NL2014892B1 - Flow-through water reservoir. - Google Patents

Abstract

The invention relates to a flow-through water reservoir (1), suitable for a reserve supply of drinking water, comprising a storage vessel (10), a drain tap (16) and a water admission system (20), wherein the storage vessel has a vessel content (100) with a vessel volume ( 150), a barrel feeding zone (110), a barrel feeding (11) in fluid communication with the barrel feeding zone (110), a standpipe (15) in fluid communication with the barrel contents (100), and a barrel outlet (14) in fluid communication with the standpipe (15), wherein the vessel inlet (11) and the vessel outlet (14) are in fluid communication with the water admission system (20); the water admission system (20) comprises a supply conduit (21), a discharge conduit (22), and a switching element (124), the supply conduit (21) and the discharge conduit (22) being configured to connect the water admission system (20) to a water conduit system (30) so that water from the water supply system (30) can enter the water admission system (20) from the supply line (21) and water from one or more of the container contents (100) and the water admission system (20) can be returned to the water supply system (30) via the discharge line (22) and wherein the switching element (124) further comprises a first configuration whereby a liquid flow is possible between the supply line (21) and the vessel feed (11) and a second configuration wherein a liquid flow between the supply line (21) and the barrel feed (11) is blocked; and the drain valve (16) is in fluid communication with the vessel contents (100).

Description

Area of the invention

The invention relates to an apparatus for temporarily storing an amount of water, a method for providing a reserve supply of drinking water and a method for providing a provision for a reserve supply of drinking water.

BACKGROUND OF THE INVENTION

Systems for constructing or having an emergency supply of water are known. It is often recommended, for example, to keep a supply of bottled water within reach for emergency situations. Flow-through systems are also known which are filled with tap water. For example, US20070262495A1 describes an apparatus and method for inline storage of water during use under pressure. The device comprises a check valve forming a unit with an incoming connection point of the water tank which ensures that water does not flow back through the incoming connection point. The tank is configured with two round end caps connected to a tubular body that provides structure when the device is under pressure. The incoming connection point is connected near the top with the tank to prevent back pressure. An outgoing connection point is also connected to the tank. The above system can be incorporated in the water supply system with which the water is continuously refreshed. A backflow valve can also be included in the supply pipe so that when the water pressure drops, the water cannot flow back via the input to the water supply system.

Summary of the invention

In the event of disruptions in the water supply, it is advisable to keep a supply of drinking water available. 3 liters per person per day are advised by the (Dutch) government. For the also recommended period of 3 days, this is for a person at a small 10 liters. This stock is expected to be used only sporadically and should therefore preferably be replaced (refreshed) regularly. The reservoir according to the invention can therefore in particular be included in a water supply system as a flow-through reservoir, so that during normal operation the reservoir is full of water which is regularly refreshed. The reservoir is therefore in particular included in the water pipe at a location with a sufficient flow, in particular where the contents of the reservoir are refreshed in a maximum of 3 days. For locations where many people can be present, such as a nursing home, a workshop, an office building, a hotel, etc., placement in the (main) water pipeline (in particular for the transport of cold water) in particular appears to be further downstream (multiple) taps to different rooms or devices using water, such as, for example, a water pipe that supplies an entire toilet block with water, suitable for this purpose. In a home, placement for a (dishwasher) washing machine (dishwasher or washing machine), combi boiler or boiler or a toilet dump, or a frequently used kitchen faucet seems suitable for this in most situations. However, other locations may also be suitable as long as the water demand downstream of the flow-through reservoir is sufficient to change the reservoir regularly, preferably once every three days, in particular once or several times a day.

In the event of a malfunction in the water supply system, the (water) pressure often falls away in the water supply, where after the repair of the malfunction and the return of the pressure there is a chance that the water will initially be contaminated, such as rust, but possibly also after major malfunctions. contains sand or other non-drinkable material or even microbial contaminants. The presence of (these) contaminants is not desirable in drinking water and contaminants are therefore preferably excluded from a drinking water supply (vessel). In particular, there is a risk that contamination can accumulate in the vessel if the renewal and / or movement of water in the vessel is (locally) low. These contaminations can also cause blockages or malfunction of mechanical parts if they are not stopped in time. For example, blockages in and / or malfunction of a backflow valve as used in US20070262495 can cause problems in which possible backflow of water is not prevented when the water pressure drops and the storage tank can still be drained in the event of a malfunction (in the water supply). The spontaneous emptying of a storage tank can possibly be prevented by running the supply and discharge of water via the highest point of the water supply. However, this may have adverse consequences for the water change. It is therefore an object of the invention to provide a device for storing an emergency supply of water in which a solution is offered for the disadvantages mentioned. It is also an object of the invention to provide a method for providing an emergency supply of potable water, and a method for providing a facility for storing an emergency supply of drinking water. It is also an object of the invention to provide an adapted water supply system for storing an emergency supply of drinking water.

To this end, the invention provides in a first aspect a flow-through water reservoir, suitable for a reserve supply of drinking water, comprising a storage vessel, a drain tap and a water admission system, wherein (i) the storage vessel has a vessel content with a vessel volume, a vessel feed zone, a vessel feed in fluid communication with the vessel feeding zone, a standpipe in fluid communication with the vessel contents, and a vessel outlet in fluid communication with the standpipe, wherein the vessel inlet and the vessel outlet are in fluid communication with the water admission system, (ii) the water admission system (in particular adapted for admitting of clean drinking water in the storage tank) comprises a supply pipe, a discharge pipe, and a switching element, wherein the supply pipe and the discharge pipe are configured to connect the water admission system to a (in particular cold-water water pipe of a) water pipe system such that (during operation) water from the water supply system the water supply bore system can enter via the supply line and water from one or more of the vessel contents and the water admission system can be returned to the water line system via the discharge line and wherein the switching element further comprises a first configuration whereby a liquid flow is possible between the supply line and the vessel line and a second configuration wherein a liquid flow between the supply line and the vessel feed is blocked, and (iii) the drain valve is in fluid communication with the vessel contents.

The water reservoir is particularly configured to store or contain drinking water (in the storage tank), in particular a minimum of 50 liters of (drinking) water, such as a minimum of 100 liters or a minimum of 500 liters of water. In one embodiment (particularly suitable for private use) the vessel volume is selected from the range of 50 - 100 liters. In another embodiment, the vessel volume is selected from the range of 250-500 liters. In yet another embodiment, particularly suitable for locations where groups of people in general, such as more than 50 people (up to a few hundred people) in emergency situations could use the reserve stock (such as in a care home, a hotel, etc.) .), the vessel volume is selected from the range of 500 - 5000 liters, such as 500 - 2500 liters, in particular 500 - 1000 liters. However, the invention does not preclude smaller vessel volumes being selected at these types of locations. It can thus also be advantageous to use more than one water reservoir with a vessel volume selected, for example from the range of 50-100 liters, in locations where groups of people are generally present. The water reservoir is in particular configured to store or transmit a (supply of) water suitable for (human) consumption. The water reservoir is in particular a flow-through water reservoir. The terms "water reservoir", "reservoir" and "flow-through (water) reservoir" according to the present invention therefore also refer in the description and further explanation of the present invention to the same device, the flow-through water reservoir according to the present invention. Thus, the water supply system is not, in particular, part of the flow-through water reservoir, but the flow-through water reservoir is particularly functionally connected to the water supply system during use (actually providing the reserve water supply system mentioned below). The functional connection between the water supply system and the water reservoir is in particular provided via the water admission system. The water admission system is in particular in fluid communication with the vessel inlet and the vessel outlet and with the water supply system. The water admission system also comprises a switching element, in particular for enabling or not allowing a liquid flow between the supply line and the vessel feed. It will be clear to a person skilled in the art that even if a fluid flow is blocked between the supply line and the vessel feed (in the second configuration of the switching element) there can still be talked about a fluid contact between the supply line and the vessel feed. The term "in fluid contact" is used herein for a contact where a fluid flow can be provided (for both a gas and a liquid), regardless of whether or not this flow can be blocked or blocked.

In a house, the water reservoir can be incorporated particularly advantageously in a water pipe, in particular between a water supply pipe and a water-using device, such as a (dish) washing machine, a boiler or a combi boiler, and a toilet cistern, or a frequently used tap wherein in particular the water supply line is arranged upstream of the water reservoir and the water-using device is arranged downstream of the water reservoir. In one embodiment, the water reservoir is arranged as close as possible upstream of a water-using device. In other locations, especially in locations where under normal circumstances more people are present than in a residential home, such as in a nursing home, a school, an office, a workplace, a hotel, etc., the water reservoir can be particularly advantageous in a (main) ) water pipes of a water pipe system are included upstream of a (large) number of water-using devices to promote the refreshing of the water in the reservoir. It is also possible to include more than one reservoir in a water pipe system at these types of locations. This is possible by including the second and further water reservoir downstream of the first water reservoir, but this may also be advantageous by including the different reservoirs in different water pipes of the water pipe system. Also in a house it can be particularly advantageous to be included in a water line upstream of a number of water-using devices.

In particular, the water reservoir is configured in a water pipe through which so much water regularly flows that the water in the water reservoir is regularly refreshed, in particular the water is substantially completely refreshed at least once every three days. It can therefore be advantageous to configure the water reservoir in a building at a location in a (main) water pipe where the water pipe system enters the building (coming upstream from a water supplier network).

The terms "upstream" and "downstream" are related to a device, in this case the water reservoir, during normal operation. During normal use (not being an emergency) of the water reservoir, as soon as water flows, this water will flow from "upstream" of the water reservoir to "downstream" of the water reservoir through the flow-through water reservoir. This arrangement of the water reservoir relative to the water supply side of the water pipe and a water-using device makes it possible for water to leave the water reservoir via the vessel outlet if water flows through the water pipe (if water is taken by a water-using device) (and) downstream of the water reservoir) and that at the same time (again) fresh water can flow into the water reservoir via the drum feed (and water from the water pipe can flow into the drum through the drum feed).

The water reservoir, in particular the storage vessel, comprises a standpipe which is in fluid communication with the vessel outlet, the standpipe being arranged in particular upstream of the vessel outlet and in fluid communication with the vessel contents. This arrangement (wherein the standpipe is in fluid communication with the vessel contents and with the vessel outlet) allows that if substantially the entire vessel volume comprises water, this water can leave the vessel via the standpipe and the vessel outlet. During normal operation (with sufficient water pressure (such as more than 0.5 bar overpressure) in the water supply system), an amount of water that flows out of the vessel via the vessel outlet will be (can be) replenished via the vessel outlet, whereby a continuous flow of water (through the water reservoir) ) can originate. However, if no water is supplied to the storage vessel (via the vessel feed), but water is requested downstream of the water reservoir and water could leave the vessel, the storage vessel could flow empty. In particular to prevent this, the storage vessel therefore comprises the standpipe, arranged in particular such that during use the water in the storage vessel can only flow out of the vessel if there is a (certain) minimum amount of water present in the vessel and the water is in contact with the output. In particular, the water in the storage tank must then be in fluid communication with the water in the standpipe. When a portion of the vessel is filled with water (a portion of the vessel volume comprises water) then this water will form a water column with a water column axis. The water reservoir is (during use) particularly preferably arranged in the water pipe system such that a longitudinal axis of the standpipe runs substantially parallel to the water column axis. If the water in the standpipe can no longer be supplemented with fresh water (at which time the level of the water column rises to the point where the standpipe is in fluid communication with the vessel content), no more water will be able to leave the storage tank via the water output, whereby the remainder of the water in the storage tank can be retained and can serve as a reserve stock. In one embodiment of the pre-filled vessel, the standpipe is arranged such that a flow of water through the standpipe is only possible if the vessel content comprises at least 50% by volume of the vessel volume of water. In another embodiment, the standpipe is arranged so that that flow is only possible if the vessel content comprises at least 75 volume%, such as at least 80 volume%, such as at least 90 volume% water. In particular, in one embodiment the present invention provides the flow-through water reservoir, wherein the standpipe is arranged such that during (normal) operation a flow of water through the standpipe is only possible if the vessel content is at least 90% by volume (in particular 95 vol.%) Of the vessel volume is filled with water. In yet a further embodiment, the (longitudinal) length of the standpipe in the storage tank is at least 90% of the maximum achievable height of the water column in the storage tank (the height at which, in particular, the entire tank volume comprises water).

The water admission system is particularly configured to allow clean (drinkable, suitable for human consumption) drinking water into the storage tank. After a failure in the water supply, such as the loss of pressure in the water pipe (upstream of the water reservoir), it can happen that when the water supply resumes, the water is temporarily contaminated, for example with rust or other contamination. In the event of a longer malfunction, a microbiological contamination cannot be excluded. Because the purpose of the water reservoir is in particular to store potable water for emergency situations (in which (clean) drinking water can no longer be tapped from the water pipe), it is not desirable that contaminants can end up in the storage tank. The water reservoir is therefore in particular provided with a water admission system which is adapted to not allow (possibly) contaminated water into the storage tank, in particular water coming from the water supply system upstream of the storage tank. To this end, the water admission system comprises a first configuration and a second configuration, wherein in the second configuration a possible liquid flow between the water pipe system, in particular via the supply pipe, and the vessel feed is blocked. In the first configuration, this water transport is particularly possible. Assuming that the water in the water pipe is not very frequently subject to malfunctions, the water admission system will therefore mainly be in the first configuration and, in particular in special situations, preferably in the second configuration. In many cases, a failure in the water supply system can be noticed quickly because the water does not normally flow out of the water supply system at other locations in the water supply system. In these cases, it may be advantageous to provide the water admission system (if it comprises the first configuration) manually with the second configuration. The invention provides this with an embodiment of the flow-through water reservoir, wherein it is possible to switch manually between the first configuration and the second configuration of the switching element. In one embodiment the switching element comprises a change-over tap, such as a three-way tap. In a further embodiment, this change can be provided by converting a change-over tap, wherein the water in the second configuration of the change-over tap is led directly from the supply line to the discharge line via a bypass line. In the first configuration of the diverter tap, the water can in particular be led directly from the supply line to the vessel feed. It can be changed here if it appears that the pressure in the water supply system has dropped, for example, because no running water is (also) obtained at another water tap point. In a special embodiment, this signaling can also be based on a pressure sensor provided in the water admission system, in particular in the supply line. In another embodiment, a pressure sensor is provided in the water pipe system, in particular in the water pipe upstream of the water reservoir. In addition, it can be particularly advantageous to configure the switching element in the second configuration if it is known that the pressure will be taken from the water supply system, for example by work of a water supply company, but also by personal work elsewhere in the water supply system. Additionally or alternatively, the change from the first configuration to the second configuration, and possibly also from the second configuration to the first configuration, but especially from the first configuration to the second configuration, can be automatically provided, for example, by a system coupled to a pressure sensor in the water supply, and / or, for example, a meter that determines the turbidity and / or a meter that determines the conductivity of the water upstream of the water reservoir in the water supply system. In a further embodiment, the flow-through water reservoir is therefore provided, wherein the switching element is configured in the first configuration during normal operation, and wherein a control element is configured to switch the switching element in the second configuration as a function of the pressure in the water supply system configure if a predetermined minimum pressure, in particular a minimum pressure upstream of the water reservoir, is achieved, in particular a pressure lower than 1 bar, such as lower than 0.5 bar (excess pressure with respect to the atmospheric pressure).

Before using the water reservoir, the water reservoir (in particular the water admission system) is arranged in particular in the water supply system such that in the first configuration of the switching element the water flows through the storage tank when a water-using device flows downstream of the water reservoir from this water reservoir and wherein in the second configuration (of the switch element) a possible transport of water to this water-using device (downstream of the water admission system) is in particular not blocked by the water reservoir (in particular is not blocked by the switch element) ( and is led directly to the water-using device via a bypass line, for example). This arrangement makes possible contamination present in the water supply system upstream of the water reservoir to route the water reservoir if the switching element is configured in the second configuration (and water flows through the water supply system's water supply system). However, this arrangement also makes it possible for contamination to be present in the water supply system downstream of the water reservoir. It can therefore be advantageous to incorporate measures that (downstream) water cannot flow into the storage vessel via the vessel outlet, in particular that possible transport of water from the discharge line to the vessel outlet is blocked in particular. In one embodiment of the flow-through water reservoir, the water admission system further comprises a check valve configured to block a liquid flow from the discharge line (from the water line system) to the vessel outlet and to allow a liquid flow from the vessel outlet through the discharge conduit. The term "non-return valve" can also refer to a plurality of, optionally functionally linked, non-return valves.

The water reservoir in particular comprises materials suitable for storing and being in contact with drinking water. Examples of these materials are stainless steel and food grade plastics such as HDPE (high-density polyethylene), PE (polyethylene), PETP (polyethylene terephthalate) PFTE (polytetrafluoroethylene), and ABS (acrylonitrile butadiene styrene).

In particular, the invention provides measures with which the (drinking) quality of the stored water can be maintained for a longer time. As mentioned above, one of the measures is aimed at permitting only clean drinking water. Further embodiments include measures that influence the flow in the storage tank, wherein the flow can ensure good refreshing of the water in the storage tank. The invention provides that the vessel feed is configured on a first side of the storage vessel, in particular on which the first side of the water reservoir is that side where a water column is present, even if the vessel content comprises only a very small amount of water. In particular, the water will flow from the vessel feed in a direction substantially parallel to a longitudinal axis of the water column (formed by the present water) before the water can again leave the storage tank via the standpipe.

In order to promote the renewal of the water in the storage vessel, the standpipe is particularly configured such that the distance between the vessel feed and the standpipe (at the place where the standpipe is in fluid communication with the vessel content) is relatively large. In particular (the standpipe in) the water reservoir is configured such that (after installation of the water reservoir in the water supply system) the height of the water column in the case that no water is supplied to the storage vessel but the water is released from the vessel via the standpipe has been able to flow is at least 90% of the maximum water column height to be realized (the water column where the vessel volume mainly comprises only water). In this way, a large part of the water present in the storage tank will also remain stored in the storage tank if water is used downstream of the water reservoir, while no water can flow into the storage tank via the water inlet, for example due to a malfunction. The water reservoir comprises a standpipe in fluid communication with the water outlet. The invention provides in one embodiment the flow-through water reservoir, wherein the standpipe is arranged such that during operation only a flow of water through the standpipe to the vessel outlet is possible if the vessel content is at least 80% by volume, such as 85% by volume, in particular at least 90% by volume, such as 95% by volume of the vessel volume is filled with water. In particular, the water outlet is not directly (cold) configured on the wall of the storage tank (in particular the highest point of a possible maximum water column in the storage tank) to prevent noise nuisance as much as possible. This noise nuisance (if the water outlet without standpipe would be cold on the wall of the storage vessel) could arise, for example, if a small amount of air is present in the storage vessel and this air is partly entrained by the water leaving the vessel (via the water outlet ) and, for example, partially hangs or flows back into the storage tank.

In one embodiment, the flow-through water reservoir further comprises a turbulence-promoting device which can provide a turbulent flow in the storage tank (when water flows through the water reservoir (in the first configuration)). In particular, a turbulent flow can prevent the water from being refreshed less at certain locations in the storage tank than at other locations. In one embodiment, the turbulence-promoting device comprises a mechanical turbulence-promoting device, in particular driven by running water, such as running water in the standpipe or in the water inlet. In a further embodiment, the turbulence-promoting device comprises an electromechanical turbulence-promoting device such as an electric mixer or stirrer. In one embodiment, the turbulence-promoting device comprises a static mixer. In particular, the turbulence-promoting device is arranged in the drum feeding zone. Therefore, in one embodiment, the invention provides the flow-through water reservoir wherein the vessel feed zone comprises the turbulence-promoting device. In a further advantageous embodiment the barrel feed comprises the turbulence-promoting device. In one embodiment, the (kinetic) energy of the water flowing through the barrel feed is used to drive a mixer. In a further embodiment, the barrel feed is configured to provide a turbulent flow in the barrel feed zone. For this purpose, in one embodiment, the vessel feed is directed, for example, towards the wall of the storage vessel, so that the incoming water flows towards the wall and can, for example, provide a rotating flow in the inlet zone. In a further embodiment, the barrel feed is configured to introduce water turbulent into the storage vessel (the barrel feed zone), for example due to a constriction in the barrel feed. In a further embodiment the barrel feed comprises two or more barrel feeders (as a turbulence-promoting device), wherein the different barrel feeders are configured to together provide a turbulent flow of the incoming water. In a further embodiment, which, like the embodiments described above, can advantageously be combined with one or more of the embodiments described above, the turbulence-promoting device comprises a perforated plate (in particular arranged in the input zone) (comprising perforations) , which is configured to promote turbulence when water flows through the perforations. The barrel feeding zone preferably comprises less than 50% by volume of the vessel volume, in particular less than 30% by volume of the vessel volume. However, in embodiments, in particular in embodiments with more than 1 vial feed, and in particular where the different vial feed are distributed throughout the vial content, the vial feed zone may comprise more than 50% by volume of the vessel volume. In an advantageous installation of the water reservoir and in normal operation, the storage vessel comprises a water column with a height of the water column. In one embodiment, the height of the water column in the inlet zone comprises in particular a maximum of 30% of the maximum height of the water column (in the case of a storage vessel completely filled with water). Therefore, in particular the turbulence-promoting device will mainly be covered with water or be enclosed with water if a maximum of 50% by volume, in particular 30% by volume or less, of the vessel volume is filled with water. have effects on the quality of the water (stored in the storage tank). In a further advantageous embodiment, the flow-through water reservoir is therefore configured to minimize an amount of light that can enter the vessel. In one embodiment, the water reservoir comprises a slightly impermeable coating on the outside. In another embodiment, the inside of the storage vessel comprises a slightly impervious coating. In a further embodiment, the storage vessel is configured from a slightly impermeable material. In yet a further embodiment, the water reservoir further comprises a slightly impervious casing. In yet a further embodiment, the water reservoir comprises a storage vessel, wherein the vessel contents are at least partially enclosed by a vessel wall, the vessel wall being slightly impervious.

In addition, the water is preferably stored in the storage vessel at not too high temperatures. For the incoming water cold water is therefore used in particular. Where in this description and claims the terms "water pipe system" or water pipe is used, particular reference is made to a water pipe system and water pipes for transporting the cold water (connected to the cold water pipe of the water pipe network), in particular water with a temperature in the range of 0-30 ° C, such as 0-25 ° C, in particular 5 - 15 ° C. The water reservoir is therefore preferably arranged in a water pipe where regularly, preferably at least once every three days, and in particular several times a day, a more than average amount, in particular a volume at least equal to the volume of the content, (cold) water flows through. In particular, it may be advantageous to arrange the water reservoir in a water pipe where an amount of water flows through in three days is at least equal to 3 times the vessel volume. In addition, it may be advantageous to take measures so that the water in the storage tank does not heat up quickly. In one embodiment, the water reservoir is provided with an insulating layer, such as a layer of insulating material or a double wall. This embodiment can be particularly advantageous if the water reservoir is arranged in a warm place (in a building). In a further embodiment the flow-through water reservoir is therefore provided, further comprising means for preventing heating of the water in the water reservoir. The water reservoir according to the present invention preferably contains no heating element. The water reservoir in particular also does not comprise a boiler or other heat device, and in particular can also not be used in a method for keeping a liquid warm or warming up.

The water reservoir is particularly suitable for storing water, wherein the water is regularly refreshed with newly supplied water. During normal operation, the water reservoir functions primarily as a buffer for water that flows through the water supply system. The water reservoir is therefore particularly configured for use at (water) pressures at least equal to the water pressure in the water supply system. In particular, the materials of the storage vessel and the dimensions, such as the thickness of the vessel wall, are selected and the construction is designed in such a way that the water reservoir can withstand this working pressure. In particular, the water reservoir is configured for high pressure at locations where the water may be present, such as in the container contents of the storage tank and for an atmospheric pressure on the outside of the water reservoir. This pressure difference can normally be around 1.5 - 2.5 bar, and a maximum of around 5 bar. In an embodiment of the invention, the flow-through water reservoir is configured to store water with a maximum water pressure of 7.5 bar (excess pressure), in particular a maximum water pressure of 5 bar (excess pressure relative to atmospheric pressure). In addition, it may be advantageous to make provisions that ensure that the pressure in the water reservoir does not exceed a predetermined value, such as placing a pressure reducing valve in the supply line. In one embodiment, a reducing valve is therefore placed in the supply line. In a further embodiment the storage vessel comprises a cylindrical shape for providing a sturdy construction and for being able to resist these pressure differences advantageously, in particular a cylindrical shape with two rounded ends. In another embodiment, the storage vessel comprises a substantially spherical shape. These forms are furthermore particularly advantageous for counteracting locations in the storage tank where the water is more difficult to change.

The water reservoir is particularly suitable for emergency situations in which (clean) drinking water can no longer be supplied by the water supply system, such as because upstream of the water reservoir there is a problem with the water supply, for example due to a break in the water supply system (locally or in the public water supply network) which provides the water locally), or such as because the water is contaminated upstream of the water reservoir (for example in the public water supply network). During such an emergency situation, it may be advantageous to be able to use as much as possible of the clean water stored in the storage tank and to be able to drain from the storage tank via the drain tap. In an advantageous embodiment of the flow-water reservoir, the drain valve is therefore arranged in such a way that it is possible to cause substantially all of the water present in the container content to flow out of the storage tank via the drain valve. In an advantageous arrangement of the water reservoir (in the water supply system), this drain valve is then connected in particular to the storage vessel at a location, whereby substantially the entire contents of the storage vessel can be drained. In a further embodiment, the flow-through water reservoir is provided, wherein the drain valve is arranged such that it is possible to allow substantially all of the liquid present in the container content to flow out of the storage tank via the drain valve. In particular, the drain valve will also be located in the input zone.

In a further embodiment, the water reservoir comprises at least one further drain tap. In particular, this embodiment is suitable for an embodiment comprising a large vessel volume, such as larger than 100 liters, or an embodiment (during operation) comprising a width of a water column that is larger than the maximum realizable height of the water column.

In a further embodiment, the drain valve is configured at a height from the lowest point in the vessel content measured along a longitudinal axis of the storage vessel (parallel to a longitudinal axis of a possible water column in the storage vessel) selected in the range of 0 - 10%, in in particular 0-5%, of the maximum height (measured along said longitudinal axis of the storage vessel) from the lowest point in the container contents. In addition, it may be advantageous if the drain valve cannot be opened if the water admission system is configured in the first configuration. In a further embodiment, measures have therefore been taken to prevent the drain valve from being used to drain water if the water admission system comprises the first configuration. For example, the first configuration can mechanically block the opening of the drain valve.

For both the filling of the storage tank (increasing the water column and the amount of water in the container content) and the emptying of the storage tank (such as during draining during emergency situations) it can be advantageous for air to be able to flow into the tank as water flows out of the vessel, or that air can flow out of the vessel and can be expelled by water when the storage vessel is filled. In one embodiment, the flow-through water reservoir further comprises a breather, in particular an automatic breather, in fluid communication with the vessel contents.

In an embodiment (in particular suitable for installation in a residential home) a water reservoir is provided which is light-tight and can easily handle a (water) pressure of at least 3.5 bar, in particular of at least 5 bar. The storage vessel comprises a cylindrical tank and the water reservoir comprises a vessel feed on the underside (the side of the storage vessel which is in contact with water for the longest time as a water column in the vessel decreases in height) which is constructed such that the water with some turbulence storage tank can flow in, thereby stimulating a substantially complete renewal of all water. From the bottom of the stock tank a standpipe (tube) is arranged up to about 3 cm from the top (the side of the tank opposite to the bottom of the tank, viewed from the bottom through an axis of the water column) of the tank. In the normal situation (when there is a normal (water) pressure on (the water pipe of the) water pipe system) this standpipe (pipe) releases the water for use and prevents the tank from draining when the water pressure drops. In one embodiment there is a drain tap on the underside of the storage tank with which the emergency supply can be used. In one embodiment, an (automatic) breather is located at the top of the storage vessel.

As already described above, the storage vessel in particular comprises a shape configured for storing a liquid under pressure, such as a spherical shape or a cylindrical shape. An embodiment of the storage vessel comprising a cylindrical shape in particular further comprises two particularly convex end caps connected to a cylindrical intermediate piece. In a further embodiment the invention comprises the flow-through water reservoir, wherein the storage vessel comprises a cylindrical shape and the vessel volume is in particular selected from the range of 50-100 liters.

In particular, the invention provides the water reservoir for storing 50-100 liters of water with a maximum operating pressure of 5 bar (excess pressure), comprising the standpipe arranged in such a way that during operation only a flow in the standpipe is possible if the vessel content is at least 90% by volume of the vessel volume is filled with water, whereby it is possible to switch at least manually between the first configuration and the second configuration of the water admission system, wherein the water reservoir comprises a turbulence-promoting device, and wherein the drain valve (or the drain valves) arranged in such a way that essentially the entire container content can flow out of the storage tank via the drain valve (or drain valves).

In a second aspect, the invention provides a method for providing a reserve supply of drinking water comprising (i) providing a water pipe from a water pipe system and a flow-through water reservoir as described herein, (ii) providing a first water pipe opening and a second water pipe opening in the water pipe, for example by removing a part of the water pipe, wherein, and (iii) the functional connection of the water supply system to the first water pipe opening and the second water pipe opening, wherein the first water pipe opening and the second water pipe opening are arranged such that water water reservoir can flow in via the vat feed (and water from one or more of the vat contents and the water admission system can be returned to the water piping system via the drain pipe). In an embodiment, the first water pipe opening is connected to the supply pipe with a (first) (flexible) connecting pipe and the second water pipe opening is connected to the discharge pipe via a (second) (flexible) connecting pipe. In an embodiment of the water reservoir according to the present invention, it is particularly suitable for use in a residential home, a small office or, for example, a small public space where usually no more than 10 people are present. In another embodiment, the water reservoir according to the invention is particularly suitable for use in locations where usually more than 10, such as 10-50, or 50 - 100, or even more people are present. In one embodiment of the method, the reserve supply of drinking water is therefore provided in a residential home. In a further embodiment, the reserve supply of drinking water is provided in a small office or a small public space. In yet another embodiment of the method, the emergency supply of drinking water is provided in a larger building such as a hotel or a care home. In particular, the method provides an emergency supply of water in a building.

In a third aspect, the invention provides a method for providing a reserve supply of drinking water comprising providing a water pipe of a water pipe system and a flow-through water reservoir as described herein, functionally connected to the water pipe, and allowing water to flow through the water pipe via the flow-through water reservoir. Here, the supply pipe and the discharge pipe of (the water admission system of) the flow-through water reservoir are functionally coupled to the water pipe, whereby the water can flow into the water reservoir (from the water pipe upstream of the water reservoir) via the vessel feed and the water from the water reservoir (at a filled vessel volume) can be returned via the discharge line to the water line (downstream of the water reservoir). This configuration can be provided, for example, by removing a portion of the water pipe, whereby a first water pipe opening and a second water pipe opening are created, and subsequently the functional connection of the supply pipe with the first water pipe opening and the discharge pipe with the second water pipe opening (both connections configured, for example, with a (flexible) connecting line), wherein the first water line opening and the second water line opening are arranged such that the water from the water line can flow into the water reservoir via the vat feed (and water from one or more of the vat contents and the water admission system can be returned to the water pipe through the drain pipe).

In one embodiment of this method, a reserve supply of drinking water is provided in a building. In a further embodiment of this method, a reserve supply of drinking water is provided in a residential home. In a further embodiment of the method, the method provides a reserve supply of drinking water upstream of a water-using device, in particular a (dish) washing machine. In another embodiment of the method, the method becomes a reserve supply of drinking water for, for example, a care home, a hotel or an office. Therefore, in one embodiment, the invention provides the method for providing a reserve supply of drinking water, wherein the flow-through water reservoir is placed upstream of a water-using device, in particular wherein the water-using device comprises a dishwasher or a washing machine.

In a fourth aspect, the invention provides a reserve water supply system in a building comprising a water supply system in which at least one through-flow water reservoir, as described herein, is arranged, which is functionally connected to a water supply system of the water supply system. In a special embodiment, at least one water reservoir is arranged in the water supply system during the construction of the building. In another embodiment, the water supply system comprises a plurality of serially placed flow-through water reservoirs. The term "reserve water supply system" refers in particular to a (normal) water supply system, such as in a home, but (functionally) provided with the flow-through water reservoir described herein.

This can be particularly advantageous when building a large building, such as a school, a hotel, etc. and configuring a water reservoir comprising a large vessel volume, in particular a vessel volume of at least 1000 liters. However, in other buildings, such as a house, it can be advantageous to arrange a water reservoir directly in the water pipe system when building the building

The terms "substantially" and "substantial" herein will be understood by those skilled in the art. The terms "substantially" and "substantial" may also include embodiments with "whole", "full", "all", etc. Therefore, in embodiments, the terms "substantially" and "substantial" can also be deleted. Where applicable, the terms "substantially" and "substantial" may also refer to 90% or higher, such as 95% or higher, in particular 99% or more, even more particularly 99.5% or more, including 100%. The term "includes" also includes embodiments in which the term "includes" means "includes" or "exists."

In addition, the terms first, second, third and the like in the description and in the claims are used for the distinction between possibly similar elements and not necessarily for describing a sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate conditions and the embodiments of the invention described herein may optionally work in sequences other than described or illustrated herein.

The devices in this document are described during use, among other things. As will be apparent to those skilled in the art, the invention is not limited to methods or devices in operation / in use.

It should be noted that the embodiments described herein illustrate the invention more than limit and that those skilled in the art can design (many) alternative embodiments without departing from the scope of the appended claims. In the claims, references in parentheses should not be interpreted as limiting the claims.

The use of the verb "to include" and the conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article "a" preceding an element does not exclude the presence of a plurality of such elements.

The invention can be implemented by means of hardware comprising various individual elements, and by means of a suitably programmed computer. Different means can be enumerated in the device claim (s), different of these means being designed with the same hardware.

The mere fact that certain measures are described in mutually different subclaims does not indicate that a combination of these measures is not applied with advantage.

The invention further relates to a device or apparatus which comprises one or more of the characterizing measures described in the description and / or represented in the accompanying drawings. The invention further relates to a method or process which comprises one or more of the characteristic features described in the description and / or shown in the accompanying drawings.

It will be clear that the various aspects mentioned in this patent application can be combined and can each qualify separately for a split-off patent application.

Brief description of the figures

Embodiments of the invention will now be described by way of example, with reference to the accompanying schematic drawings in which corresponding reference numerals designate corresponding parts, and in which:

Figures 1a and 1b schematically show a number of aspects of some embodiments of the water reservoir according to the invention;

Figure 2 shows diagrammatically the water reservoir in a water supply system.

The figures are not necessarily to scale. The figures are described in more detail below.

Description of embodiments

In the figures, corresponding parts are designated by the same reference numerals.

Figure 1a shows diagrammatically aspects of the device 1, also referred to as "flow-through water reservoir" or simply "water reservoir", in particular suitable for storing a reserve or emergency supply of drinking water. The device 1 is particularly suitable for storing a reserve supply of water for placement and use in a building, wherein the size of the water reservoir 1 or the vessel volume 150 can be selected depending on the number of people who can use the residual supply of water in case of emergency. For residential houses, this vessel volume may, for example, be 50 - 100 liters, while for a hotel this may have to be at least 1000 liters. The flow-through water reservoir 1 comprises a storage tank 10, a drain valve 16 and a water admission system 20 and often also an automatic air vent 18. The water admission system 20 is in particular configured to let clean water enter the storage tank 10 if it is connected to (a cold water pipe) 31 of a water pipe system 30 (see figure 2). The drain valve (or drain valves, see also Figure 2) 16 is (are) preferably connected at a low point to the storage vessel 10, so that as much of the water present in the vessel as possible can flow out of the vessel via the drain valve 16 in emergency situations. . This also offers the possibility of being able to flush the storage vessel 10 properly in the unlikely event that a contamination or other irregularity has ended up in it. In the embodiment shown, this drain valve is connected to the storage vessel 10 at the lowest point of the storage vessel 10. The drain valve 16 is preferably at a height (relative to the lowest point of the storage vessel 10) between 0 and 10% of the maximum height of the storage vessel 10 (the height being measured along a longitudinal axis of a water column in the vessel ).

During normal operation, water flows into the storage vessel 10 via a water inlet 17, whereafter the water can leave the vessel 10 via standpipe 15. The standpipe is particularly configured such that the entire vessel contents 150 can be refreshed as well as possible. In one embodiment, the standpipe 15 is arranged in such a way that during operation only a flow of water through the standpipe 15 is possible if the vessel content 100 is filled with water for at least 90% by volume of the vessel volume 150. It is also advantageous here that in this way, if fresh water cannot flow into the storage tank, the reserve supply of water occupies a minimum of 90% by volume of the container content, because then less than 10% by volume can still leave the tank 10 via the standpipe 15. The standpipe is further particularly configured such that in use the longitudinal axis of the standpipe extends substantially parallel to a longitudinal axis of a water column in the vessel 10. Both the vessel inlet 11 and the vessel outlet 14 are in fluid communication with the water admission system 20. Although these fluid connection, this does not mean that water always flows in and out of the vessel 10 via the water admission system as water flows through the water pipe 31. The water admission system is in particular configured to allow clean water to flow into the storage vessel and in this case in particular comprises a switching element 124 for which can be configured in a first and a second configuration. During normal operation, the switching element 124 is configured in the first configuration whereby the water can flow into the vessel 10 via a supply line 21 and the vessel feed 11. This flow of water through the vessel 10 will take place during normal operation, if the water reservoir is included in a water pipe system 30, when a water flows through the water pipe 31, for example if a water-using device 40 requires water downstream of the water reservoir 1. This water will then be supplied upstream of the water reservoir, flow into the vessel 10 via the supply pipe 21 and the water inlet 11, while water leaves the water reservoir 1 via the standpipe 15, the water outlet 14 and the discharge pipe 22.

In the second configuration, the water flow to the vessel feed 11 is blocked and, in the event of a water demand, the water flows directly from the supply pipe 21 to the discharge pipe 22. It is noted here that both in the first and in the second configuration there is a fluid connection between the supply line 21 and the water inlet 11. The presence of this fluid connection is independent of the fact that the liquid flow from the supply line 21 to the water inlet 11 is blocked in the second configuration.

In the schematic representation of Figure 1, the barrel feed 11 consists of a tube directed towards the vessel wall 105. In other embodiments, the barrel feed 11 comprises a plurality of barrel feeders and these barrel feeders 11 may be configured at different locations in the barrel 10. The storage vessel further comprises an input zone 110. The location (s) and size of this input zone 110 will be highly dependent on the configuration. In the example given in Figure 1a, this input zone 110 here covers approximately the lower 20% by volume of the vessel volume 150. In other embodiments, the input zone can also be present both at the top and at the bottom of the vessel, and the size can also be more than 50% of the vessel volume 150.

Due to the materials and design used in embodiments, the storage vessel 10 can withstand a water pressure of at least 5 bar excess pressure. The embodiment shown comprises a storage vessel 10 with a cylindrical shape. The invention provides that the shape can also be configured differently. Depending, for example, on the future placement of the water reservoir 1, a rectangular shape, or a square shape, or a different shape may also be advantageous. Both to prevent locations in the vessel where the water is not refreshed as well as for robustness, precisely shaping without (blind) corners can be advantageous.

Figure 1b shows an embodiment of the water admission system 20 in which switching from a first configuration to a second configuration is made possible by a switching element 124 comprising a switch tap, in particular one configured as a three-way valve 24 and a bypass line 23. In the first configuration, as shown in Fig. 1b, transport is possible from the supply line 21 to the water inlet 11, through which water can flow into the vessel 10. In the second configuration (see dotted line), this direction is blocked for the water and the water can only flow directly from the supply line 21 to the discharge line 22. In this embodiment, the three-way valve 24 will have to be converted for this purpose, whereby the transport of water into the second configuration of the switching element 124 will run via the bypass line 23. This second configuration can be used in the event of a malfunction or at other times to ensure that only clean water can get into the storage tank. Switching between the first configuration and the second configuration can be performed manually in embodiments, but the invention also provides that this change can be performed automatically. For example, when the water pressure in the water pipe system 30 or other deviant behavior in the water pipe system 30 is signaled, the switching element 124 can be detected by a control element 37 (see Figure 2) of the first configuration in the second configuration. configures. In the water admission system 20, a non-return valve 25 is also schematically shown configured to block a liquid flow from the discharge conduit 22 to the vessel outlet 14 and to allow a liquid flow from the vessel outlet 14 through the discharge conduit 22 so that the water does not pass through the discharge line 22 (or the bypass line 23) can still flow into the vessel 10.

The invention provides for several measures to promote the drinking quality of the stored water in the water reservoir 1, inter alia by filling the device with cold water, the water supply system 20 which blocks contaminated water, installing at locations with sufficient water demand, a large distance between water flowing in and out, so that the water flows through vessel 1 as much as possible, etc. In addition, embodiments are provided in which one or more turbulence-promoting device (s) 17 are configured, in particular for turbulent flow in the storage vessel 10 to provide. Various embodiments of this turbulence-promoting device 17 are provided. For example, it may consist of mixers which, for example, get their energy from the flowing water (such as in the standpipe 15 or the barrel feed 11). It is also possible for the barrel feed 11 to be configured to cause turbulence, for example by causing the water flow from the barrel feed to collide with the vessel wall 105, by a construction in the barrel feed 11, or for example by configuring several barrel feeders to jointly produce a turbulent cause flow. Also, the storage vessel, in particular the drum feeding zone 110, may be provided with a perforated plate 115 for improving the flow of fluid by promoting turbulence when water flows through the perforations 116. Often the turbulence-promoting device 17 will be placed in the input zone 110. However, also placement in other parts of the storage vessel 10 can be advantageous.

In addition, light can have a negative effect on the quality of the water. In particular for locations where that may be a problem, the invention further provides that some embodiments are also provided with at least partially light-impermeable vessel walls 105 enclosing the vessel contents 100. This can be done, for example, by choice of material (matte plastic, steel), but also by applying a coating.

Figure 2 shows schematically a further embodiment of the water reservoir 1 and the connection of a water reservoir 1 in a water pipe 31 of a water pipe system 30. The reservoir is in particular upstream of at least one already present water-using device 40, such as a dishwasher or a cistern in a residential home, or just in front of a toilet block 40 or in a main water pipe 31 in a larger building (both a water-using device 40 and a water pipe downstream of the water reservoir 1 are schematically shown in the figure). For installation, a piece is removed from a water pipe 31 (sawn), whereby a first water pipe opening 35 and a second water pipe opening 36 are formed, which are connected, for example with flexible pipes 32, to the supply pipe 21 and the discharge pipe 22 of the water supply system 20. In figure 2 also shows a control element 37 which, if the pressure in the water supply system 30 suddenly drops, can cause the switching element 124 to be configured in the second configuration (shown schematically with the dotted line from control element 37 to switching element 124) so that there is no chance that after recovery of the water supply, contamination enters the vessel 10 because the water is then first guided around the vessel 10. Figure 2 also shows a second drain valve 16, which can be particularly advantageous in a wide storage vessel as shown in Figure 2. Figure 2 also shows diagrammatically a part of a reserve water supply system in a building according to the invention comprising in this case a water supply system with a through-flow water reservoir. Particularly during the construction of the building or a renovation of the building, the reserve water supply system can be configured in an advantageous manner. The flow-through reservoir is therefore actually integrated in the water pipe 31.

References I flow-water reservoir 10 storage vessel II vessel inlet 14 vessel outlet 15 standpipe 16 drain valve 17 turbulence-promoting device 18 air vent 20 water admission system 21 supply pipe 22 drain pipe 23 bypass pipe 24 diverter valve 25 non-return valve 30 water pipe system 31 water pipe 32 (flexible) connection pipe 35 first water inlet opening 36 second water pipe opening 37 control element 40 water-using device 100 vessel contents 105 vessel wall 110 vessel feeding zone 115 perforated plate 116 perforation 124 switching element 150 vessel volume

Claims (20)

A flow-through water reservoir (1), suitable for a reserve supply of drinking water, comprising a storage vessel (10), a drain tap (16) and a water admission system (20), wherein the storage vessel has a vessel content (100) with a vessel volume (150), a barrel feeding zone (110), a barrel feeding (11) in fluid communication with the barrel feeding zone (110), a standpipe (15) in fluid communication with the barrel contents (100), and a barrel outlet (14) in fluid communication with the barrel (15) ), wherein the vessel inlet (11) and the vessel outlet (14) are in fluid communication with the water admission system (20); the water admission system (20) comprises a supply line (21), a discharge line (22), and a switching element (124), wherein the supply line (21) and the discharge line (22) are configured to connect the water admission system (20) to a water supply system (30) so that water from the water supply system (30) can enter the water admission system (20) via the supply line (21) and water from one or more of the vessel contents (100) and the water admission system (20) can be returned to the water supply system ( 30) via the discharge line (22) and wherein the switching element (124) further comprises a first configuration in which a liquid flow is possible between the supply line (21) and the vessel feed (11) and a second configuration in which a liquid flow between the supply line (21) and the vessel feed (11) are blocked; and the drain valve (16) is in fluid communication with the vessel contents (100). The flow-through water reservoir according to claim 1, wherein manual switching between the first configuration and the second configuration of the switching element (124) is possible. The flow-through water reservoir (1) according to one or more of the preceding claims 1-2, wherein the switching element (124) is configured in the first configuration during normal operation, and wherein a control element (37) is configured to as a function of the pressure in the water supply system (30), configure the switching element (124) in the second configuration if a predetermined minimum pressure is reached. The flow-through water reservoir (1) according to one or more of the preceding claims 1-3, wherein the switching element (124) comprises a switch tap (24). The flow-through water reservoir (1) according to one or more of claims 1-4, wherein the water admission system (20) further comprises a non-return valve (25) configured to direct a liquid flow from the discharge line (22) to the vessel outlet (14). ) and allow a liquid flow from the vessel outlet (14) through the discharge conduit (22). The flow-through water reservoir (1) according to one or more of claims 1 to 5, wherein the drain valve (16) is arranged such that it is possible to discharge substantially all of the liquid present in the container contents (100) from the storage tank (10). let flow through the drain valve (16). The flow-through water reservoir (1) according to one or more of claims 1-6, wherein the standpipe (15) is arranged such that during operation only a flow of water through the standpipe (15) to the vessel outlet (14) is possible if the vessel content (100) is filled with water for at least 90% by volume of the vessel volume (150). The flow-through water reservoir (1) according to one or more of the preceding claims 1-6, wherein the flow-through water reservoir (1) further comprises a turbulence-promoting device (17) configured to provide a turbulent flow in the storage vessel (10) to provide. The flow-through water reservoir (1) according to claim 8, wherein the vessel feeding zone (110) comprises the turbulence-promoting device (17). The flow-through water reservoir (1) according to one or more of claims 8-9, wherein the vessel feed (11) comprises the turbulence-promoting device (17). The flow-through water reservoir (1) according to one or more of claims 8-10, wherein the turbulence-promoting device (17) comprises a perforated plate (115), which is configured to allow water to flow through the perforations (116) ) to promote turbulence. The flow-through water reservoir according to one or more of claims 1 to 11 configured to store water with a maximum water pressure of 5 bar. The flow-through water reservoir according to one or more of claims 1 to 12 further comprising an automatic air vent (18) in fluid communication with the vessel contents (100). The flow-through water reservoir according to one or more of claims 1-13, wherein the storage vessel (10) comprises a cylindrical shape and the vessel volume (150) is selected from the range of 50-100 liters. The flow-through water reservoir according to one or more of claims 1-14, wherein the vessel contents (100) are at least partially enclosed by a vessel wall (105), wherein the vessel wall (105) is slightly impermeable. A method of providing a provision for a reserve supply of drinking water comprising (i) providing a water pipe (31) of a water pipe system (30) and a flow-through water reservoir (1) according to one or more of the preceding claims 1 -15, (ii) providing a first water conduit opening (35) and a second water conduit opening (36) in the water conduit (31), and (iii) operably connecting the water supply system (20) to the first water conduit opening (35) and the second water conduit opening (36), wherein the first water conduit opening (35) and the second water conduit opening (36) are arranged so that water can flow into the water reservoir (10) via the tank feed (11). A method for providing a reserve supply of drinking water comprising (i) providing a water pipe (31) of a water pipe system (30) and a flow-through water reservoir (1) according to one or more of the preceding claims 1-15, functionally connected to the water pipe (31), and (ii) allowing water to flow through the water pipe (31) via the flow-through water reservoir (1). A method according to any one of the preceding claims 16-17, wherein the flow-through water reservoir (1) is placed upstream of a water-using device (40). The method of claim 18, wherein the water-using device (40) comprises a dishwasher or a washing machine. A reserve water supply system in a building comprising a water supply system (30) and at least one flow-through water reservoir (1) according to any of claims 1-15, functionally connected to a water supply line (31) of the water supply system (30). The reserve water supply system according to claim 20, comprising a plurality of serially placed flow-through water reservoirs (1).