DE202004005418U1 - Energy saving water supply for building has the consumer units gravity fed from a high mounted tank which is refilled from a rainwater cistern with a submersible pump - Google Patents

Abstract

An energy saving water supply for a building has a water tank (14) mounted above all the consumer units, which are gravity fed from the tank. A control unit (5) monitors the water level in the tank and refills the tank as and when required from a rainwater cistern lower in the building, e.g. underground. The cistern is fitted with a submersible pump (2) to refill the water tank via a non return valve (3) and a rising duct. When the rainwater level falls below a set level the control system refills the water tank from the mains supply.

Description

The rainwater arrives from the roof of a building via a downpipe, a filter system and feeds into a rainwater storage tank. From there, the water is pumped to the consumers via a pressure line using a pump or a two-pump system. As a rule, a pressure of several bars is generated in the pressure line. The water flows slowly into, for example, commercially available toilet containers, whereby the pumps work against great resistance until the container is filled. In order to ensure a water supply in the event of a lack of rain water, drinking water is either fed into the rain water cistern or drinking water is pumped to the consumers via a separate drinking water reservoir and an associated control using the pump. Here the pump also works against a high resistance until, for example, the conventional toilet bowl is slowly filled. Such or similar systems are described, for example, in the writings DE 202 06 082 U1 or DE 100 15 771 C1 ,

problem

When removing water, e.g. by triggering the toilet flush what very often during the day can happen every time the process of increasing pressure in the line to consumers to a certain pressure value performed. This consumes a lot of electricity and the pumps are subject to high wear.

The generation of noise can also and transmission the pumping process in the basement lead to acoustic disturbances, especially in smaller residential units and family houses.

Neither works in the event of a power failure the rainwater supply or the alternative use of drinking water.

The primary energy consumption of water supply is very long and the lifespan of the pumps is increased by the frequent switching on and reduced working against great resistance.

In Scripture DE 298 14 205 U1 describes the use of regenerative energy sources, such as photovoltaic systems, on the house to operate the pumps. However, this is costly and the primary energy consumption is also very large due to the power generation plant.

Based on the previous description is the object of the invention, a water supply system to create which especially with the simplest design effort reliable and trouble-free can be operated as well as an emergency supply in the event of a power failure has and about the entire use phase has a very low primary energy consumption Has.

She sees the solution to the problem Invention of a water supply system with the features of the preamble of claim 1 and with the further features that the water supply system consists of a rainwater storage tank and a water tank, the one with the tapping points in the building via an unpressurized line is connected, with the water tank above the highest Tapping point is attached and the rainwater by means of a Submersible pump in the rainwater tank via a free inlet in the water tank arrives. If water is required from a tapping point, the water flows due to the hydrostatic pressure from the tapping point in e.g. one Toilet tank. The water tank The invention is dimensioned so that only after e.g. some toilet flushes again refilled must become. This avoids the disadvantage that the pump starts with every use and against big ones Resist the pressure in the line to the tapping points again builds.

Because of the free entry into the water tank guaranteed that's the filling process of the water tank quickly and thanks to the submersible pump in the rainwater cistern with the least possible Energy consumption takes place around a quick and energy-saving enema in the water tank to allow must the water column in the supply line from the submersible pump in the cistern to the water tank in the building remain. This is achieved by opening one towards the water tank check valve immediately after the pump in the cistern into the supply line to water tank is arranged.

Another possibility is that the rainwater storage at the same time as the water tank in the building or located higher. Here the rainwater is affected by the hydrostatic pressure after the Principle of a communicating tube and a suitable locking device, e.g. via an electrically operated valve, in desired Way over initiated a free inlet in the water tank.

If there is a shortage of rainwater, the water tank inside the building Drinking water over fed a free inlet. This ensures that only one relatively small amount of drinking water is replenished.

In the lower area of the water tank in the building is a water reservoir is available, which can be used for e.g. some Toilet flushing is sufficient.

With very high buildings due to the hydrostatic pressure in the sampling line a very greater Pressure. One or more pressure reducers are provided here to be arranged in the sampling line.

The water storage for the rainwater is usually frost-proof in the basement of the building or as a cistern outside the building in the ground. The commercial submersible pump in this memory has one Dry-running protection in the form of a float switch that prevents the pump from starting if the water level is too low.

There is a measuring device in the water tank in the building arranged the information about at least 4 Determine fill levels can and feeds a controller. The top level generates a warning signal because the water level is above normal level and the overflow of the water tank is claimed.

The next lower level is the maximum level, where the filling is normally switched off by rainwater or drinking water.

Is the next lower level reached, the pump in the rainwater storage tank is activated or the electrically controlled valve opened for refilling Rainwater. Is not refilled here because of lack of rainwater the dry run protection of the submersible pump in the cistern starts up prevents or no rainwater from the rainwater storage tank located higher up can continue to run, the water level drops when water is withdrawn until the lowest level is reached becomes. There is a refill here of drinking water in the water tank inside the building.

In the event of a power failure, the refill of Not rainwater or the drinking water feed into the water tank possible. Because of the water reservoir in the lower area of the water tank Water supply system able to provide a water supply through a certain period of time.

Filtering and collecting rainwater as well as storage in the cistern or other water storage takes place inexpensively using commercially available products. The supply line from the rainwater storage tank to the water tank in the building is frost-proof commercially available lines inside the building. This keeps installation costs low.

To illustrate the invention 2 drawings are explained in more detail below:

Drawing 1: Schematic representation the invention with rainwater storage in the ground or basement of the Building.

Drawing 2: Schematic representation another embodiment with rainwater storage tank at the same height as the water tank.

1

Rainwater cistern or container

2

submersible pump

3

check valve

4

float switch

5

control

6

water tank

7

level level

8th

Rain water pipe

9

pressure reducer

11

control drinking water supply

12

control submersible pump

13

outlet

14

water reservoir emergency

15

shut-off valve

Description of drawing 1:

The water supply system, which is shown in drawing 1, consists of a rainwater storage tank 1 a water tank in the building 6 and a controller 5 , The rainwater storage tank 1 is designed as an underground tank or storage in the basement of the building. The water tank 6 is located above the highest tapping point. Via a supply line 8th is the rainwater storage 1 with the water tank 6 connected.

The control 5 determined with that in the water tank 6 existing measuring device 7 the water level. The control activates when the water level drops to a certain level 5 the submersible pump located in the rainwater tank 2 over the line 12 , Is there enough rainwater in the rainwater storage tank? 1 is about the free enema 8th Rain water in the water tank 6 pumped up the measuring device 7 determines the maximum water level and the control 5 the submersible pump 2 off. In order to ensure a quick and energy-saving refill process is in the supply line 8th a check valve 3 arranged so that in the feed line 8th water column is retained.

If there is not enough rainwater, the float switch, which works as a protection against dry running, prevents it 4 the submersible pump 2 the pumping process.

As a result, the level in the water tank drops when water is withdrawn from the tapping point BW 6 up to a next level, which is from the measuring device 7 is recorded. The control activates the drinking water inlet TW via the line 11 up to the maximum fill level.

The water is withdrawn from the water tank via a free outlet 13 , which is connected to all BW tapping points. Due to the hydrostatic pressure in the line 13 water flows automatically. If the distance between the tapping point and the water tank in the building is very large, the pressure limiter is used 9 an overpressure ver avoided.

If there is an emergency, for example if the power fails, it is in the water tank 6 in the lower area a water reservoir 14 available, which can be used without energy.

Description of drawing 2:

The water supply system, which is shown in drawing 1, consists of a rainwater storage tank 1 a water tank in the building 6 and a controller 5 , The rainwater storage tank 1 is designed as a high tank or storage tank in the area of the building's water tank. The water tank 6 is located above the highest tapping point. Via a supply line 8th is the rainwater storage 1 with the water tank 6 connected. The control 5 determined with that in the water tank 6 existing measuring device 7 the water level. The control opens when the water level drops to a certain level 5 that on the line 12 arranged shut-off valve 15 , Is there enough rainwater in the rainwater storage tank? 1 flows through the free inlet 8th Rain water in the water tank 6 until the measuring device 7 determines the maximum water level and the control 5 the shut-off valve 15 closes. To prevent in the water tank 6 Any water that can flow back into the rainwater storage tank is in the supply line 8th a check valve 3 arranged.

If there is not enough rainwater, the shut-off valve is activated 15 although open, no or insufficient rainwater can flow into the water tank. As a result, the level in the water tank drops when water is withdrawn from the tapping point BW 6 up to a next level, which is from the measuring device 7 is recorded. The control activates the drinking water inlet TW via the line 11 until the maximum level is reached.

The water is withdrawn from the water tank via a free outlet 13 , which is connected to all BW tapping points. Due to the hydrostatic pressure in the line 13 water flows automatically. If the distance between the tapping point and the water tank in the building is very large, the pressure limiter is used 9 overpressure avoided.

If there is an emergency, for example if the power fails, it is in the water tank 6 in the lower area a water reservoir 14 available, which can be used without energy.

Claims (7)

Water supply system consisting of a rainwater storage tank and at least one second water tank via a pressure-free supply line is connected to the rainwater storage tank and the one The water level measuring device and the associated control has the Introduces rainwater from the rainwater tank into the water tank controls or feeds drinking water into the water tank if there is a lack of rain, that about an unpressurized sampling line and a free drain that supplies water consumption points. System according to claim 1, characterized in that the water tank in the building above the highest located tapping point is arranged. System according to claim 1, characterized in that the water tank is designed so that a volume of water is used as an emergency supply given is. System according to claim 1, characterized in that the water level measuring device in the water tank is designed such that a volume of water is provided as an emergency supply. System according to claim 1, characterized in that the feeding of rainwater and drinking water into the water tank depends on different levels in Water tank. System according to claim 1, characterized in that a pressure limiter is installed in the sampling line. System according to claim 1, characterized in that a non-return valve in the connecting line between the rainwater storage tank and the water tank is arranged with opening direction to the water tank.