초록 ▼

A method for operating a water softening system (1) comprising an automatically adjustable blending means for mixing a blended water flow V(t)blended from a first, softened partial flow V(t)part1soft and a second untreated water partial flow V(t)part2raw and comprisingan electronic control means (11

A method for operating a water softening system (1) comprising an automatically adjustable blending means for mixing a blended water flow V(t)blended from a first, softened partial flow V(t)part1soft and a second untreated water partial flow V(t)part2raw and comprisingan electronic control means (11), wherein the control means (11) readjusts the adjustment position of the blending means by means of one or more experimentally determined instantaneous measured values in such a fashion that the water hardness in the blended water flow V(t)blended is adjusted to a predetermined desired value (SW), is characterized in that the control means (11) ignores at least one of the one or more instantaneous measured values for readjustment of the adjustment position of the blending means in one or more defined operating situations, and instead uses the respectively last corresponding measured value that was valid prior to occurrence of the defined operating situation, or a standard value for the corresponding measured value, which is stored in the electronic control means (11). The inventive method reduces the wear of the automatically adjustable blending means and improves the reliability of the adjustment of the water hardness of the blended water.

대표청구항 ▼

1. A method for operating a water softening blending system comprising: mixing a blended water flow V(t)blended from a first, softened partial flow V(t)part1soft and a second untreated water partial flow V(t)part2raw with an automatically adjustable blender; andreadjusting an adjustment position of

1. A method for operating a water softening blending system comprising: mixing a blended water flow V(t)blended from a first, softened partial flow V(t)part1soft and a second untreated water partial flow V(t)part2raw with an automatically adjustable blender; andreadjusting an adjustment position of the blender with an electronic controller using one or more experimentally determined instantaneous measured values in such a fashion that a water hardness in the blended water flow V(t)blended is adjusted to a predetermined desired value (SW), andwherein the electronic controller ignores at least one of the one or more instantaneous measured values for readjustment of the adjustment position of the blender in one or more defined operating situations of the water softening blending system, and instead uses a respectively last corresponding measured value that was valid prior to occurrence of the defined operating situation, or a standard value for a corresponding measured value, which is stored in the electronic controller,wherein the method comprises a sensor in an untreated water area of the water softening blending system for determining an instantaneous untreated water hardness WHrawinst and at least two flow meters for direct or indirect determination of instantaneous partial flows V(t)part1softinst and V(t)part2rawinst and the electronic controller ignores at least one of the instantaneous measured values WHrawinst,V(t)part1softinst and V(t)part2rawinst for readjustment of the adjustment position of the blending device in the defined operating situations, and instead uses a respectively last corresponding measured value that was valid prior to occurrence of the defined operating situation or a standard value for a corresponding measured value, which is stored in the electronic controller. 2. The method according to claim 1, wherein the sensor is designed as a conductivity sensor, which determines an instantaneous electrical conductivity Lrawinst of the untreated water, that the electronic controller determines the instantaneous untreated water hardness WHrawinst from the determined instantaneous conductivity Lrawinst of the untreated water, and wherein the electronic controller furthermore determines an instantaneous desired ratio of the partial flows V(t)part1soft and V(t)part2raw from the determined instantaneous untreated water hardness WHrawinst by means of which the predetermined desired value (SW) of the water hardness is established in the blended water flow V(t)blended, and wherein the electronic controller readjusts the adjustment position of the blender to the instantaneous desired ratio according to the determined instantaneous partial flows V(t)part1softinst and V(t)part2rawinst. 3. The method according to claim 1 wherein the electronic controller ignores the measured values for the two instantaneous partial flows V(t)part1softinst and V(t)part2rawinst only in combination together. 4. The method according to claim 1 wherein the defined operating situations include times when the ratio between the measured values V(t)part1softinst and V(t)part2rawinst has changed since the last readjustment of the adjustment position of the blending means by less than a relative flow change value, and wherein the relative flow change value is between 2% and 10%. 5. The method according to claim 1 wherein the defined operating situations include the times of regeneration of a softening device. 6. The method according to claim 1 wherein the defined operating situations include falling below a minimum flow rate and/or exceeding a maximum flow rate at a flow meter. 7. The method according to claim 1 wherein the defined operating situations include times when there is a hardness breakthrough at a water softening system supplying the softened partial flow V(t)part1soft. 8. The method according to claim 1 wherein the defined operating situations include times when a leakage is detected at a water softening system supplying the softened partial flow V(t)part1soft, the water softening blending system or any downstream water installation. 9. The method according to claim 1 wherein in at least part of the defined operating situations, the electronic controller completely suspends readjustment of the adjustment position of the blender such that the blended water flow is mixed with the last adjustment position of the blender, which was set prior to occurrence of the defined operating situation. 10. The method according to claim 1 wherein the water softening blending system comprises a conductivity sensor in an untreated water area for determining the instantaneous conductivity of the untreated water Lrawinst, and that the defined operating situations include times when the instantaneous measured value Lrawinst has changed by less than a predefined conductivity difference value since the last readjustment of the adjustment position of the blending means, wherein the conductivity difference value is between 5μS/cm and 50μS/cm. 11. The method according to claim 1 wherein the defined operating situations include times when at least a minimum amount of water has not been continuously flowing through the water softening blending system directly prior to an intended evaluation of one or more of the instantaneous measured values. 12. The method according to claim 1 wherein the defined operating situations include times when water has not been continuously flowing through the water softening blending system for at least a minimum duration directly prior to an intended evaluation of one or more of the instantaneous measured values. 13. The method according to claim 1 wherein the water softening blending system further comprises a supply container for providing regenerant solution and apparatus for automatic performance of regeneration of a softening device, and the electronic controller automatically triggers regeneration of the softening device in dependence on soft water withdrawals performed since a the last regeneration of the softening device. 14. The method according to claim 13, wherein the electronic controller detects a residual capacity of the softening device in dependence on the soft water withdrawals performed since a last triggered regeneration, and on one or more associated determined untreated water hardnesses, and upon depletion thereof, automatically triggers regeneration of the softening device . 15. The method according to claim 14 wherein the water softening blending system comprises a conductivity sensor in the untreated water area, and that an overall hardness I of the untreated water, which hardness is used to control the regeneration process of the softening device is derived from the measured conductivity Lraw by means of a first calibration characteristic (F1), and an overall hardness II of the untreated water, which hardness is used to control the blending means, is derived from the measured conductivity Lraw using a second calibration characteristic (F2). 16. The method according to claim 15, wherein the overall hardness I derived from the first calibration characteristic (F1) is greater, at least in sections, than the overall hardness II derived from the second calibration characteristic (F2). 17. The method according to claim 13 wherein the electronic controller ignores at least one of the one or more instantaneous measured values also for automatic triggering of regeneration of a softening system in one or more defined operating situations, and instead uses a respectively last corresponding measured value that was valid prior to occurrence of the operating situation, or a standard value for a corresponding measured value, which is stored in the electronic controller. 18. A method for operating a water softening blending system comprising: mixing a blended water flow V(t)blended from a first, softened partial flow V(t)part1soft and a second untreated water partial flow V(t)part2raw with an automatically adjustable blender; andreadjusting an adjustment position of the blender with an electronic controller using one or more experimentally determined instantaneous measured values in such a fashion that a water hardness in the blended water flow V(t)blended is adjusted to a predetermined desired value (SW), andwherein the electronic controller ignores at least one of the one or more instantaneous measured values for readjustment of the adjustment position of the blender in one or more defined operating situations of the water softening blending system, and instead uses a respectively last corresponding measured value that was valid prior to occurrence of the defined operating situation, or a standard value for a corresponding measured value, which is stored in the electronic controller,wherein the defined operating situations include times when an experimentally determined instantaneous water hardness, an instantaneous untreated water hardness WHrawinst or an instantaneous blended water hardness WHblendedinst is outside of a predetermined value interval. 19. The method according to claim 18 wherein the defined operating situations include times when the experimentally determined instantaneous water hardness, the instantaneous untreated water hardness WHrawinst or the instantaneous blended water hardness WHblendedinst has changed by less than a predefined hardness difference value since the last readjustment of the adjustment position of the blending means, in particular, wherein the hardness difference value is between 0.2° dH and 2.0° dH. 20. The method according to claim 18, wherein the predetermined value interval ranges from 2° dH to 50° dH. 21. The method according to claim 18, wherein the water softening blending system comprises a sensor in a blended water area of the water softening blending system for determining the instantaneous blended water hardness WHblendedinst, and that the electronic controller ignores at least the instantaneous measured value WHblendedinst for readjustment of the adjustment position of the blender in the defined operating situations, and instead uses the last defined blended water hardness that was valid prior to occurrence of the defined operating situation or a standard value for the blended water hardness, which is stored in the electronic controller.