one aspect of this invention, the consumer can activate and control the system 200 directly through the tap. The consumer can open the hot water tap or use another system activation element 200 located at or next to the tap. The advantage of not using the hot water tap but another activation element is that unnecessary loss of water is avoided, if for example the user is not prepared. Said other activation element allows the consumer to activate the system 200 to obtain hot water, and when it is really hot, then the consumer opens the hot water tap and consumes this water.

[067] The faucet may comprise even more elements for controlling and / or stopping the system 200 or it may be the same element that activates, controls and for the system 200. In another aspect of this invention, the faucet comprises a wireless control for activating , control and stop the system 200. In this way, the system 200 can be activated from any place of the installation and it is not necessary to first access the bathroom or the kitchen or wherever. In a particular aspect, the tap comprises both elements for activating, controlling and stopping the system 200 and said wireless controller, so that the consumer can choose for example to activate the system 200 remotely or, if it is already next to the tap to be activated , you can do it directly on the tap. In yet another particular aspect, the wireless controller can be represented by a closed circuit with different control units distributed throughout the floor or it can be an application in the mobile with a base station, for example the control unit 427, next to the tap.

[068] In one aspect of this invention, one of these elements for activating, controlling and stopping the system 200 mentioned above may be a button located on the tap. In one aspect of this invention there is only one button to activate the system 200 and to deactivate it. In order to indicate whether water re-activation is activated or not, the button is accompanied by at least one indicator, either visual or audible, for example an LED in a certain color above or below said button, the LED can be included in said button or the height of said button can be differentiated. In another aspect of this invention, a button for activating the system 200 and another button for stopping the system 200 are provided. Activation or not of the water reconduction can be signaled as mentioned above. In a particular aspect of this invention, the buttons for activating and stopping the system 200 further comprise a small control screen showing the current temperature. Optionally, this screen can comprise even more buttons to control the desired temperature, for example to raise or lower it according to the needs of each consumer.

[069] In one aspect of this invention, the tap comprises at least one signaling element. Said at least one signaling element can signal that the desired hot water temperature has been reached, it may signal that the water reconduction is activated or not, or it may warn that the reconduction does not work or that there is a problem in the pipe. The at least one signaling element may be a visual and / or acoustic element, for example the LED described above.

[070] In a particular aspect, the system comprises exactly one signaling element to signal to the consumer that the water already has the desired temperature. Said signaling element may be a visual or acoustic element. For example, it may be a light, such as a pilot light, of a certain color, such as green or red, or it may be an acoustic signal that functions as an alarm system and that gives a timely or periodic signal once the water has reached the desired temperature. The acoustic signal has the advantage that the consumer can move on the floor and does not have to go back from time to time to check the state of the water reconduction.

[071] In a particular aspect, there is more than one signaling element and visual and / or acoustic elements can be combined in any way. This can be advantageous, for example, when the consumer can choose between different procedures to redirect the water to indicate which procedure is activated. In yet another aspect of this invention, said at least one signaling element may also be comprised in the wireless controller described above or may be comprised only in said wireless controller.

[072] In one aspect of this invention, the visual signaling element is an LED light that can be of any color. Preferably, the LED light is red. Depending on the state of water reconduction, the LED light may change color. For example, when system 200 is activated, the LED light may be red and once the water has reached the desired temperature, the LED light may change from red to green indicating that hot water is already available. However, the present invention is not limited thereto, and any color for the visual signage element can be used and combined.

[073] In one aspect of this invention, the faucet and / or the wireless controller may comprise a timer. The timer is a device that allows you to program the reconduction of water for short-term heating. When the timer is activated, the system 200 is activated and therefore the water reconduction. Activation only lasts for a certain time that has been previously programmed in or through the timer. Normally, said time may vary between half a minute and a few minutes, for example 1 minute, 2 minutes, 3 minutes, 4 minutes or up to 5 minutes. Depending on the age of the boiler and / or the distance between tap and boiler, said predetermined time may be even longer than 5 minutes.

[074] In one aspect of this invention, the timer is programmed with a fixed fixed time that can be between half a minute to five minutes. In this case, the consumer cannot vary the duration of water reconduction. This embodiment is particularly suitable for installations that need a similar predetermined temperature, or that does not vary. Depending on the length of the section of hot water pipe 103b between the boiler and the hot water outlet of the tap, the timer can be programmed so that a fixed period of water reconduction time is always activated. If said section is very long, a longer reconduction time will be needed than if said section is short.

[075] In another aspect of this invention, the timer is programmable and the consumer may vary the time determined to redirect water. In this case, the consumer can choose between a few seconds, preferably 30 seconds, and a few minutes, for example up to five minutes. This allows flexible installation of the system of the invention in any installation, regardless of the length of the section between the boiler and the tap.

[076] Providing a programmable timer also has the advantage that each consumer can freely choose their desired hot water temperature. In addition, it allows to shorten

or extend the activation time of system 200 as needed. It is also possible that the fixed time is not suitable for some pipes and / or boilers so that this time could be too short and when the tap was opened it would still be cold or it could be too long so that the consumer would have to wait long and In addition the energy expenditure would be higher.

[077] In a particular aspect of this invention, the timer may be directly connected to a button to activate the system 200 described above. In another aspect of this invention, the timer may be directly connected to a

previously described button and at least one light that signals the activation of the

200 system and / or the desired hot water temperature has been reached.

[078] In one aspect of this invention, the faucet and / or the wireless controller may comprise a means for stably or removably incorporating a programmer card containing instructions executable by a hardware and / or software and / or firmware system that indicate different applications to redirect water. Said hardware and / or software and / or firmware system controls and drives the control unit 427 to carry out the water reconduction in a certain manner according to the instructions stored in said programming card.

[079] In one aspect of this invention, the instructions refer to an economical way to redirect water. In the economic mode, water reconduction is only activated when the consumer actually requests hot water. The request for hot water is made by opening the hot water tap or by pressing a button on the tap and / or wireless control. Since the economic mode, and therefore the water reconduction, is only activated as needed, you have to wait a period of time to have hot water and the boiler is heating the water only in these moments and during the consumption of hot water. When the hot water consumption stops, the boiler returns to standby mode.

[080] In another aspect of the invention, the instructions refer to a comfort mode for redirecting water. In comfort mode, water reconduction is always activated. Therefore, when the consumer requests water either hot or cold, the water is retracted during the consumption of water and resumed once the consumption has ended. The advantage in this way is that the consumer will always have hot water whenever he wants. However, the boiler will also have to be activated as long as it involves a higher expense compared to energy consumption.

[081] In yet another aspect of this invention, the instructions refer to a programmed mode for water reconduction. In the programmed mode you can program and plan the water reconduction at certain times of the day or week. For example, if the consumer has a certain morning routine, you can schedule the water reconduction for an expected time and so the consumer does not have to wait a period until the water reaches the desired temperature but can for example

shower directly with hot water. Therefore, the boiler does not consume more than

necessary to preheat the water and energy consumption is minimal.

[082] In yet another aspect of the invention, a programmer card may contain the instructions for all the modes described above and more, such as instructions with different desired water temperatures according to the needs of different consumers. In yet another aspect of this invention, there may be a signaling element for each mode programmed in the programming card to signal to the consumer that the desired mode has been activated. In a particular aspect of this invention, a program or a software application is used in place of said programmer card that can execute the ways of redirecting the water described above.

[083] In another aspect of this invention, the faucet and / or the wireless controller comprise a thermostat that allows to set the desired temperature for hot water. For example, the thermostat can be a device that is located in the tap and by means of which a certain temperature can be adjusted as desired. The thermostat can also be located on the wireless controller. The thermostat can be implemented through an analog system or through a digital system, such as software.

[084] In a particular aspect of this invention, the system 200 is housed entirely inside a tap to optimize the flow of tap water. The advantage of having the system 200 housed entirely in a tap is that it can be easily mounted both in new construction home pipes and in old home pipes. In addition, it is not necessary to carry out complicated works on the floor because it is carried out by assembling the faucet according to the invention in the outlets of the pipe in the kitchen, the bathroom and the like. In older floors, the existing conventional tap is simply replaced by a tap according to the invention. In this way, the previous aesthetics of the bathroom, kitchen and the like can be preserved or improved.

[085] The faucet that fully comprises the system 200 may comprise some to all the aspects described above in any combination. In a preferred aspect, the tap further comprises at least one button and at least one luminous light outside. Said luminous light is preferably an LED light that can have any color. Said LED light signals at least that the desired hot water temperature has been reached. It can also signal that system 200 is activated or not. By means of the at least one button the consumer can activate the system 200. In one aspect two buttons can be provided. A button can be to activate the system 200 in comfort mode as described above. The other button may be to activate the system 200 in economic mode as described above. You can also combine both functions with a single switchable button. Thus, the consumer can choose between two modes of water reconduction to heat said water prior to its use without wasting anything. In a particular aspect, the economic mode button described here can be connected to a timer as described above so that the consumer can plan the waiting time until the hot water reaches its desired temperature.

[086] The tap can have any shape and size that allows the entire system 200 of this invention to be fully accommodated. The tap can have a substantially rectangular, substantially curved or substantially linear design. Said tap can be configured to be placed in a substantially inclined, substantially horizontal or substantially vertical direction. The tap can have a tap, that is, it is a mixer tap, or it can be a tap with two keys, one for hot water and one for cold water. Instead of keys, the tap can also comprise push-buttons that activate the flow of water. The tap can comprise a fixed spout or a movable spout, for example for use in a kitchen with two spades. In a particular aspect of this invention, the tap may comprise an area configured to receive signals through the air of a wireless controller.

[087] The procedure for optimizing water flow is described below. By way of example, Fig. 5 shows a flow chart comprising different steps of the process.

[088] In a first step 530 the request for hot water in a tap is detected. System 200 is notified that hot water has been requested. Said system 200 then checks 531 the current water temperature in section 203 by means of a temperature sensor. If the measured temperature is equal to or greater than a predetermined or pre-programmed temperature threshold, the system 200 is not activated 532 since the pipe already contains in the section 203 sufficiently hot water. If the measured temperature is below said temperature threshold, ie the water in section 203 is still cold, system 200 is activated 540.

[089] The activation of system 200 comprises several stages, which can be carried out at the same time or in sequence within a few moments in the range of micro or milli seconds. When the system 200 is activated, the access of the water to the junction point 206 is closed and a closed water circuit 542 is established. Said closed water circuit is constituted by the water coming from the boiler 105 of the hot water pipe 103b , which passes through the first section 203 and instead of exiting the tap exceeds the counter pressure in the cold water pipe 104, that is, the flow of water in the cold water pipe is temporarily reversed

104. During the time that the system 200 is activated, the water flows through the cold water pipe 104 in the opposite direction of the normal, and enters the first part of the hot water pipe 103a again to pass the boiler 105. The water is heated 543 in the boiler 105 and returns to the second part of the hot water pipe 103b and the first section 203. The system measures the current temperature of the water in the first section 203 on time or periodically until it reaches a temperature threshold indicating that hot water is already available.

[090] Said temperature threshold may be fixed or may vary according to consumer preferences. In a particular aspect of this invention, the temperature threshold may be in a range of 25 ° C to 60 ° C, more preferably in a range between 30 ° C and 50 ° C, even more preferably in a range between 30 ° C and 45 ° C.

[091] When the system 200 measures that the water that is circulating along section 203 has reached or exceeded the temperature threshold, it can notify the consumer of this fact through a visual or acoustic signal. For example, in a particular aspect of this invention, a red LED light on a faucet that signals the consumer that he can already take a shower is turned on. In addition to notifying the consumer, the system 200 also stops and returns to a standby mode. That is, the access to the water at the junction point 206 is opened so that hot water can flow from the tap. The stages of notifying the consumer and stopping the system 200 can occur at the same time or one after the other at a very short interval in the range of few micro or milli seconds. System 200 remains in standby mode until the next hot water request.

[092] What has been described comprises several exemplary embodiments. As it is not possible or feasible to describe in detail all the variety of combinations and permutations of the inventive concept that would lead to a large number of embodiments, and redundant paragraphs, the editor understands that the person skilled in the art would derive, after a direct reading and objective of this disclosure, the different permutations and possible combinations of the different embodiments and aspects described. Therefore, the main embodiments and aspects have been described, understanding that they comprise the other combinations, variations and modifications, as long as they fall within the scope of protection defined by the claims. The average person skilled in the art would understand that the description of the presented embodiments does not limit the invention, nor does the drawings.

Claims (37)

1. Water saving system (200) for installations that provide hot water to from non-preheated water using at least one hot water pipe and at least 5 a non-preheated water pipe, the system comprising: a first section for the hot water inlet of the at least one hot water pipe; a second section for the non-preheated water inlet of at least one non-preheated water pipe; 10 a third section for the water outlet; Y water reconduction means from the first section to and through the second section without passing through the third section allowing the reuse of water that is not at the desired temperature. The system (200) according to claim 1, wherein the system (200) is entirely housed in a tap. 3. The system (200) according to claim 1 or 2, wherein the system (200) comprises also a control unit (427). twenty 4. The system according to claim 3, further comprising at least one flow detection means. 5. The system according to claim 3, further comprising at least one temperature sensing means. The system (200) according to claim 3, wherein the system (200) comprises at least one safety means (425) for interrupting the reconduction means allowing the flow of non-preheated water through the third section. 7. The system according to claim 3, wherein the water reconduction means comprise at least one valve system (423, 424), a means (420) for diverting the water and a means (426) for partially inverting the direction of water flow in at least one section of non-preheated water.

8.

The system (200) according to claim 7, wherein the means for diverting the water is

a connecting pipe (420).

9.

The system (200) according to claim 8, wherein the means for partially reversing the direction of water flow in at least one section of non-preheated water is a pump (426).

10.

The system (200) according to claim 9, wherein the system (200) comprises two first and second valve systems (423, 424).

eleven.

The system (200) according to claim 10, wherein the first and second valve systems (423, 424) are located in proximity to the branches of the connecting pipe (420).

12.

The system (200) according to claim 10, wherein the first and second valve systems (423, 424) are composed of solenoid valves.

13.

The system (200) according to claim 12, wherein the solenoid valves are three-way valves.

14.

The system (200) according to claim 4, wherein the flow detection means is located downstream of the water reconduction means.

fifteen.

The system (200) according to claim 4, wherein the flow detection means is located upstream of the water reconduction means.

16.

The system (200) according to claim 5, wherein the temperature sensing means is located upstream of the water reconduction means.

17.

The system (200) according to claim 6, wherein said safety means (425) is configured to detect a demand for cold water from the tap.

18.

The system (200) according to claim 6, wherein the safety means (425) is a microswitch or a pressure sensor.

19.

The system (200) according to claim 3, wherein the control unit has

wired and / or wireless connection with all the means included in the system (200).

twenty.

The system (200) according to claim 3, further comprising additional devices that are selected from the group comprising a wireless controller, at least one button, at least one signaling element, at least one timer, a thermostat, a means for incorporating a computer readable medium, or combinations thereof.

twenty-one.

The system (200) according to claim 20, wherein the at least one button is configured to activate, control and stop said system (200).

22

The system (200) according to claim 20, wherein the at least one button is connected to at least one signaling element.

2. 3.

The system (200) according to claim 20, wherein the at least one button is connected to a timer.

24.

The system (200) according to claim 22, wherein said signaling element is a visual and / or acoustic element.

The system (200) according to claim 22 wherein the visual signaling element is an LED element.

26.

The system (200) according to claim 20, wherein the timer is a programmable timer configured to be programmed by a user.

27.

The system (200) according to claim 20 wherein the computer readable medium is a programmer card.

28.

The system (200) according to claim 27 wherein the programmer card is configured to execute an activated water reconduction mode as necessary, a water always activated mode and / or a planned water reconduction mode.

29.

The system (200) according to claim 20 wherein it comprises at least a first

button connected with a first LED light and a second button connected with a second LED light, in which the first button activates a first mode of redirecting water and the second button activates a second mode of redirecting water.

30

Tap comprising a system (200) according to any of claims 1-29.

31.

The tap according to claim 30 comprising more than one water outlets.

32

Water saving procedure for installations that provide hot water from non-preheated water by at least one hot water pipe and at least one non-preheated water pipe, the procedure comprising:

detect (530) a hot water request; determine (531) the current water temperature in a first inlet section of Hot water; compare the measured temperature with a predetermined threshold; and redirect the water from the first section to and through a second section of non-preheated water inlet without going through a third section of water outlet when the determined temperature is below the predetermined threshold, thus allowing the reuse of water that is not at the desired temperature.

33.

Method according to claim 32, comprising the steps of:

control the current water temperature in the closed water circuit formed by the water reconduction; and when the current water temperature equals or exceeds the predetermined threshold, disable water reconduction.

3. 4.

Method according to claim 33, wherein the procedure is carried out entirely in a tap.

35

Method according to claim 33, further comprising interrupting the reconduction of water allowing the flow of non-preheated water through the third section.

36.

Method according to claim 33, which comprises diverting the water and partially reversing the direction of water flow in at least one section of non-preheated water.

5 37. A method according to claim 34, which comprises interrupting the reconduction of water when a demand for cold water is detected by means of the cold water tap. 38. A method according to claim 33, comprising activating, controlling and stopping the normal flow and reconduction of water. 39. A method according to claim 33, further comprising programming a timer by a user. A method according to claim 33, comprising a mode of reconduction of activated water according to need, a mode of reconduction of water always activated and / or a mode of reconduction of planned water. 41. A method according to claim 33, comprising activating a first mode of 20 redirect water by means of a first push button and activate a second way of redirecting water by means of a second push button. FIG. one FIG. 2A FIG. 2B FIG. 2 C FIG. 3A FIG. 3B  FIG. 3C   FIG. 4A FIG. 4B FIG. 5