NL1013603C2 - Hot water tap. - Google Patents

Abstract

Draw-off conduit for transporting water from a hot-water heater to a draw-off point, which is connected in the vicinity of the draw-off point to a thermally insulated storage vessel and comprises control means for storing water from this draw-off conduit in that storage vessel and filling this draw-off conduit with cold water immediately following drawing of water from the draw-off point, and extracting water from that storage vessel at the start of a repeated drawing of water from that draw-off point.

Description

TAPLEIN FOR HOT WATER

The invention relates to a tap pipe for transporting water from a hot water appliance to a tapping point.

Such taps are the cause of loss of energy and water, which loss is caused by the cooling of warm water that remains after a first tap of water at a tapping point in the tapping line. Before hot water can be tapped a second time, a user first leaves the tap in the tapping line after the first tapping and since then drained cooled water, which means a loss of water and energy. Depending on the length of a tap pipe and the frequency of tapping, such so-called tap losses can become substantial on an annual basis. The potential cost of tap losses in homes is further distorted by the measure that attempt is made to keep tap lines short by placing a second hot water appliance (for example a kitchen water heater or electric boiler) in the immediate vicinity of a tap point. Placement of a second hot water appliance obviously contributes to the comfort of the user, who only has to wait a short time for hot water to be available, but results in operating and investment costs that are relatively high compared to the cost of a first heating appliance , for example a combination appliance placed in an attic for hot water supply and home heating.

It is an object of the invention to provide a tapping pipe in which loss of water and energy as a result of the cooling of hot water in that pipe does not at least hardly occur.

This object is achieved, and other advantages are achieved, with a tapping pipe of the type described in the preamble, which according to the invention is connected in the vicinity of the tapping point to a thermally insulated storage vessel and comprises control means for storing water 1013603 2 from that tapping line in that storage vessel and filling that tapping line with cold water immediately after tapping water at the tapping point, and withdrawing water from that storage vessel at the start of a repeated tapping of water at that tapping point.

In a tapping line according to the invention, when the tapping point is opened, hot water is withdrawn from the storage vessel, which then mixes with cold water from the tapping line, and thus mixed hot water flows from the tapping point. With a correct dimensioning of the storage vessel, the amount of hot water therein is sufficient to match the total amount of cold or. cooled water in the tap line to be mixed, and heated water from the water heater reaches the draw-off point even before the storage vessel is completely empty. When the tapping point is closed, the storage vessel is filled with hot water from the tap pipe, and the tap pipe is filled with cold water from a cold water pipe, so that in principle no hot water from the hot water appliance remains in the tap pipe.

In an embodiment of a tap line according to the invention, the storage vessel is provided on its underside with an outflow opening closable by a non-return valve, in which non-return valve an inflow opening is provided.

In this embodiment, the inflow opening preferably has a smaller diameter than the outflow opening.

More preferably, the storage vessel is provided with a pressure-independent flow limiter used as an outflow limiter.

In yet another embodiment, the tapping pipe according to the invention is connected to the storage vessel via a thermally insulating pipe piece.

In an advantageous embodiment, the storage vessel is a stainless steel thermos bottle.

It has been found that the tapping losses in a tapping line according to the invention are in particular minimized if the volume of the storage vessel is approximately twice the volume of the tapping line.

In order to ensure that hot water is immediately available at the tapping point of a tap line 1 01 3603 3 according to the invention, irrespective of the time of the previous tapping, the storage vessel is preferably provided with a heating element.

In an embodiment of a tap pipe according to the invention in which the hot water appliance is a geyser, the control means are chosen such that water is stored from the tap pipe in the storage vessel at a flow rate which is so low that the burner of the 10 tap line connected geyser is not activated, so the geyser supplies cold water to the tap line.

In an embodiment of a tap line according to the invention in which the hot water appliance comprises a storage vessel, for instance with an electric boiler or a gas boiler, the tap line is connected by means of a switching device placed in the vicinity of the storage vessel below a certain water pressure in that tap line. the storage vessel, and the tap pipe above that particular water pressure is connected to a cold water pipe.

In a preferred embodiment, the switching device comprises a cylinder with an axial inflow opening to the cold water pipe, a lateral inflow opening to a pipe to the storage vessel, a lateral outflow opening to the tap pipe and a slide movable in said cylinder, the lateral outflow opening closer to the axial inflow opening is placed than the lateral inflow opening, and the slider, depending on the pressure in the tap pipe, assumes a rest position between the lateral outflow opening and the lateral inflow opening, wherein the tap pipe is connected to the cold water pipe, or occupies a working position between the lateral outflow opening and the axial inlet opening, where the tapping line is connected to the storage vessel.

The invention will be elucidated hereinbelow on the basis of exemplary embodiments with reference to the drawings.

In the drawings show 1013fin 4

Fig. 1 shows a schematic view of a first embodiment of a tap pipe according to the invention,

Fig. 2 is a longitudinal sectional view of a storage vessel for the tapping pipe shown in FIG. 1, FIG. 3 a schematic view of a second embodiment of a tap pipe according to the invention,

Fig. 4 is a longitudinal sectional view of a changeover device for the tapping line shown in FIG. 3.

In the drawings, corresponding parts 10 are designated with the same reference numerals.

Fig. 1 shows a geyser 1 (for example in the attic of a house above a bathroom), which is connected via a short tap pipe 2 to a first tap 3 (for example in that bathroom), and which is connected via a long tap pipe 4 to a second tap 5 (for example in the kitchen of the house). In the vicinity of the second tap 5, an inverted thermos bottle 6 connected by means of a connecting piece 41 to the tap line 4 is placed, with outer bottle 7, vacuum chamber 8 and inner bottle 9, the opening 10 of which is closed by a pierced check valve 11. The thermos flask 6 provides savings on tap losses in the tap line 4 in the following manner. The thermos bottle 6 is approximately 70% (level II) filled with hot water during normal operation of the system. Above the water level there is a compressed volume of air, which is maintained by continuously degassing freshly supplied water. When the tap 5 is opened, the pressure in the tap line 4 drops to approximately 10% of its original value, as a result of which hot water is forced from the thermos bottle 6 into the tap line 4 through the compressed air, where it mixes with that line 4 present cold water. Thus, mixed hot water flows from the tap 5 immediately after opening. The volume of the thermos bottle 6 is chosen such that the amount of hot water stored therein is just enough to mix with the amount of cold water in the tap line 4. Even before the thermos bottle 6 is completely empty, the pressure of the air bubble is equal to the pressure in the tapping line 1013603 5 4, and stops the flow of hot water from the thermos bottle 6, which remains approximately 10% filled with hot water (level I). In this situation, hot water heated by a burner 12 has become available from the geyser 1 to the tap 5. When 5 the tap 5 is closed, the pressure in the tap line 4 increases, and the non-return valve 11 of the thermos bottle 6 is closed. Hot water flows from the tap pipe 4 through the bore in the non-return valve 4 into the thermos bottle 6, with such a low flow rate that the burner 12 of the geyser 1 is switched off, 10 and the tap pipe 4 slowly fills with cold supplied via the geyser 1 water from a cold water pipe 23. The water flowing into the thermos bottle 6 rises again to an equilibrium level II, whereby the air bubble is compressed to a pressure equal to the pressure in the tap pipe 4.

The cycle described above is repeated the next time the tap 5 is opened. A tapping pipe 4 provided with a thermos bottle 6 offers the advantage that hot water flows therefrom directly upon opening of the tap 5, which results in a saving of both water and energy compared to taps without a thermos bottle.

Fig. 2 shows the stainless steel thermos 6 of FIG. 1 with the opening facing downward in more detail. The thermos flask 6 can withstand a pressure of 8 bar, the highest occurring pressure in the tap line 4. The opening is closed by a plug 14 sealed with O-ring 13, in which an outflow opening 15 is formed, which is closed by a non-return valve 11, into which an inflow opening 16 has been drilled, the diameter of inflow opening 16 being smaller than that of outflow opening 15. In the inflow opening 16 30 a cleaning pin 17 which is freely movable over certain distances is arranged. In order to prevent heat leakage, the thermos bottle 6 is connected to the connecting piece 41 to the tap pipe 4 via a pipe piece 19 of a thermally insulating plastic material sealed with O-ring 18, using a swivel connection 20. A pressure-independent flow limiter 21 is provided in the swivel connection 20, which provides a constant outflow speed, independent of the pressure in the thermos bottle 6. The figure furthermore shows a low-voltage heating element 22 arranged in the plug 14, with with the aid of which this amount can also be kept at the correct temperature during long-term storage of an amount of water in the thermos bottle 6. It is sufficient to maintain an amount of 1.5 liters of water in a thermos bottle 6 at a temperature of approximately 80 ° C with such an element 22, which is for instance fed by a 6-volt plug transformer with separate windings. with a continuous power supply of approx. 3 Watt, which, including the use of the plug-in transformer, results in an annual consumption of approx. 40 kWh. This consumption is negligible compared to the annual energy savings achieved with the thermos flask.

FIG. 3 shows a boiler 23 with heating element 24 (for example in the attic of a house above a bathroom), which is connected via a short tap line 2 to a first tap 3 (for example in that bathroom), and which is connected via a long tap line 26 with a second 20 tap 5 (for example in the kitchen of the house). In the vicinity of the second tap 5, it is analogous to that shown in FIG.

1 shows an inverted thermos bottle 6 connected to the tap line 4. Unlike the tap line 4 of a geyser 1 (fig. 1), the tap line 26 for an electric or gas-heated boiler 24 is connected to a switching valve 27, which, depending on the pressure therein, connects the tap line 26 to a line 28 to the boiler 24 or the cold water pipe 23. The operation of the thermos 6 has been explained above in the explanation of fig. 1, and will be repeated only as necessary for an understanding. When the tap 5 is opened, the pressure in the tap line 4 drops, as a result of which hot water is forced from the thermos bottle 6 into the tap line 26 by the compressed air, where it mixes with cold water present in that line 26, and if as a result of which the tap line 26 is connected to the boiler 24 by the changeover valve 27. When the tap 5 is closed, the pressure in the tap line 26, 1013603 7 increases and the non-return valve 11 of the thermos bottle 6 is closed. Hot water flows from the tapping line 4 through the bore in the non-return valve 11 into the thermos bottle 6, with such a low flow rate that pressure in the tapping line 26 remains higher than when tap 5 opened 5, as a result of which a switchover takes place in the switching valve 27, and the tap line 26 is connected to the cold water line 23, so that the tap line 26 slowly fills with cold water from that cold water line 23. The hot water flowing into the thermos bottle 6 rises again to equilibrium level II, whereby the air bubble is compressed to a pressure which is equal to the pressure in the tap line 26. The cycle described above is repeated the next time tap tap 5 is opened.

Fig. 4 shows the switching valve of FIG. 3 in more detail in a rest position, with the tap 5 closed and the water in the pipes 28, 26 and 23 coming to a stop. The change-over valve 27 comprises a cylindrical housing 29 with an axial inflow opening 30 to the cold water pipe 23, a lateral inflow opening 31 to the boiler pipe 28, a lateral outflow opening 32 to the tap pipe 26 and a slide 34 displaceable in said cylinder 27, the lateral outflow opening 32 is positioned closer to the axial inflow opening 30 than the lateral inflow opening 31, and the slider 34, depending on the pressure in the tap line 26, assumes a rest position between the lateral outflow opening 32 and the lateral inflow opening 31, the tap line 26 being connected to the cold water pipe 23, or occupies a working position between the lateral outflow opening 26 and the axial inlet opening 30, the tap pipe 26 being connected to the boiler pipe 28, and thus to the boiler 24. The switching takes place by means of a with the slide 34 connected and piston 35 enclosed under pre-pressure of a coil spring 33. If a ve When the pressure is created, it moves to the right against the pressure of the spring 33, as a result of which the slide 34 closes the cold water pipe 23 and releases the connection between the boiler pipe 28 and the tap water pipe 26. The differential pressure 1013603 8 arises as a result of a small constriction 36 in the outlet opening 32. On the left side of the piston 35 there is always the full pressure of the cold water pipe 23, which is admitted via a first internal channel 37, on the right side of the piston 35 always shows the (variable) pressure of the tap water pipe 26, which is admitted via a second internal channel 38. With a small flow through the changeover valve 27, the pressure differences occurring are too small to counteract the piston 35 against the pressure of the spring 33 move to the right 10. A slight pressure difference occurs if the tap 5 is closed again after tapping hot water, and the thermos bottle 6 fills slowly. In this situation, cold water flows from the cold water pipe 23 via the switching valve 27 into the tap pipe 26.

It is noted that the examples described here are intended to illustrate the invention, not to limit it.

For example, embodiments fall within the scope of the appended claims, wherein the discussed switching valve is not realized by a cylinder with piston-slide combination, but by a membrane with a switching valve, for instance in an existing casting of a reducing valve.

1 01 3603

Claims (10)

1. Tap line (4, 26) for transporting water from a water heater (1, 24) to a draw-off point (5), marked. in the vicinity of the draw-off point (5) it is connected to a thermally insulated storage vessel (6) and comprises 5 control means (11) for storing water from said tap line (4, 26) in that storage vessel (6) and filling from that tapping line (4, 26) with cold water immediately after tapping water at the tapping point (5), and withdrawing water from that storage vessel (6) at the start of a repeated tapping of water at that tapping point (5 ). 2. Tap line (4, 26) according to claim 1, characterized in that the storage vessel (6) is provided on its underside with an outflow opening (15) which can be closed by a non-return valve (11), in which non-return valve (11) has an inflow opening. (16) is provided. Tap pipe (4, 26) according to claim 2, characterized in that the inflow opening (16) has a smaller diameter than the outflow opening (15). Tap line (4, 26) according to any one of the preceding claims, characterized in that it is connected to the storage vessel (6) via a thermally insulating pipe section (19). Tap line (4, 26) according to any one of the preceding claims, characterized in that the storage vessel (6) is provided with a pressure-independent flow limiter (21) used as an outflow limiter. Tap line (4, 26) according to any one of the preceding claims, characterized in that the storage vessel is a stainless steel thermos (6). Tap line (4, 26) according to any one of the preceding claims, characterized in that the volume of the storage vessel (6) is approximately twice the volume of the tap line (4, 26). Tap line (4, 26) according to any one of the preceding 1013603 claims, characterized in that the storage vessel (6) is provided with a heating element (22). Tap line (26) according to any one of the preceding claims, wherein the hot water appliance comprises a storage vessel (24), characterized in that the tap line (26) is provided by means of a switching device (27 located in the vicinity of the storage vessel (24). below a certain water pressure in that tapping pipe (26) is connected to the storage vessel (24), and above that certain water pressure is connected to a cold water pipe (23). Tap pipe (26) according to claim 9, characterized in that the switching device (27) has a cylinder (29) with an axial inflow opening (30) to the cold water pipe (23), a lateral inflow opening (31) to a pipe (28 ) to the storage vessel (24), includes a lateral outflow opening (32) to the tapping line (26) and a slide (34) movable in that cylinder (29), the lateral outflow opening (32) closer to the axial inflow opening (30 ) is placed than the lateral inflow opening (31), and the slide (34), depending on the pressure in the tap pipe (26), takes a rest position between the lateral outflow opening (32) and the lateral inflow opening (31), the tap pipe (26) is connected to the cold water pipe (23), or occupies a working position between the lateral outflow opening (32) and the axial inlet opening (30), the tapping pipe (26) being connected to the storage vessel (24). 101 3603