AT503732B1 - WATER TREATMENT PLANT FOR A SWIMMING POOL - Google Patents

Description

Austrian Patent Office AT503 732 B1 2009-10-15

Description: [0001] The invention relates to a water treatment plant for swimming pools according to the preamble of claim 1.

Generic water treatment plants are needed in particular in public baths to remove the registered by the visitors contaminants from the bath water. Usually, the water is pumped to circulating through the pool and at least one cleaning device, such as a filter, circulating. If the water treatment plant or parts of it are above the water level, a negative pressure is created when the system is switched off. This suppression can damage the boiler or other parts of the system, which is why automatic ventilators must be installed.

To prevent the idling of the boiler or parts of the system loops are usually mounted after the high points on the maximum height of the high point, which prevent idling. These loops are also equipped with automatic ventilation to avoid lifting effects.

From the aeration of the water cycle follows that when restarting the water treatment plant by switching on the circulating pumps, the air contained in the circulation lines must be displaced again. In other words, the circulation line must be vented again. However, this venting of the lines is only possible if a sufficiently high flow resistance is given in the lines. On the other hand, if the flow resistance is too low, it is not possible to displace the air out of the lines even if the pumping power available is high, since the backpressure required for venting the lines does not build up. It is therefore common that the Filtratseite a higher-standing filter system is throttled behind a possibly existing loop to allow the venting of the line when restarting the circulation pumps.

A disadvantage of this type of design, however, is that the high flow resistance in the circulation lines must be overcome permanently in normal operation after the complete venting of the line. For this purpose, a significant proportion of the pump power is required, so that the result is a high proportion of energy costs wasted unnecessarily.

Based on this prior art, it is therefore an object of the present invention to propose a new water treatment system for swimming pools, with which the pump energy required for operation can be minimized. It is another object of the present invention to propose a method for operating such a water treatment plant with effective use of the pump energy.

This object is achieved by a water treatment plant and a method for operating a water treatment plant according to the teaching of the main claims.

Advantageous embodiments of the invention are the subject of the dependent claims.

The water treatment plant according to the invention is based on the idea that in the circulation line at one point, a throttle element, for example an adjustable flap, is provided. By adjusting the throttle element, the flow resistance in the circulation line, which counteracts the circulating water, can be changed. As a result, it is possible that, depending on the respective operating state of the water treatment plant, the flow resistance in the circulation line is changed. When starting up the water treatment system for venting the circulation line, a high flow resistance is set with the throttle element to displace by pumping the water against this high flow resistance located in the air line. Furthermore, by the adjustability of the throttle element the possibility that after venting the circulation line of the flow resistance of the throttle element is reduced or completely eliminated. Thus, in continuous operation of the water treatment plant, in which the water in the line is pumped circulating, no longer needs to be pumped against an unnecessarily high flow resistance in the throttle element. In continuous operation of the water treatment plant thus the required pump energy use can be minimized.

In what way the throttle element is adjusted, is basically arbitrary. For example, it is conceivable that the throttle element is manually adjusted by the operator to set a high flow resistance, for example, when starting the system and in continuous operation after complete venting of the line a low flow resistance. In order to minimize the operating effort to operate the throttle element, however, it is particularly advantageous if the throttle element can be operated remotely. In this way, the throttle element can be remotely controlled by the operator or by a suitable control or regulating device to the respectively necessary flow resistance.

As briefly shown above, the adjustment of the throttle element is primarily the setting of each optimized flow resistance for venting the circulation line or to reduce the flow resistance after complete venting of the circulation line. It is conceivable, for example, that the throttle element is actuated in a time-controlled manner and, for example, after restarting the circulation pump, a high flow resistance is set for a certain predetermined period of time and then a correspondingly low flow resistance is selected. However, a further optimized use of the pumping power is possible in that a sensor, for example a filling level sensor, is provided in the ventilatable part of the water treatment plant, with which the water level of the ventilatable part of the water treatment plant can be measured. Preferably, this sensor should be located in the highest region of the ventilatable part of the water treatment plant, so that it can be determined by evaluating the measurement signals of the sensor, whether the system is completely vented.

Particularly suitable for fulfilling this function are so-called vibration sensors which emit an oscillation signal and measure the transmission of this oscillation signal in the surrounding medium. Since water and air transmit vibrations in different ways, it can be deduced from these measurement signals whether there is water or air in the pipe.

By transmitting the measurement signal of the sensor to a control or regulating device, the level of the ventilatable part of the system can be monitored and used to control the throttle element. As long as there is still air in the system, the throttle element is adjusted by the control or regulating device such that a sufficiently high flow resistance is present in order to further vent the line. Once the sensor air freedom detected and thus adequate ventilation of the system is displayed, the control or regulating device by pressing the throttle element can reduce the flow resistance or the pump power of the circulation pump can be reduced so that wasted in continuous operation no unnecessary pump power to overcome the flow resistance at the throttle element becomes.

In modern water treatment plants circulating pumps with relatively high pump powers are available, which allow for setting a correspondingly high flow resistance in the circulation line a very fast venting of the ventilatable part of the circulation line. The fast venting is quite desirable. However, too fast a venting of the ventilatable part of the line can also lead to problems, since the abrupt displacement of the air in the line can cause damage to the system. To solve this problem, it is proposed to additionally provide in the ventilatable part of the water treatment plant a pressure sensor with which the air pressure can be measured. By transmitting this measurement signal of the pressure gauge in the ventilatable part of the water treatment plant, the pressure can be monitored by the control or regulating device. If the pressure in the ventilatable part of the line rises unacceptably high, the pumping capacity of the circulating pump is reduced as a function of the measuring signal, so that the pressure is correspondingly limited to a tolerable level.

At which point of the water treatment system, the ventilation elements are arranged, is basically arbitrary. Ventilation elements should preferably be provided on the cleaning device, for example a sand filter, and / or on a downflow section, which is arranged downstream of a riser section (so-called pure water loop). With the combination of such downpipe sections and riser sections, the complete water filling of the circulation line or the cleaning device can be ensured.

The water treatment plant according to the invention is particularly advantageous if the height level of the cleaning device of the water treatment plant or parts thereof is higher than the highest point of the swimming pool. This is for example the case when the filter used as a cleaning device is arranged on the same level as the swimming pool itself. By this type of arrangement, construction costs can be saved to a considerable extent, since an underfloor arrangement of plant components is associated with significant construction measures.

An embodiment of the invention is shown schematically in the drawings and is explained below by way of example.

In the drawings: Fig. 1 shows the piping diagram of a water treatment plant according to the invention in a schematic view; Fig. 2 is a partial section of the line diagram of FIG. 1 in an enlarged view.

In Fig. 1 the wiring diagram of a water treatment plant 01 is shown schematically. The various sections of the circulation line are indicated by solid lines. The electrical connection lines between different functional elements of the water treatment plant 01 are indicated by dashed lines.

The water treatment plant 01 is used for the treatment of water in a swimming pool 02 located 03. The water at the edge of the pool 03 is collected in overflow troughs 04 and passes from there into an overflow basin 05. From the overflow basin 05, the water 03 by means of circulating pumps Withdrawn 06 and 07 and pumped through a supply line 20 in a cleaning device 08, which may be formed, for example, in the manner of a sand filter. The water treatment plant or parts thereof, such. As the cleaning device 08, is located above or only partially above a height level 21, which is defined by the upper edge of the swimming pool 02, so that an underfloor arrangement of the cleaning device 08 is avoided.

To the cleaning device 08 includes, for example, a riser section 09, the upper end is above the uppermost point of the cleaning device 08, so that a complete water filling of the cleaning device 08 is ensured by the riser section 09. The downcomer section 09 is in turn followed by a downcomer section 10 which can also directly follow the water treatment system and through which the water is pumped back into the pool 02 via a return line 11.

In normal operation of the water treatment plant 01 all lines 09, 10, 11 and 20 and the cleaning device 08 are completely filled with water, the water by driving the circulation pumps 06 and 07 through the pool 02, the overflow basin 05 and the cleaning device 08 circulates , As soon as the circulation pumps 06 and 07 are switched off, the parts of the water treatment plant 01 located above the level of the height level 21 are ventilated. For this purpose, ventilation pipes 13 and 14 are provided at the uppermost point of the cleaning device 08 and at the transition 12 between riser section 09 and downcomer section 10. In the ventilation tubes 13 and 14 each ventilation flaps 15 are installed, with which the ventilation tubes 13 and 14 are opened or verschlos- 3/8

Claims (17)

Austrian Patent Office AT503 732B1 2009-10-15 sen. The ventilation flaps 15 are automatically driven and can be controlled by a controller 19. For aerating the water treatment plant 01, the ventilation flaps 13 and 14 are opened so that air from the outside through the ventilation pipes 13 and 14 can flow into the circulation of the water treatment plant and thereby allows the flow of water located in the circulation circulation down. When restarting the water treatment plant 01, the circulation pumps 06 and 07 are turned on again and thereby the water pumped again in the cleaning device 08 and in the riser 09. The ventilation flaps 15 remain open initially, so that the air in the circulation circuit can be displaced through the ventilation pipes 13 and 14 to the outside. In order to have a sufficiently high flow resistance when starting the water treatment plant 01, which allows the displacement of the air in the pipes through the ventilation pipes 13 and 14, a throttle element 16 is installed at the lower end of the downcomer section 10. The throttle element 16 is formed, for example, in the manner of a Drosselstellklappe and is set by driving an automatic actuator by means of the controller 19 to the desired throttle resistance. When starting up the water treatment system 01, the throttle 19 is relatively widely closed by the controller 19, thereby enabling a relatively high flow resistance in the circulation line. By pumping the water through the circulation pumps 06 and 07 against the flow resistance in the throttle element 16, the air is displaced within a short time from the circulation lines. In order to limit the air pressure in the system, in particular in the ventilation tubes 13 and 14, to a permissible level, the air pressure can be measured by means of pressure sensors 17 in the ventilation tubes 13 and 14 and this value is passed to the controller 19. If the pressure during venting in the ventilation tubes 13 and 14 increases unacceptably high because the air in the lines is displaced too quickly, the pumping power of the circulation pumps 06 and 07 is reduced by the controller 19, thereby achieving a pressure reduction. Next is located in the ventilation tubes 13 and 14 each have a sensor 18, with which the queuing of water can be measured. Once the air is displaced from the circulation lines so far that the sensors 18 report the presence of water in the system to the controller 19, then the ventilation flaps 15 are closed by controlling the corresponding servomotors. In addition, the throttle element 16 is adjusted by driving the servo motor so that the flow resistance of the throttle element 16 is reduced, since the high flow resistance in continuous operation of the water treatment plant is not required. In Fig. 2, the ventilation tube 14 is shown enlarged with the ventilation flap 15 incorporated therein, the pressure sensor 17 and the level sensor 18. Further, one recognizes the throttle element 16 formed in the manner of a butterfly valve at the lower end of the downcomer section 10. By rotating the butterfly valve in the throttle element 16, the flow resistance in the downcomer section 10 can be changed in the desired manner. 1. Water treatment plant (01) for a swimming pool (02), wherein the water (03) with at least one circulation pump (06, 07) in a line (09, 10, 11, 12, 20) formed by the swimming pool ( 03) and at least one cleaning device (08) is circulating umpumpbar, and wherein at least a part of the water treatment system (01) after switching off the circulation pump (06, 07) by a venting element (13, 14) is ventilated, characterized in that in at least one Line (10) a throttle element (16) is provided by the adjustment of the flow resistance, which counteracts the circulating water (03) in the conduit (10) is variable. 2. Water treatment plant according to claim 1, characterized in that the Dros- Austrian Patent Office AT503 732 B1 2009-10-15 selelement (16) is remotely operable. 3. Water treatment plant according to claim 1 or 2, characterized in that in the ventilatable part (08, 09, 10, 12, 13, 14) of the water treatment plant (01) at least one sensor, in particular a level sensor (18), is provided with the the water level in at least one ventilatable part (08, 09, 10, 12, 13, 14) of the water treatment plant (01) is measurable. 4. Water treatment plant according to claim 3, characterized in that the sensor, in particular the level sensor (18), in the highest region of the ventilatable parts (08, 09, 10, 12, 13, 14) of the water treatment plant (01) is arranged. 5. Water treatment plant according to claim 3 or 4, characterized in that the sensor, in particular the level sensor (18), is designed in the manner of a vibration sensor with which the different transmission of vibrations in air and water can be detected. 6. Water treatment plant according to one of claims 3 to 5, characterized in that a control or regulating device (19) is provided, with which the throttle element (16) in response to the measurement signals of the level sensor (18) can be controlled. 7. Water treatment plant according to one of claims 1 to 6, characterized in that in at least one ventilatable part (08, 09, 10, 12, 13, 14) of the water treatment plant (01) at least one pressure sensor (17) is provided, with the Air pressure in the ventilatable part (08, 09, 10, 12, 13, 14) of the water treatment plant (01) is measurable. 8. Water treatment plant according to claim 7, characterized in that a control or regulating device (19) is provided, with which the pumping power of the circulation pump (06, 07) and / or the position of the throttle element (16) in dependence of the measuring signals of the pressure sensor ( 17) is controllable. 9. Water treatment plant according to one of claims 1 to 8, characterized in that the cleaning device (08) with a ventilation element (13) can be ventilated and / or vented. 10. Water treatment plant according to one of claims 1 to 9, characterized in that a down-line section (10), which is a riser section (09) downstream, with a ventilation element (14) can be ventilated and / or vented. 11. Water treatment plant according to claim 10, characterized in that the riser section (09) is arranged downstream of the cleaning device. 12. Water treatment plant according to claim 10 or 11, characterized in that the height level of at least a part of the water treatment plant, in particular the height level of the transition (12) between riser section (09) and downcomer section (10), higher than the highest point of the cleaning device (08 ) lies. 13. Water treatment plant according to one of claims 1 to 12, characterized in that the height level of at least part of the water treatment plant, in particular the cleaning device (08), higher than the highest point of the swimming pool (02), in particular that the cleaning device (08) is arranged above a height level (21), which is defined by the upper edge of the swimming pool (02). 14. A method for operating a water treatment plant in particular according to one of claims 1 to 13, characterized in that when venting the water treatment plant (01) the throttle element (16) is set in a position with relatively high flow resistance and after substantially complete venting of the water treatment plant ( 01), the throttle element (16) is set in a position with a relatively low flow resistance. 15. The method according to claim 14, characterized in that the adjustment of the throttle element (16) to a low flow resistance, as soon as a sensor, in particular a level sensor (18) in the ventilated Part (08, 09, 10, 12, 13, 14) of the water treatment plant (01) the queuing of water to the control or regulating device (19) reports. 16. The method according to claim 14 or 15, characterized in that the control or regulating device (19) automatically adjusts the throttle element (16) before starting the venting in the position with a relatively high flow resistance. 17. The method according to any one of claims 14 to 16, characterized in that when venting the water treatment plant (01) of the air pressure in the ventilatable part (08, 09, 10, 12, 13, 14) of the water treatment plant (01) with the pressure sensor (17 ) ü monitored and when a limit value is exceeded, the pump power of the circulation pump (06, 07) is reduced. For this 2 sheets drawings 6/8