PT11205Y - AUTOMATION FOR WATER SAVING - Google Patents

Abstract

THIS AUTOMATION WAS WASTE WATER IN HOT WATER TAPS, WHERE THE COLD WATER CONTAINED IN THE PIPES ARE GENERALLY WASTED WHILE THE HOT ONE DOES NOT ARRIVE, AVOIDING WASTE WATER WASTE, WHICH UNDERSTANDS TWO MODULES PAIRED BY RADIO, INTERCHANNING THE EMISSION MODULE (E) BETWEEN THE WATER OUTLET AND THE TAP (19), AND THE RECEIVER MODULE (R) BETWEEN THE WATER OUTLET (23) AND THE WATER HEATER (16). AFTER INSTALLED, IT IS ENOUGH TO OPEN THE HOT WATER TAP THAT THE ISSUER (E) IS FURNISHED INTERNALLY BY A HYDROGATOR (2), SWITCHS THE WATER THROUGH THE ELECTED THREE-WAY VALVE (1) AND ISSUES RADIO SIGNAL TO THE RECEIVER (R) THAT IS CONNECTED TO THE CURRENT (18), AND OPERATES THE ELECTRIC PUMP (12) FORCING THE WATER CIRCULATION BETWEEN HOT PIPE (21) AND COLD (22). WHEN HOT WATER COMES TO THE ISSUER (E), THE THREE-WAY ELECTRODE VALVE (1) REPLACE THE EXIT TO THE TAP (19) AND THE CESSA RADIO SIGNAL, MAKING THE MODULES WAITING.

Description

DESCRIPTION

TECHNICAL FIELD OF THE INVENTION: Said water-saving automation is an electromechanical system composed of two emitter (E) and receiver (R) modules and is intended to save water on hot water taps in domestic, professional or industrial environment. The prior art:

Currently when you open a hot water tap, it is necessary to wait some time until it actually gets hot to the tap, and the cold water that is contained in the pipes usually goes to the sewer and is wasted. Every day, considerable amounts of drinking water are lost in this way. In order to avoid this waste, some people use buckets, buckets or other containers that end up occupying space in the bathroom and are impractical and unsightly. There are other similar patented automations for the same purpose of saving water such as: ES1074141U, EP2554919, ES1060933Y, DE3723089, FR2992986, WO2013017938, DE19712051, but which in one way or another do not solve the problem in the same way as described below .

Description of the figures

FIG. 1 shows the preferred embodiment of the two modules: The receiver (R), which is inserted between the second conduit (22) and the respective water heating apparatus (16) and which is supplied through a socket (18) and the emitter (E) which is sandwiched between the first conduit (21) and the second conduit (22) and the water outlet valve (19). The emitter modules (E) and receiver (R) are mounted on the supports (25).

Fig.2- In this figure we observe the emitter module (E) with the approximate aspect of the various components and placed in the places provided: Hydrogenerator (2), through which enters the water that produces electric current; which connects to the three-way valve (1), which switches the water between the outlet adapter to the tap (8) and the fixture (9) and the T-tube (6); which is tightened to a second securing accessory (9a); we observe a T-shaped tube 6, which receives the water from below the second conduit 22, connects with the electrovalve 1, from which it receives the return water, and the upper outlet towards the faucet that is tightened with the second securing accessory (9a); a first general switch (7); a thermal switch (5), placed on top of the metal tubing of the electrovalve (1) or upstream of the hydro generator, as can be seen in figure 4; a first electrical regulation and distribution plate (3), to which all the electrical components present are connected; and finally, a radio transmitter (4), for communication with the receiver module (R).

Fig.3- In this figure we have the receiver module (R) with the approximate aspect of the various components and placed in the places provided: A circulating electro-pump (12), through which water enters; which is coupled to a normally open flow switch (11), which only connects the receiver module when there is circulating water; which joins a curve (10), through which the water leaves; a second general switch (14); a power supply and a second electrical regulation and distribution board (15); and a radio receiver (13), with which signal is received from the emitter module (E).

In the receiver module (R), (upper part of the drawing), we can observe a water heater, cylinder, solar panel or other (16), to which the connects said module; the water comes from said second channel (22); enters the circulation pump (12); which joins with the normally open flow switch (11); which joins said water heating apparatus (16); there is a power supply socket (18); to which a second general switch (14) is connected; which is connected to the water flow switch (11); which drives the electrical circuit for the power source and the electrical regulation and distribution board (15); which feeds the radio receiver (13); which in turn turns the circulation pump (12) on / off; and finally we see the first channel (21), which is directed to the various taps. Looking now at the emitter module (E) (bottom of the drawing), we have the water inlet passing through the normally closed thermal switch (5); and goes to the hydrogenerator (2); and continues to the three-way electrovalve (1); where the water outlet between the tap (19) and the second channel (22) is switched; in the electric scheme we see the hydrogenerator (2); which goes to the main switch (7); together with the thermal switch (5), which switches the emitter module on / off according to the water temperature; to the first electric regulation and distribution plate (3); which feeds the three-way electrovalve (1); and the radio transmitter (4), which turns the receiver module (R) on / off.

In this figure we see the module (E / R) and the holder (25) designed in such a way that it can be mounted horizontally or vertically, using for this purpose the use of bushing and screw (23), double tapes adhesive (24) or flexible clamp (27), depending on the location or surface where it will be installed. To insert or remove the respective module (E / R), press the tab (26) to insert or remove it from the holder (25).

DETAILED DESCRIPTION OF THE INVENTION: The present invention, which is described in figure 4, is composed of two emitter (E) and receiver (R) modules, the emitter (E) being interposed between the existing faucet (19). the first channel 21 and second channel 22, and the receiver R interspersed with the water heater or other water heating equipment 16 and the second channel 22. These two modules are paired via radio, not resorting to electrical cables between them.

It is now described as follows: after installing the modules in their respective places, the hot water faucet opens, triggering the whole process of automatism, putting the water circulating through the hydrogen generator (2), and proceeding to the electrovalve (1) which switches the outlet between the tap (19) and the second channel (22). In the electric circuit, the hydrogen generator (2) rotates by force of the water circulation thus producing electric current, which is sent to the first electric regulation and distribution plate (3) to which all present electrical devices are connected; the thermal switch 5 compares the water temperature, and if it is below the pre-set temperature, closes the supply circuit of the three-way electrovalve 1 which will switch the water outlet from the tap 19 to the second channel 22 and immediately closes the power supply circuit of the radio transmitter 4 which will send signal to the radio receiver 13.

At the same time, during the above-described process, when the tap was opened, the water passed through the circulation pump (12) by freely rotating it and then passed the normally open water flow switch (11) and followed the water heater, cylinder, solar panel or other (16). In the electrical circuit, the water flow switch 11 was caused to establish electrical potential communication from the power supply to the second electrical regulation and distribution board 15, which in turn fed the radio receiver 13, which upon receiving the signal from the emitter 4, closed the electric circuit which feeds the circulation pump (12) which then led the water to circulate through the first conduit (21) thereby maintaining the circulation of water in the hydro generator (2) . From the above described, we see that the cold water that was inside the first conduit 21 was recannealized to the second conduit 22 by the action of the three-way electrovalve 1. This automatic process takes about three seconds to occur and will remain in this state until the hot water from the heater, cylinder, solar panel or other (16) reaches the desired temperature upon reaching the thermal switch (5).

In the reverse process, when the hot water reaches the thermal switch (5) and reaches the predetermined temperature, it opens the circuit and causes the three-way electrovalve (1) to return to the initial position, thereby switching the water from the first (21) to the tap (19) and then the radio transmitter (4) is switched off and the signal stops. While the hot water is running, the hydrogenerator (2) continues to produce electrical current and to power the internal components, now in their standby mode. At the same time, in the receiver module (R), when the radio signal has ceased, the radio receiver has opened the electric circuit which feeds the circulation pump (12) off. At this point the receiver module (R) is also in the standby mode, waiting for a new order from the transmitter module (E).

In order to turn off the aforementioned automatism for water saving, simply close the hot water tap which stops the circulation of water in the first conduit (21), which stops the rotation of the generator (2), leaving it to produce electric current; at this stage, the entire emitter module (E) is switched off and waiting for a new water opening to repeat the process, if the water from the first conduit (21) is already cold again. At the same time in the receiver module (R), after the tap has been closed, the water has stopped flowing through the water flow switch (11) causing it to open the circuit connecting the power source and the second regulating and distribution plate (15); at this stage, the entire receiver module (R) is switched off until the water flows back through the water flow switch (11), thus waiting for a new order from the transmitter module (E).

With the tap closed, no water flowing in the first conduit (21) there is no consumption of electric current by the said automation. A general switch has been set in each module, (7) and (14) respectively, with the intention of preventing said water saving automation from operating when this is not desired, either by hypothetical equipment malfunction, holiday trip or other reason why the said modules should be switched off. If the general switches (7) and (14) are switched off, the taps can be used normally as if the said modules were not installed, without compromising the common use of the water.

Claims (10)

An automatic water-saving system characterized by including: a. an emitter module (E) containing: i. a three-way electrovalve (1); ii. a hydrogenerator (2) connected to said three-way electrovalve (1), upstream thereof; iii. a T-shaped tube (6) connected to said three-way electrovalve (1), downstream thereof; iv. an outlet adapter (8) connected to said three-way electrovalve (1), downstream thereof; wherein said three-way electrovalve (1) is capable of switching its output between an outlet, directed to said T-shaped tube (6), and another outlet, directed to said outlet adapter (8); v. a radio transmitter (4); saw. a thermal switch (5) capable of electrically actuating: A. on said three-way electrovalve (1); and B. on said radio transmitter (4); as a function of a predetermined temperature threshold value; and vii. a first electrical regulation and distribution plate (3) which: A. is electrically powered by said hydrogenerator (2); and B. is in electrical connection: I. with said thermal switch (5); II. with said three-way electrovalve (D and III) with said radio emitter (4), and b) a receiver module (R) containing: a circulating electro-pump (12); a flow of water (11), connected to said circulating electro-pump (12), downstream thereof, (iii) a curve (10) connected to said water flow switch (11), downstream thereof; a radio (13) which: A. is capable of receiving a radio signal from said radio transmitter (4), and B. is in electrical connection with said circulating electropump (12); and a second electrical regulation and distribution plate (15) which: A. is electrically powered by said input for electrical power or power source (18); (11) with said radio receiver (13). A system according to claim 1, characterized in that, in said emitter module (E), there is a first attachment device (9) to which said output adapter (8) is tightened. A system according to any one of the preceding claims, characterized in that in said emitter module (E) there is a second fixing accessory (9a), fastened to an outlet of said T-shaped tube (6). A system according to any one of the preceding claims, characterized in that in said emitter module (E), said thermal switch (5) is placed on the metal pipe of said three-way electrovalve (1). A system according to any one of claims 1 to 3, characterized in that said emitter module (E), said thermal switch (5) is positioned upstream of said hydrogenerator (2). A system according to any one of the preceding claims, characterized in that in said emitter module (E) there is a first general switch (7) between said hydrogenerator (2) and said thermal switch (5). System according to any one of the preceding claims, characterized in that said emitter module (E) is connected to a support (25) including bushing and screw (23), double-adhesive tapes (24) or flexible clamp ( 27) and a tab (26) for connecting and disconnecting said emitter module (E). A system according to any one of the preceding claims, characterized in that, in said receiver module (R), there is a second general switch (14) between said input for the electric power or power source (18) and the second said water flow switch (11). A system according to any one of the preceding claims, characterized in that said receiver module (R) is connected to a support (25) including bushing and screw (23), double-adhesive tapes (24) or flexible clamp ( 27) and a tab (26) for connecting and disconnecting said receiver module (R). An automatic process for saving water, executed by the system described in any one of the preceding claims, characterized in that it comprises the following steps: a. start of water flow; B. (2), from a water heating apparatus (16) by a first conduit (21); W. a first electrical potential communication, is of said hydrogenerator (2) to the first electric regulation and distribution plate (3); d. (12), coming from the network by a second conduit (22), the latter being free to rotate; and. current water inlet in the three-way electrovalve (1), coming from said hydrogenerator (2); f. passing water through the water flow switch (11), coming from said circulating electro-pump (12) and directed to said water heating apparatus (16); g. a second electrical potential communication, from the input to electrical power or electrical power source (18) to the second electrical regulation and distribution board (15), triggered by actuation of said water flow switch (11); H. a third electrical potential communication, said second electrical regulation and distribution plate (15) to the radio receiver (13); i. evaluation of the temperature of the running water by the thermal switch (5); j. the value obtained for the running water temperature is less than the pre-set temperature threshold: i. switching the outlet of said three-way solenoid valve (1) from the mackerel directed to a tap via the outlet adapter (8) to another outlet is directed to said water heating apparatus (16), via the shaped tube (6) and said second conduit (22), triggered by a first electric actuation, is said thermal switch (5); ii. the emission of a radio signal by the radio transmitter (4), triggered by a second electric actuation, is also of said thermal switch (5); iii. receiving said radio signal by said radio receiver (13); iv. (12), triggered by a third electric actuation, said one of said radio receiver (13), in turn unchained by said receiving; v. (1) is connected to said circulation pump (12), which is already connected, and is conditioned by said switching, wherein the water: (A) leaves said water heating apparatus (16); B. is carried by said first channel (21); C. then passes through said hydrogenerator (2); D. then enters said three-way electrovalve (1); E. then exits said three-way electrovalve (1) and enters said T-shaped tube (6); F. then exits said T-shaped tube (6), following said second conduit (22); G. then passes through said circulation electro-pump (12); H. then passes through said water flow switch (11); and I. thereafter enters said water heating apparatus (16); k. when the value obtained for the temperature of the tap water is equal to or greater than the said pre-set temperature threshold: switching of said switching, triggered by the cessation of said first electric actuation; ii. cessation of the emission of said radio signal by said radio transmitter (4), triggered by cessation of said second electric actuation; iii. cessation of reception of said radio signal by said radio receiver (13), triggered by said cessation of transmission; iv. disconnection of said circulating electro-pump (12), triggered by the cessation of said third electric actuation, in turn triggered by said cessation of the reception; v. cessation of said forced water circulation, triggered by said shut-off and said reverse switching; and vi. establishing the water circuit towards a faucet, triggered by said reverse switching; l. end of water flow; m. stopping said hydrogenerator (2) and terminating said water passage through the water flow switch (11), caused by said flow end; n. cessation of said first electric potential communication, caused by said stop; O. cessation of said second electrical potential communication, caused by said end of said passage; and p. cessation of said third communication of electric potential, caused by said cessation of said second communication.