EP2218840B1 - Armature sanitaire dotée d'une commande de joystick - Google Patents
Armature sanitaire dotée d'une commande de joystick Download PDFInfo
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- EP2218840B1 EP2218840B1 EP09002169A EP09002169A EP2218840B1 EP 2218840 B1 EP2218840 B1 EP 2218840B1 EP 09002169 A EP09002169 A EP 09002169A EP 09002169 A EP09002169 A EP 09002169A EP 2218840 B1 EP2218840 B1 EP 2218840B1
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- Prior art keywords
- mixed water
- temperature
- signal
- value
- stored
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 473
- 230000015654 memory Effects 0.000 claims description 45
- 230000006870 function Effects 0.000 claims description 12
- 230000007935 neutral effect Effects 0.000 claims description 8
- 239000003086 colorant Substances 0.000 claims description 2
- 239000000470 constituent Substances 0.000 claims 1
- 230000004044 response Effects 0.000 description 5
- 230000007423 decrease Effects 0.000 description 4
- 238000010276 construction Methods 0.000 description 3
- 238000010079 rubber tapping Methods 0.000 description 3
- 230000002123 temporal effect Effects 0.000 description 3
- 230000001960 triggered effect Effects 0.000 description 3
- 238000006243 chemical reaction Methods 0.000 description 2
- 230000001276 controlling effect Effects 0.000 description 2
- 230000003247 decreasing effect Effects 0.000 description 2
- 238000009428 plumbing Methods 0.000 description 2
- 230000001105 regulatory effect Effects 0.000 description 2
- 230000003111 delayed effect Effects 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
- 238000006073 displacement reaction Methods 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 230000003287 optical effect Effects 0.000 description 1
- 230000011664 signaling Effects 0.000 description 1
Images
Classifications
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03C—DOMESTIC PLUMBING INSTALLATIONS FOR FRESH WATER OR WASTE WATER; SINKS
- E03C1/00—Domestic plumbing installations for fresh water or waste water; Sinks
- E03C1/02—Plumbing installations for fresh water
- E03C1/05—Arrangements of devices on wash-basins, baths, sinks, or the like for remote control of taps
- E03C1/055—Electrical control devices, e.g. with push buttons, control panels or the like
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03C—DOMESTIC PLUMBING INSTALLATIONS FOR FRESH WATER OR WASTE WATER; SINKS
- E03C1/00—Domestic plumbing installations for fresh water or waste water; Sinks
- E03C1/02—Plumbing installations for fresh water
- E03C1/04—Water-basin installations specially adapted to wash-basins or baths
- E03C1/0412—Constructional or functional features of the faucet handle
Definitions
- the present invention relates to a sanitary fitting according to the preamble of patent claim 1.
- valve devices for the outlet of water, especially for the outlet of mixed water mixed with cold water and hot water.
- valve devices In order to be able to set the outflowing water to a certain mixed water flow rate and a certain mixed water temperature, it is known to provide sanitary fittings with valve devices.
- These valve devices or valves which are installed in the valve devices, typically have a cold water connection and a hot water connection on one side and a mixed water outlet on the other side.
- Such valve means may comprise a hydraulic single-lever mixer, such as in WO 2006/098795 disclosed.
- valves that can be controlled by means of an electrical control to open or close them.
- a control signal generator for generating an input signal to the controller can be used, wherein the controller controls the valves due to the input signal accordingly.
- WO 2009/019731 A discloses a device for mixing water and regulating the flow rate of service water in hydraulic systems.
- the apparatus comprises an electronic board or circuits electrically connected to one or more solenoid valves for regulating the flow rate of hot and cold water, the water being delivered to one or more faucets.
- the relative displacement of one or more magnets in relation to one or more magnetic linear and / or rotational sensors of the electronic circuit generates a potential difference.
- the potential difference is correspondingly transmitted to the solenoid valves for full / partial hope of this.
- the sanitary fitting which in WO 2006/098795 discloses a hydraulic single-lever mixer as a valve device to manually adjust the mixed water flow rate and the mixed water temperature.
- an electrically controllable valve is installed, which can be operated in two different modes. In one In manual mode, the valve is open and the mixing water flow rate and mixing water temperature are controlled only by the manually operated single lever mixer. In a second mode, the mixed water flow rate and the mixed water temperature are preset by the manually operable single lever mixer, and the electrically controllable valve may be either fully open or fully closed.
- the controller receives an input signal from a touch or environment sensor when an object (such as a hand) is near the sensor. This input signal causes the controller to send an "on” or “off” flip-flop signal to the valve, which in turn causes the valve to be fully closed or fully opened, and the water flow to be opened or closed accordingly.
- An object of the present invention is to provide a sanitary fitting with a control signal generator, wherein both mixing water temperature and water flow rate can be adjusted by means of the control signal generator and the control signal generator is only electrically connected via an electrical control with the valve device. This allows a fine and differentiated control of the mixed water temperature and mixed water flow rate with various possible, implementable in the electronic control, additional functions.
- the sanitary fitting with the control signal generator according to the present invention has a cold water connection, a hot water connection and a mixed water outlet.
- it is equipped with a valve device. This is connected on the one hand to the hot water connection and the cold water connection and on the other hand to the mixed water outlet.
- the valve device can merge the cold and the hot water to mixed water, which then flows through the mixed water outlet.
- the sanitary fitting includes an electrical control for controlling a valve, wherein the control signal generator can generate an input signal to the controller.
- the valve is an integral part of the valve device and the controller controls, in response to the input signal of the control signal generator, the valve device.
- the mixed water temperature and the mixed water flow rate can be adjusted.
- This design allows a very space-saving design of the control signal transmitter, since it has no direct contact with the water connections and no valve is installed.
- the setting of both the mixed water temperature and the water flow rate by the user is done exclusively by means of the control signal generator.
- the Control signal generator is connected via an electrical control with the valve device, it is possible to program the controller so that in terms of temperature and quantity finely graduated and differentiated mixed water discharge is possible.
- various additional functions can be implemented in the controller, which can be triggered by a corresponding actuation of the control signal generator.
- the input signal includes a water amount plus signal, a water amount minus signal, a temperature plus signal, or a temperature minus signal.
- the controller sends a signal to increase the mixing water flow rate due to the receipt of the water quantity plus signal to the valve device.
- the controller sends a signal for reducing the mixed water flow rate, a signal for increasing the mixed water temperature due to the reception of the temperature plus signal, and a signal due to the receipt of the temperature minus signal to reduce the mixed water temperature.
- This design allows extremely simple operation of the sanitary fitting, which is very intuitive for a user. By this type of signaling and control of the valve device, any mixed water flow rates can be set with any mixing water temperature in a simple manner.
- a temperature memory for storing a mixed water temperature value adjustable by the control signal generator, a mixed water flow memory for storing a current mixed water flow rate, and a timer for storing a time value are incorporated in the controller.
- These memories allow the logic of the controller to be extended over the simpler variant described above by means of various additional functions which can be triggered by a certain type of operation of the control signal generator, as described below.
- the mixed water flow memory and the temperature memory allow the realization of a controller, which allows a proportional control means of pulse-like input signals from the control signal generator.
- the timer serves to compare the duration of the input signal and the time sequence of the input signals with the specifications implemented in the controller. As a result, it is only possible to distinguish a longer input signal from a pulse-like input signal or to evaluate the temporal sequence of pulse-like input signals.
- the controller controls the valve device in such a way that, upon receipt of a constant water quantity plus signal, the mixed water flow rate is continuously increased with at least approximately constant temperature according to the mixed water temperature stored in the temperature reservoir. This allows to increase the amount of mixed water slowly and steadily controlled.
- control signal generator is an electric joystick with an operating lever mounted in a base element.
- the mounting and technical structure of the joystick is described in more detail in the same applicant's commonly assigned patent application entitled “Plumbing Fitting with a Joint” (Representative Reference A18634EP), which expressly refers to the disclosure of this document.
- the actuating lever has an actuating lever end region which can be deflected from its neutral, preferably central rest position into at least two planes which are at least approximately at right angles to one another.
- the base member is provided with at least one sensor to determine the position of the operating lever relative to its neutral rest position and to convert it into the electrical input signal.
- the base element is preferably equipped with a sensor which cooperates with a sensor end of the actuating lever facing away from the actuating lever end region.
- the actuating lever is equipped at its sensor end with a permanent magnet, which cooperates with Hall sensors, which are fixedly mounted with respect to the base element of the joystick.
- a permanent magnet which cooperates with Hall sensors, which are fixedly mounted with respect to the base element of the joystick.
- the controller may preferably control the valve device according to claim 5 such that when receiving a constant water quantity minus signal, the mixed water flow rate, with at least approximately constant mixed water temperature according to the temperature stored in the mixed water temperature value, is continuously reduced. This allows to reduce the amount of mixed water slowly and steadily controlled.
- the controller may preferably control the valve device according to claim 6 such that when receiving a pulse-like amount of water plus signal, the mixed water flow rate, if the current mixed water flow rate according to the Stored mixed water flow storage value is less than a lower Mischwasser spell, preferably 30%, is increased to this lower Mischwasser book, rabbitgrenzwert at least approximately constant mixing water temperature is suddenly increased.
- the controller may preferably control the valve device according to claim 7 such that upon receiving a pulse-like water quantity plus signal, if the current mixed water flow is at the lower Mischigan beflußgrenzwert or between the lower Mischigan notebook, a Mischigan beflußgrenzwert, preferably 80%, the Mischigan bookmolecule is increased to the upper mixing water flow rate at at least approximately constant mixed water temperature. As a result, the mixing water flow can be increased suddenly to a value corresponding to the upper mixing water flow limit value.
- the controller may preferably control the valve device according to claim 8 such that upon receipt of a pulse-like water quantity minus signal, the valve is closed without delay so that the mixed water flow rate reaches zero. As a result, a faster, jump-like outflow stop of the mixed water outflow can be effected.
- the controller may preferably control the valve device according to claim 9 such that when receiving a constant temperature plus signal, if the current mixed water flow is zero, the mixed water temperature value is continuously increased in the temperature memory until the end of the temperature plus signal or until Mixed water temperature has reached an upper temperature limit. This allows to select the mixed water temperature slowly and steadily increasing.
- the controller may preferably control the valve device according to claim 10 such that upon receipt of the constant temperature plus signal, if the current mixed water flow is greater than zero, the mixed water temperature value is continuously increased in the temperature memory until the end of the temperature plus signal or until Mixed water temperature has reached an upper temperature limit. At the same time, the mixed water temperature of the effluent mixed water is adjusted continuously in accordance with the mixed water temperature value, with at least approximately constant mixed water flow rate. This allows the mixing water temperature of the currently flowing mixed water to be increased slowly and steadily in a controlled manner.
- the controller may preferably control the valve device according to claim 11 such that upon receipt of the pulse-like temperature plus signal, if the current mixed water flow rate is zero, the mixed water temperature value in the temperature memory is set to the upper temperature limit. This allows to increase the preset mixed water temperature by leaps and bounds.
- the controller can preferably control the valve device according to claim 12 such that when receiving the pulse-like temperature plus signal, if the current mixed water flow rate is greater than zero, set the mixed water temperature value in the temperature storage to an upper temperature limit and at the same time the mixed water temperature corresponding to the mixed water temperature value at least approximately constant mixed water flow rate is adjusted. This allows to increase the mixed water temperature of the currently flowing mixed water leaps and bounds.
- the controller may preferably control the valve device according to claim 13 such that upon receipt of the constant temperature minus time value, if the current mixed water flow rate is zero, the mixed water temperature value in the temperature memory is continuously reduced until the end of the temperature minus signal or until Mixed water temperature value has reached a lower temperature limit. This makes it possible to select the preset mixed water temperature slowly and continuously decreasing controlled.
- the controller may preferably control the valve device according to claim 14 such that upon receipt of the constant temperature minus signal, if the current mixed water flow rate is greater than zero, the mixed water temperature value in the temperature storage is continuously reduced until the end of the temperature minus signal or until Mixed water temperature value has reached a lower temperature limit. At the same time, the mixed water temperature of the effluent mixed water is corresponding, at approx constant mixing water flow rate, continuously adjusted. This allows to slowly and steadily reduce the mixed water temperature of the currently flowing mixed water.
- the controller may preferably control the valve device according to claim 15 such that upon receipt of the pulse-like temperature-minus signal, if the current mixed water flow rate is zero, the mixed water temperature value in the temperature memory is set to a lower temperature limit. This allows to rapidly reduce the preset mixed water temperature.
- the controller may preferably control the valve device according to claim 16 such that upon receipt of the pulse-like temperature-minus signal, if the current mixed water flow rate is greater than zero, the mixed water temperature value is set to a lower temperature limit. At the same time, the mixed water temperature is adjusted according to the mixed water temperature value with at least approximately constant mixing water flow rate. This allows to suddenly reduce the mixed water temperature of currently flowing mixed water.
- the increase resp. Reduction of the mixed water temperature when receiving a constant, longer temperature plus input signal or a constant, longer temperature minus input signal continuously along a predetermined first temperature control characteristic preferably a linear temperature control characteristic with a predetermined slope (in the case of increase with a positive, in the case of reduction, preferably with a magnitude same, but negative slope).
- a predetermined first temperature control characteristic preferably a linear temperature control characteristic with a predetermined slope (in the case of increase with a positive, in the case of reduction, preferably with a magnitude same, but negative slope).
- the increase resp. Reducing the mixing water flow rate upon receipt of a constant, longer water quantity plus input signal or a constant, longer water quantity minus input signal continuously along a predetermined first water flow control curve preferably a linear water flow control curve with a predetermined slope (in the case of increase with a positive, in the case the reduction preferably with a magnitude same, but negative slope).
- Other curves, which increase or decrease continuously, however, are also conceivable for the temperature
- Reduction of the mixed water temperature abruptly, in practice preferably along a second linear temperature control characteristic with a magnitude much greater slope compared with the slope of the first temperature control characteristic.
- the increase resp. Reducing the amount of mixed water suddenly, in practice, preferably along a second linear water flow control curve with a in terms of amount much greater slope compared to the slope of the first water flow control curve.
- the water flow rate can be varied linearly between 0% and 100% for a pulse-like signal in 0.3 seconds and for a continuous signal in 3 seconds.
- the mixed water temperature can be varied linearly between 0% and 100% in 0.5 seconds for a pulse-like signal and 2 seconds in a continuous signal.
- the lower temperature limit corresponds to the temperature of the cold water, which passes through the cold water connection to the valve device.
- the upper temperature limit value preferably corresponds to the temperature of the warm water which passes through the hot water connection to the valve device.
- one input level in a deflection direction is assigned the input signal water quantity plus signal and in the corresponding counter deflection direction the water quantity minus signal.
- the temperature-plus signal is assigned to the other deflection plane in a deflection direction, and the temperature-minus signal is assigned in the corresponding further counter deflection direction.
- a first valve of the valve device consists of a first Proportional valve, which is connected on its inlet side with the cold water connection and on its outflow side with the mixed water outlet.
- a second valve of the valve device consists of a second proportional valve, which is connected on its inlet side with the hot water connection and on its outflow side with the mixed water outlet.
- the controller controls the first proportional valve with a first electrical control signal and the second proportional valve with a second electrical control signal.
- the first and the second proportional valve are activated in the same way.
- the first proportional valve is closed (respectively opened) by a first percentage amount and the second proportional valve is opened (closed) by a second percentage amount so that the mixed water flow rate always remains constant (at least approximately) (ie, the sum of the percentage Openings of the first proportional valve and the second proportional valve must always remain constant).
- the first and second proportional valves are activated such that both valves are opened either by a first and a second opening value (in the case of increasing the mixing water flow rate) or by a first and a second closing value closed (in the case of a Reducing the mixing water flow rate).
- the opening ratio of the first to the second proportional valve must always remain constant in order to keep the mixed water temperature at an - approximately constant - temperature value.
- a light source preferably a light-emitting diode (LED)
- LED light-emitting diode
- the light-emitting diode is attached to the control signal generator, which can suggest to the user a direct optical relationship between control signal input and mixed water temperature and thus facilitates the operation of the sanitary fitting.
- the temperature minus time value, the temperature plus time value, the water amount minus time value, and the water amount plus time value may have different values. In a preferred embodiment, however, these values are all the same, preferably 0.3 seconds.
- FIG. 1 schematically shows a possible embodiment of a sanitary fitting according to the invention 10.
- the sanitary fitting 10 has a valve device 12 which is connected on one side with a cold water connection 14 and a hot water connection 16 and on the other side with a mixed water outlet 18.
- the mixed water outlet 18 is connected to a water outlet pipe 20.
- the valve device 12 in turn includes at least one valve 22a, 22b as an integral part, wherein in a preferred embodiment in the valve device 12, two proportional valves 24, 26 are integrated.
- the first proportional valve 24 is connected on one side to the cold water connection 14 and on the other side to the mixed water outlet 18, and the second proportional valve 26 is connected on one side to the hot water connection 16 and on the other side connected to the mixed water outlet 18th
- the sanitary fitting 10 has an electrical control 28, which controls the valve device 12 in response to an input signal 30.
- the input signal 30 receives the electric control 28 from a control signal generator 32, preferably from a joystick 34, which includes an operating lever 38 mounted in a base element 36.
- Warehousing and the technical construction of the joystick 34 as well as the spout with the spout 20 are disclosed in detail in the same applicant's commonly assigned patent application entitled "Jointed Plumbing Fitting" (Representative Reference A18634EP).
- the actuating lever 38 includes a Betsch Trentshebelend Scheme 40, which is deflected from its neutral, central rest position in two mutually at least approximately at right angles levels.
- the base element 36 is equipped with at least one sensor 42, which cooperates with a Betreli whyshebelend Scheme 40 remote sensor end 44 of the actuating lever 38 to determine the position of the actuating lever 38 relative to its neutral, central position of rest and convert it into the electrical input signal 30.
- the actuating lever 38 is provided at its sensor end 44 with a permanent magnet 46 which cooperates with Hall sensors 48 which are fixedly mounted with respect to the base member 36 of the joystick 34.
- the mixed water temperature and the mixed water flow rate are adjusted.
- Both the electrical controller 28 and the joystick 34 and the valve device 12 are connected to a power supply 50.
- the actuating lever 38 of the joystick 34, a light source 52 a, more preferably a light emitting diode 54 a, attached, which stores the stored in a temperature memory of the electrical controller 28 mixed water temperature by a corresponding color indicates.
- the or a further light source 52b or light-emitting diode 54b may be mounted at an end of the water outlet pipe 20 facing the valve device in order to illuminate the outflowing mixed water with a color corresponding to the mixed water temperature.
- a light guide 55 from the light source 52b or light emitting diode 54b may be led to a water outlet end of the water outlet tube 20 opposite said end of the water outlet tube 20 within the water outlet tube 20 directing the light to the water outlet end of the water outlet tube 20 conducts and illuminates the mixed water at the exit from the Wasserauslassrohr 20.
- FIG. 2 shows a schematic detail view of the electrical controller 28 and the components to which the controller 28 is connected.
- the controller 28 is connected to the power supply 50. It receives input signals 30, which may consist, for example, of a water quantity plus signal 56, a water quantity minus signal 58, a temperature plus signal 60 or a temperature minus signal 62. These input signals 30 originate from the control signal generator 32 or the integrated sensor 42, for example the Hall sensors 48.
- the controller 28 can supply to the first proportional valve 24 a first electrical control signal 64a and to the second proportional valve 26 a second electrical control signal 64b for increasing or decreasing the water flow send out.
- controller 28 may send to the light source 52a, 52b or light emitting diode 54a, 54b a light control signal 66 to adjust the color of the light, which the light source 52a, 52b or light emitting diode 54a, 54b emits to determine.
- the controller 28 includes a programmable microprocessor.
- a register 67 with multiple register locations 68 is integrated.
- Various values may be stored therein, such as a value for the mixed water temperature in a temperature storage register, a value for the mixed water flow rate in a mixed water flow storage register, or different time values (for example, a water amount minus time value, a water amount plus time value , a temperature minus time value or a temperature plus time value) in a timer register.
- These memory modules allow the logic of the controller 28 and the microprocessor can be expanded with various additional functions, which can be triggered by a certain type of operation of the control signal generator 32.
- FIGS. 3a, 3b and 3c show three different examples of temporal curves of the mixed water temperature in response to different, corresponding input signals 30.
- the generated by appropriate actuation of the control signal generator 32 input signals 30 are located below the horizontal time axis, while on the vertical axis in each case the mixed water temperature is plotted percentage. 0% corresponds to the temperature of the water in the cold water connection and 100% corresponds to the temperature of the water in the hot water connection.
- FIG. 3a is initially constant for about one second, ie continuously, the control signal generator 32 is actuated such that a first temperature-plus signal 70 is generated as an input signal 30 to the controller 28.
- the control signal generator 32 is designed as a joystick 34, for example, in that the actuating lever 38 of the joystick 34 is deflected at its actuating lever end region 40 in one of the at least two deflection planes in a direction which corresponds to the temperature plus direction (the same applies analogously to the examples shown in FIG. 3b and 3c ).
- a second temperature plus signal 72 is pulse-like generated by the control signal generator 32 for about 0.2 seconds 72 as an input signal 30.
- a first temperature-minus signal 74 is constantly generated for approximately 0.7 seconds by actuation of the control signal generator 32 as input signal 30 to the controller 28.
- the control signal generator 32 is designed as a joystick 34, for example in that the actuating lever 38 of the joystick 34 at its Betuschistshebelend Scheme 40 in a direction which corresponds to the temperature-minus direction (and corresponding counter-deflection direction to the deflection, which of the temperature Plus direction corresponds, is) is deflected (the same applies analogously for the examples shown in FIG. 3b and 3c ).
- a second temperature-minus signal 76 is generated in pulses for approximately 0.1 seconds by actuation of the control signal generator 32.
- the controller 28 compares each input signal 30 with a predetermined and stored time value, ie, the temperature plus signal with a temperature -Plus time value and the temperature minus signal with a temperature-minus time value.
- the stored time values are 0.3 seconds. Since the first temperature plus signal 70 of one second duration lasts longer than the stored temperature plus time value of duration, increases starting from the time corresponding to the temperature plus time value of 0.3 seconds and thus for 0.7 seconds, the mixed water temperature value is linearly close to 35%.
- the pulse-like second temperature plus signal 72 which is shorter than the stored temperature plus time value, causes the mixed water temperature value to rise after about 1.3 seconds without lag and within about 0.3 seconds to 100%.
- the mixing water flow rate in the period of 0 to 5 seconds is greater than zero, for example, constant. Accordingly, only the mixed water temperature is changed.
- the changes made in the mixed water temperature value correspond to a mixed water temperature preselection.
- the mixing water flow rate is not stopped (and a positive flow rate signal 56 has been sent to the controller 28 in advance of the described temperature plus and minus temperature signals)
- the proportional valves 24, 26 will also be correspondingly changed with each change in the mixed water temperature the valve device 12 is controlled by the controller 28.
- the first proportional valve 24 and the second proportional valve 26 are actuated in opposite directions, so that the first proportional valve 24 is closed or opened by a first percentage amount, and the second proportional valve 26 is thereby displaced by a second percentage amount opened respectively closed.
- the mixing water flow rate is always kept at least approximately constant (ie, the sum of the percentage openings of the first proportional valve 24 and the second proportional valve 26 must always remain constant).
- the mixed water temperature would have the same temperature value as the last mixed water flowed through. However, in this example, since the water flow rate is not increased within 30 seconds, at the time of 35 seconds, the mixed water temperature value is automatically reset to 0%.
- a fourth temperature plus signal 80 is constantly generated as an input signal 30 to the controller 28 by operation of the control signal generator 32.
- a fifth temperature plus signal 82 is constantly generated by actuation of the control signal generator 32 for about 1.1 seconds.
- a third temperature-minus signal 84 is constantly generated by the control signal generator 32 for about 3.1 seconds.
- the mixing water flow rate is greater than 0 in the period of 0 to 2 seconds.
- the mixed water flow rate becomes 0, so the water flow stops after about 2 seconds (indicated by the dashed line).
- the set mixed water temperature value remains stored for a certain time, preferably of the order of 30 seconds.
- the mixing water flow rate is increased again at the time of about 3 seconds, the effluent mixed water on the previously set and selected mixed water temperature value of 65%.
- the constant, third temperature-minus signal 84 of approximately 1.6 seconds duration, applied 3.3 seconds after the start, causes the percentage value of the Mixed water temperature with the same slope as in the linear increase, but now with a negative sign, delayed by the temperature-minus time value, decreases linearly and thus at the end - about 4.9 seconds after the start - takes the percentage value 0.
- FIGS. 4a and 4b show temporal profiles of the mixed water flow rate in response to input signals 30.
- the input signals 30 are shown below the horizontal time axis, while on the vertical axis in each case the mixed water flow rate is plotted as a percentage.
- Analogous to the temperature control is to be noted that the input signals 30 have a certain lead time between almost 0 and a maximum of 0.3 seconds, during which the controller 28 decides whether a pulse-shaped or a continuous input signal 30 is present. During this lead time, the controller 28 does not change anything on the output side when a continuous input signal 30 is present, while at the end of a pulse-shaped input signal 30, the corresponding output signal is generated immediately.
- a first water quantity plus signal 86 is generated at the beginning for about 0.2 seconds by pulsed actuation of the control signal generator 32 to the electric control 28.
- the control signal generator 32 is designed as a joystick 34, for example, by the actuating lever 38 of the joystick 34 being deflected at its actuating lever end region 40 in a direction in a deflection plane which corresponds to the water quantity plus direction (the same applies analogously for the example shown in FIG. 4b ).
- a second water quantity plus signal 88 is generated in pulses for about 0.2 seconds.
- a first water quantity minus signal 90 is generated in pulses for about 0.2 seconds.
- the control signal generator 32 is designed as a joystick 34, for example, in that the actuating lever 38 of the joystick 34 at its Betchanistshebelend Scheme 40 in a direction which corresponds to the amount of water minus direction (and corresponding Jacobausschides to the deflection, which the Wassermenge- Plus direction corresponds, is) is deflected (the same applies analogously to the example shown in FIG. 4b ).
- the controller 28 compares each input signal 30 with a predetermined and stored time value, ie, the water quantity plus signal 56 with a Water amount plus time value and water amount minus signal 58 with a water amount minus time value.
- the stored time values are 0.3 seconds.
- the pulse-like second water amount plus signal 88 which is also shorter than the stored water amount plus time value, causes the percentage value of the mixed water flow rate, beginning with the end of the water quantity plus signal 88, increases without delay within 0.15 seconds from 30% to an upper mixed water flow limit value of, for example, 80%.
- the pulse-like 0.2 second first water level minus signal 90 after about 2.3 seconds, which is shorter than the stored water amount minus time value, causes the mixed water flow rate to begin delaying from the end of the water amount minus signal 90 within 0.24 seconds is reduced to 0%.
- the mixed water flow rate is changed at the same mixed water temperature.
- the electric controller 28 also controls the proportional valves 24, 26 of the valve device 12.
- the first proportional valve 24 and the second proportional valve 26 are activated such that both valves are opened either by a first and a second opening value (in the case of increasing the mixing water flow rate) or by a first and closed a second closing value (in case of a reduction of the mixed water flow rate).
- the percentage opening ratio of the first proportional valve 24 to the second proportional valve 26 is always kept constant in order to keep the mixed water temperature at an approximately constant temperature value.
- FIG. 4b the same applies analogously to the example in FIG. 4b ,
- FIG. 4b is initially constant by operation of the control signal generator 32 for approximately 1.2 seconds generates a third water quantity plus signal 92.
- a fourth water quantity plus signal 94 is pulsed for about 0.1 seconds and after about 1.9 seconds (and an interruption of about 0.27 seconds) for about 0.35 seconds a constant fifth water quantity plus signal 96 generated.
- a second water quantity minus signal 98 becomes constant for about 1.2 seconds and after 4.2 seconds (after an interruption of about 0.5 seconds) a fifth water quantity minus signal 100 pulses generated for around 0.1 seconds.
- the percentage value of the mixed water flow rate increases within 0.9 seconds with a delay of the duration of the water amount plus time value linear from 0% to approx. 30%.
- the fourth pulsed water amount plus signal 94 (whose signal duration is also shorter than the stored water amount plus time value) causes the water flow percentage to be instantaneous with respect to the end of the water amount plus signal 94 and 30% within 0.15 seconds 80%, according to the upper mixed water flow limit, increases.
- the renewed, fifth water quantity plus signal 96 of about 0.36 seconds duration further increases the mixed water flow rate to about 92%.
- the input signal 30 is no longer compared to a time value, but directly converted and there is therefore no lead time.
- the input signal 30 is implemented immediately.
- the second Water amount minus signal 98 of about 1.2 seconds causes the water flow to decrease linearly to about 62% starting with a delay corresponding to the water amount minus time value.
- the third, pulse-like water amount minus signal 100 causes the mixing water flow rate with respect to the end of the water amount minus signal 100 to be instantaneously lowered to 0% within 0.19 seconds.
- the temperature change, with pulse-type input signals 30, takes place at a speed of 100% in 0.5 seconds and, in the case of continuous input signals 30, at a speed of 100% in 2 seconds, and the change in the water quantity in the case of pulse-type input signals 30 at a speed of 100% in 0.3 seconds and, with continuous input signals 30, at a speed of 100% in 3 seconds.
- speed values can be selected differently by appropriate programming of the controller 28.
- input signals 30 which are less than or equal to the relevant time value are evaluated as pulse-type signals. However, it is also possible to regard only input signals 30 which are smaller than the relevant time value as pulse-like signals.
- the controller 28 may be programmed such that, for example, for the above-described mixed water temperature reset value, not the minimum value but any other value is selected. It is also conceivable that several Intermediate stages, both in the temperature setting as well as the mixed water flow rate, can be preset, which can be selected by pulse-like tapping the control signal generator 32 (for example, when increasing the mixing water flow rate not only 30% and 80%, but for example 30%, 50%, 70 % and 80% and for example not only 100% for the mixed water temperature, but for example 20%, 40% 60% 80% and 100%).
- FIGS. 3a to 3c and 4a and 4b show traces of mixed water temperature and mixing water flow rate as a function of sequential water flow plus, water flow minus, temperature plus or minus temperature input signals. These are generated by the control signal generator 32 or the joystick 34, wherein the actuating lever end region 40 of the joystick 34 can be deflected in two mutually at least approximately perpendicular Auslenkebenen.
- the four input signals can be combined in any order, so that the temperature can be changed, for example with running water, and then the mixing water flow rate can be changed at the newly set temperature value or vice versa.
- control signal generator 32 does not consist of a joystick 34, but, for example, four push buttons, each push button each one of the four input signals (water quantity plus, water quantity minus, temperature plus or minus temperature Signal) is assigned.
- the timer further has the task of detecting the duration of the unaltered mixed water flow by measuring the time during which no more 30 input water flow occurs during a mixed water flow greater than zero. After a certain flow time of a few minutes, the controller 28 automatically sets the flow to zero.
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Claims (20)
- Appareil de robinetterie comprenant un raccord d'eau froide (14), un raccord d'eau chaude (16), une sortie d'eau mélangée (18), un moyen à vanne (12) comprenant une vanne (22a, 22b) en tant que partie intégrante destinée à régler une température d'eau mélangée et un débit d'eau mélangée, qui est relié d'une part au raccord d'eau froide (14) et au raccord d'eau chaude (16) et d'autre part, à la sortie d'eau mélangée (18), une unité de commande électrique (28) destinée à commander la vanne (22a, 22b) et un générateur de signal de commande (32) destiné à générer un signal d'entrée (30) fourni à l'unité de commande (28), dans lequel l'unité de commande (28) commande le moyen à vanne (12) en fonction du signal d'entrée (30) du générateur de signal de commande (32), la température d'eau mélangée et le débit d'eau mélangée étant réglés de telle sorte que le signal d'entrée (30) contienne, en fonction de l'actionnement du générateur de signal de commande (32), un signal d'augmentation de quantité d'eau (56, 86, 88, 92, 94, 96), un signal de diminution de quantité d'eau (58, 90, 98, 100), un signal d'augmentation de température (60, 70, 72, 78, 80, 82) ou un signal de diminution de température (62, 74, 76, 84), et l'unité de commande (28) envoie au moyen à vanne (12) un signal destiné à augmenter le débit d'eau mélangée sur la base de la réception du signal d'augmentation de quantité d'eau (56, 86, 88, 92, 94, 96), envoie au moyen à vanne (12) un signal destiné à diminuer le débit d'eau mélangée sur la base de la réception du signal de diminution de quantité d'eau (58, 90, 98, 100), envoie au moyen à vanne (12) un signal destiné à augmenter la température de l'eau mélangée sur la base de la réception du signal d'augmentation de température (60, 70, 72, 78, 80, 82), et envoie au moyen à vanne (12) un signal destiné à diminuer la température de l'eau mélangée sur la base du signal de diminution de température (62, 74, 76, 84) ; l'unité de commande (28) comporte une mémoire de température destinée à stocker une valeur de température d'eau mélangée réglable au moyen du générateur de signal de commande (32), une mémoire de débit d'eau mélangée destinée à stocker un débit d'eau mélangée courant et un temporisateur ; et l'unité de commande (28), lors de la réception du signal d'augmentation de quantité d'eau (56, 86, 88, 92, 94, 96), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de quantité d'eau stockée dans le temporisateur, et lorsque la durée de signal est supérieure à la valeur d'augmentation de quantité d'eau stockée, commande le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit augmenté en continu, pour une température d'eau mélangée restant au moins sensiblement constante, conformément à la valeur de température d'eau mélangée stockée dans la mémoire de température, jusqu'à la fin du signal d'augmentation de quantité d'eau (56, 92, 96) ou jusqu'en un point dans le temps lors duquel un débit d'eau mélangée maximal admissible, de préférence de 100%, soit atteint.
- Appareil de robinetterie selon la revendication 1, caractérisé en ce qu'après l'augmentation continue du débit d'eau mélangée, le débit d'eau mélangée courant est stocké dans la mémoire de débit d'eau mélangée.
- Appareil de robinetterie selon la revendication 1 ou 2, caractérisé en ce que le générateur de signal de commande (32) comporte une manette (34) comprenant un levier d'actionnement (38) pivotant dans un élément d'embase (36), lequel levier d'actionnement peut être dévié par rapport à sa position de repos neutre par une partie d'extrémité (40) du levier d'actionnement dans deux plans orientés au moins sensiblement perpendiculairement l'un à l'autre et en ce que l'élément d'embase (36) est muni d'au moins un capteur (42) permettant de déterminer la position du levier d'actionnement (38) par rapport à son point neutre de repos et à la convertir en le signal d'entrée électrique (30), dans lequel le capteur (42) coopère de préférence avec une extrémité de détection (44) du levier d'actionnement (38) éloignée de la partie d'extrémité (40) du levier d'actionnement.
- Appareil de robinetterie selon la revendication 3, caractérisé en ce que le levier d'actionnement (38) est muni à son extrémité de détection (44) d'un aimant permanent (46) qui coopère avec des capteurs à effet Hall (48) du capteur (42), qui sont montés de manière fixe par rapport à l'élément d'embase (36) de la manette (34).
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 4, caractérisé en ce que l'unité de commande (28), lors de la réception du signal de diminution de quantité d'eau (58, 90, 98, 100), compare la durée de signal de ce dernier à une valeur de temps de diminution de quantité d'eau stockée dans le temporisateur, et lorsque la durée de signal est supérieure à la valeur de diminution de quantité d'eau stockée, commande le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit diminué en continu pour une température d'eau mélangée restant au moins sensiblement constante, conformément à la valeur de température d'eau mélangée stockée dans la mémoire de température jusqu'à la fin du signal de diminution de quantité d'eau (58, 98) ou jusqu'en un point dans le temps lors duquel le débit d'eau mélangée a atteint une valeur nulle, et stocke de préférence le débit d'eau mélangée courant dans la mémoire de débit d'eau mélangée après la diminution continue du débit d'eau mélangée.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 5, caractérisé en ce que l'unité de commande (28), lors de la réception du signal d'augmentation de quantité d'eau (56, 86, 88, 92, 94, 96), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de quantité d'eau respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps d'augmentation de quantité d'eau stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est inférieur à une valeur limite basse du débit d'eau mélangée, de préférence de 30 %, commande le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit augmenté immédiatement afin que la température d'eau mélangée corresponde sensiblement à la valeur de température d'eau mélangée stockée dans la mémoire de température et que le débit d'eau mélangée corresponde à la valeur limite basse du débit d'eau mélangée, et stocke de préférence le débit d'eau mélangée courant dans la mémoire de débit d'eau mélangée à la fin de l'augmentation immédiate du débit d'eau mélangée.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 6, caractérisé en ce que l'unité de commande (28), lors de la réception du signal d'augmentation de quantité d'eau (56, 86, 88, 92, 94, 96), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de quantité d'eau respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps d'augmentation de quantité d'eau stockée et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est supérieur ou égal à la valeur limite basse du débit d'eau mélangée, de préférence de 30 %, et est inférieur à une valeur limite basse du débit d'eau mélangée, de préférence de 80 %, commande le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit augmenté immédiatement afin que la température d'eau mélangée corresponde à la température d'eau mélangée stockée dans la mémoire de température et que le débit d'eau mélangée corresponde au moins sensiblement à la valeur de débit haute, et stocke de préférence le débit d'eau mélangée courant dans la mémoire de débit d'eau mélangée à la fin de l'augmentation immédiate du débit d'eau mélangée.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 7, caractérisé en ce que l'unité de commande (28), lors de la réception du signal de diminution de quantité d'eau (58, 90, 98, 100), compare la durée de signal de ce dernier à une valeur de temps de diminution de quantité d'eau respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps de diminution de quantité d'eau stockée, commande le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit diminué immédiatement afin que le débit d'eau mélangée atteigne une valeur nulle, et à la fin de la diminution immédiate du débit d'eau mélangée, stocke de préférence une valeur nulle dans la mémoire de débit d'eau mélangée pour le débit d'eau mélangée courant.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 8, caractérisé en ce que l'unité de commande (28), lors de la réception du signal d'augmentation de température (60, 70, 72, 78, 80, 82), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de température stockée dans le temporisateur, et lorsque la durée de signal est supérieure à la valeur de temps stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est égal à zéro, augmente en continu la valeur de température d'eau mélangée dans la mémoire de température jusqu'à la fin du signal d'augmentation de température (60, 70, 80, 82) ou jusqu'à ce que la valeur de température d'eau mélangée ait atteint une valeur limite haute de la température, et stocke de préférence la valeur de température d'eau mélangée courante dans la mémoire de température à la fin de l'augmentation continue de la valeur de température d'eau mélangée.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 9, caractérisé en ce que l'unité de commande (28), lors de la réception du signal d'augmentation de température (60, 70, 72, 78, 80, 82), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de température respectivement stockée dans le temporisateur, et lorsque la durée de signal est supérieure à la valeur de temps d'augmentation de température stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est supérieur à zéro, augmente en continu la valeur de température d'eau mélangée dans la mémoire de température jusqu'à la fin du signal d'augmentation de température (60, 70, 80, 82) ou jusqu'à ce que la valeur de température d'eau mélangée ait atteint la valeur limite haute de température, et commande simultanément le moyen à vanne (12) de telle manière que la température d'eau mélangée soit ajustée en continu en correspondance avec la valeur de température d'eau mélangée pour un débit d'eau mélangée restant au moins sensiblement constant, et stocke de préférence la valeur de température d'eau courante dans la mémoire de température à la fin de l'augmentation continue de la valeur de température d'eau mélangée.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 10, caractérisé en ce que l'unité de commande (28), lors de la réception du signal d'augmentation de température (60, 70, 72, 78, 80, 82), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de température respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est égal à zéro, règle la valeur de température d'eau mélangée à une valeur limite haute de la température et la stocke de préférence dans la mémoire de température.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 11, caractérisé en ce que l'unité de commande (28), lors de la réception du signal d'augmentation de température (60, 70, 72, 78, 80, 82), compare la durée de signal de ce dernier à une valeur de temps d'augmentation de température respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps d'augmentation de température stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est supérieur à zéro, règle la valeur de température d'eau mélangée à une valeur limite haute de la température et la stocke de préférence dans la mémoire, et commande le moyen à vanne (12) de telle manière que la température d'eau mélangée soit ajustée en correspondance avec la valeur de température d'eau mélangée pour un débit d'eau mélangée restant au moins sensiblement constant.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 12, caractérisé en ce que l'unité de commande (28), lors de la réception du signal de diminution de température (62, 74, 76, 84), compare la durée de signal de ce dernier à une valeur de temps de diminution de température stockée dans le temporisateur, et lorsque la durée de signal est supérieure à la valeur de temps de diminution de température stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est égal à zéro, diminue en continu la valeur de température d'eau mélangée dans la mémoire de température jusqu'à la fin du signal de diminution de température (62, 74, 84) ou jusqu'à ce que la valeur de température d'eau mélangée ait atteint une valeur limite basse de la température, et à la fin de la diminution continue de la valeur de température d'eau mélangée, stocke de préférence la valeur de température d'eau mélangée courante dans la mémoire de température pendant un temps défini.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 13, caractérisé en ce que l'unité de commande (28), lors de la réception du signal de diminution de température (62, 74, 76, 84), compare la durée de signal de ce dernier à une valeur de temps de diminution de température respectivement stockée dans le temporisateur, et lorsque la durée de signal est supérieure à la valeur de temps stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est supérieur à zéro, diminue en continu la valeur de température d'eau mélangée contenue dans la mémoire de température jusqu'à la fin du signal de diminution de température (62, 74, 84) ou jusqu'à ce que la valeur de température d'eau mélangée ait atteint une valeur limite basse de la température, et commande simultanément le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit ajusté en continu en correspondance avec la valeur de température d'eau mélangée pour un débit d'eau mélangée restant au moins sensiblement constant, et à la fin de la diminution continue de la valeur de température d'eau mélangée, stocke de préférence la valeur de température d'eau mélangée dans la mémoire de température pendant un temps défini.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 14, caractérisé en ce que l'unité de commande (28), lors de la réception du signal de diminution de température (62, 74, 76, 84), compare la durée de signal de ce dernier à une valeur de temps de diminution de température respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps de diminution de température stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est égal à zéro, règle la valeur de température d'eau mélangée à une valeur limite basse de température et la stocke de préférence dans la mémoire de température.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 15, caractérisé en ce que l'unité de commande (28), lors de la réception du signal de diminution de température (62, 74, 76, 84), compare la durée de signal de ce dernier à une valeur de temps de diminution de température respectivement stockée dans le temporisateur, et lorsque la durée de signal est inférieure ou égale à la valeur de temps de diminution de température stockée, et lorsque le débit d'eau mélangée courant, conformément à la valeur stockée dans la mémoire de débit d'eau mélangée, est supérieur à zéro, règle la valeur de température d'eau mélangée à une valeur limite basse de la température et la stocke de préférence dans la mémoire de température, et commande simultanément le moyen à vanne (12) de telle manière que le débit d'eau mélangée soit ajusté en correspondance avec la valeur de température d'eau mélangée pour un débit d'eau mélangée restant au moins sensiblement constant.
- Appareil de robinetterie selon la revendication 3, caractérisé en ce que le signal d'entrée (30), à savoir le signal d'augmentation de quantité d'eau (56, 86, 88, 92, 94, 96) est associé audit un plan de déviation, dans une direction de déviation, et le signal de diminution de quantité d'eau (58, 90, 98, 100) lui est associé dans une direction de déviation opposée correspondante, et le signal d'augmentation de température (60, 70, 72, 78, 80, 82) est associé audit autre plan de déviation, dans une direction de déviation, et le signal de diminution de température (62, 74, 76, 84) lui est associé dans l'autre direction de déviation opposée correspondante.
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 17, caractérisé en ce qu'une première vanne (22a) du moyen à vanne (12) est une première vanne proportionnelle (24) qui est raccordée par son côté d'entrée à un raccord d'eau froide (14) et par son côté de sortie à une sortie d'eau mélangée (18), et en ce qu'une seconde vanne (22b) du moyen à vanne (12) est une seconde vanne proportionnelle (26) qui est raccordée par son côté d'entrée au raccord d'eau chaude (16) et par son côté de sortie à la sortie d'eau mélangée (18), et en ce que l'unité de commande (28) commande la première vanne proportionnelle (24) au moyen d'un premier signal de commande électrique (64a) et la seconde vanne proportionnelle (26) au moyen d'un second signal de commande électrique (64b).
- Appareil de robinetterie selon l'une quelconque des revendications 1 à 18, caractérisé en ce qu'une source de lumière (52a, 52b) émet une lumière de différentes couleurs en fonction de la température d'eau mélangée sélectionnée.
- Appareil de robinetterie selon la revendication 19, caractérisé en ce que la source de lumière (52a, 52b) est appliquée au générateur de signal de commande (32) ou à la conduite de sortie d'eau (20) et est une diode électroluminescente (LED) (54a, 54b).
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ES09002169T ES2395599T3 (es) | 2009-02-17 | 2009-02-17 | Grifería sanitaria con control de mando |
EP09002169A EP2218840B1 (fr) | 2009-02-17 | 2009-02-17 | Armature sanitaire dotée d'une commande de joystick |
US12/707,166 US8534568B2 (en) | 2009-02-17 | 2010-02-17 | Sanitary fitting with a joystick controller |
Applications Claiming Priority (1)
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EP09002169A EP2218840B1 (fr) | 2009-02-17 | 2009-02-17 | Armature sanitaire dotée d'une commande de joystick |
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EP2218840A1 EP2218840A1 (fr) | 2010-08-18 |
EP2218840B1 true EP2218840B1 (fr) | 2012-10-10 |
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EP09002169A Not-in-force EP2218840B1 (fr) | 2009-02-17 | 2009-02-17 | Armature sanitaire dotée d'une commande de joystick |
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EP (1) | EP2218840B1 (fr) |
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-
2009
- 2009-02-17 EP EP09002169A patent/EP2218840B1/fr not_active Not-in-force
- 2009-02-17 ES ES09002169T patent/ES2395599T3/es active Active
-
2010
- 2010-02-17 US US12/707,166 patent/US8534568B2/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN105492809A (zh) * | 2013-06-03 | 2016-04-13 | 奥布拉马提克股份公司 | 用于卫生设备的控制盒 |
CN105492809B (zh) * | 2013-06-03 | 2018-07-20 | 奥布拉马提克股份公司 | 用于卫生设备的控制盒 |
EP3889365A1 (fr) * | 2020-03-30 | 2021-10-06 | Grohe AG | Procédé de fonctionnement d'un robinet mélangeur de thermostat et d'un robinet mélangeur de thermostat |
Also Published As
Publication number | Publication date |
---|---|
US8534568B2 (en) | 2013-09-17 |
EP2218840A1 (fr) | 2010-08-18 |
US20100206956A1 (en) | 2010-08-19 |
ES2395599T3 (es) | 2013-02-13 |
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