EP1835067A1 - Ironing device - Google Patents

Abstract

The device has an iron (10) comprising a soleplate (60) with a vapor production assembly (12) having a pump (76) and a water supply tank (40) from which water is pumped and brought along a flexible pipe (78) to a vaporization chamber (66). The chamber has injection points for injecting the water pumped from the tank for vaporizing it. A programmable control unit (30) supplies water to the iron when a temperature of the soleplate is sufficient for evaporation of water. The control unit supplies vapor to the iron when the production assembly reaches a predetermined operating temperature.

Description

The present invention relates to an ironing apparatus of the ironing station type combining the performance of ordinary iron and that of steam stations or other steam systems, in terms of speed of implementation of comfort, use and performance.

• utiliser un fer à repasser à sec très vite prêt, très léger mais obligeant d'utiliser une pattemouille ;
• utiliser un fer à repasser à vapeur, plus lourd et plus lent que le premier, avec une autonomie très limitée et s'entartrant en général rapidement avec l'eau du robinet ;
• utiliser une station vapeur comportant une chaudière de vapeur, produit le plus répandu des stations vapeur. Cette chaudière contient toute l'eau à évaporer et nécessite un temps très long pour amener l'eau à l'ébullition et oblige à un temps d'attente très long pour remplir d'eau froide à nouveau la chaudière et la mettre sous pression. L'efficacité de la vapeur est correcte, le poids du fer est très léger, l'entartrage se faisant au niveau de la chaudière ;
• utiliser une station vapeur comportant une mini chaudière remplissable à tout moment par une pompe haute pression en fonction d'un détecteur de niveau d'eau, comportant peu d'eau à évaporer donc plus rapide à mettre en oeuvre qu'une chaudière, sans attente après et avant remplissage du réservoir, avec un fer léger, le détartrage pouvant être géré au niveau du réservoir d'eau où cela est plus facile.

To carry out his ironing today with the help of an iron the user can either:

• use a dry iron very quickly ready, very light but obliging to use a pattemouille;
• use a steam iron, heavier and slower than the first, with a very limited autonomy and generally scaling quickly with tap water;
• use a steam station with a steam boiler, produces the most widespread steam stations. This boiler contains all the water to evaporate and requires a very long time to bring water to the boil and requires a very long waiting time to refill the boiler with cold water and put it under pressure. The efficiency of the steam is correct, the weight of the iron is very light, scaling is done at the level of the boiler;
• use a steam station with a mini boiler refillable at any time by a high pressure pump according to a water level sensor, with little water to evaporate so faster to implement a boiler, without waiting after and before filling the tank, with a light iron, the descaling can be managed at the water tank where this is easier.

However, the need to iron is to be satisfied in at least two very distinct cases: firstly, when ironing a complete laundry that includes all the washed parts in order to store them in the cabinets. In this case, the iron can be longer to implement because this time is not important compared to the total time needed to iron and more is a work scheduled in the week generally, on the other hand, when ironing the clothes coming out of the cabinets and to be retouched with the iron to redo the folds and make the net net suitable for example to be worn. In this case, the iron must be ready quickly because it is at the last moment that this operation must be done, urgently.

The best equipped users therefore usually have two irons dedicated to these two tasks, a regular iron quickly ready and a steam station for a large ironing capacity. However, they can also use a steam station with an instant steam generator claiming, like a regular iron, only a few minutes to be ready for operation, and having, like any steam station, a great deal of autonomy. The associated iron is also light to handle and scaling without further protection is at the generator which does not present any danger because without pressure unlike a boiler.

This instant generator steam station still has some disadvantages that the present invention proposes to overcome. Indeed, the steam generation is not made in iron, it does not have water and it is therefore not possible to make water spray. In addition, the start of ironing is long when the touching is urgent.

In one of the preferred versions of the invention, the iron alone is heated with the maximum power available on the electrical network and as soon as the required level of predetermined temperature is reached, the water of a separate tank is sent by an independent pump in an independent conduit to be evaporated in the steam chamber of the iron, the vapor being diffused by the sole of the iron. The tank water can be treated against scale or not and controlled or not to verify the effectiveness of water treatment means and indicate whether they should be replaced and when.

Thus, by making the iron heating priority over any other heating element, including the separate steam production system associated with it, boiler or instantaneous generator, it can accelerate the heating of this iron using the maximum power on this iron.

It was set up a treatment of the vaporization chamber of iron on all sides and its lid with a product facilitating evaporation.

Several water injection points were also installed in the soleplate to better utilize the calories stored in the heated material and distribute the scale deposited during evaporation by multiplying these evaporation zones.

It has also been set up a program of operation of the pump allowing initially to maximize the flow to quickly fill the connecting duct between the pump and the separate tank and the steam chamber of the iron and then inject the maximum l water that can be evaporated in the iron vaporization chamber in connection with the available installed power to perform this function.

Similarly, by installing a non-return valve at the entrance of the vaporization chamber to not empty the water pipe between two maneuvers because evaporation and evacuation of the vapor from the evaporation zone iron can create a depression that can suck the water contained in this pipe at the same time requiring a filling time again more or less long but in any case harmful to the user who will have to wait to benefit from the steam when he controls its production.

In a preferred version of the invention as soon as, as before, the programmed temperature of the sole of the iron is reached, the heating of the boiler or the generator, also at maximum power, can be started alternately with the heating of the boiler. iron remains a priority, the alternation signifier or one or the other of the two steam system heats but never both at the same time, when the maximum power of the network is used to equip them.

As the passage of heating from one of the two systems to the other is pre-programmed, the passage of the vaporization of the water into the vaporisation chamber of the iron or into the steam generating unit or both, may also be controlled, the user setting his choice by a control button actuating one or the other or both systems.

In the case where the system with steam production, boiler or generator, has been programmed, it will be necessary to wait until it is ready for operation to start the steam ironing, which corresponds to the current solutions.

In addition, it becomes possible to ensure a diffusion of the water arriving at the soleplate by a spray placed at the front of the iron with a controllable member to pass the water normally injected into the soleplate by the spray each once you activate the spray function.

• un passage programmé de la solution évaporation dans le fer à la solution évaporation dans l'ensemble de production de vapeur par la commande d'une unité de commande programmable, par exemple à microprocesseur, demandant ou/et autorisant la mise en route et son alimentation en courant électrique de chaque système en fonction des températures atteintes détectées par des sondes ou thermostats, le fer étant prioritaire,
• une commande manuelle par l'utilisateur de systèmes électromécaniques ou seulement électriques ou seulement mécaniques pour sélectionner la mise en marche de l'un ou l'autre des deux systèmes de vaporisation.

The means to be used to obtain these possibilities are numerous and varied, we can describe some preferred solutions of the invention:

• a programmed passage of the evaporation solution in the iron to the evaporation solution in the steam production assembly by the control of a programmable control unit, for example a microprocessor, requesting and / or authorizing the start-up and its power supply electrical current of each system according to the temperatures reached detected by probes or thermostats, iron being a priority,
• a manual control by the user of electromechanical or only electrical or only mechanical systems to select the start of one or the other of the two vaporization systems.

• des interrupteurs permettant ou non le fonctionnement des pompes alimentant ou la chambre de vaporisation du fer ou le générateur instantané;
• un interrupteur trois positions autorisant le fonctionnement de l'un, de l'autre ou des deux systèmes de production de vapeur ;
• des vannes mécaniques obturant le passage de l'eau dans l'un, l'autre, les deux ou aucun des tuyaux utilisés ;
• un système par came permettant de pincer pour l'obturer chacun des deux tuyaux, ou les deux ensemble, ou aucun des deux, en manoeuvrant un seul levier ;
• des électrovannes pouvant être actionnées par des programmes pour autoriser ou non le passage des fluides dans les tuyaux les conduisant soit à l'ensemble de production de vapeur, soit à la chambre de vaporisation du fer.

These means can be:

• switches allowing or not the operation of the pumps supplying the iron vaporisation chamber or the instantaneous generator;
• a three-position switch allowing the operation of one or the other or both of the steam production systems;
• mechanical valves closing the passage of water in one, the other, the two or none of the pipes used;
• a camming system for gripping to seal each of the two pipes, or both together, or neither, by operating a single lever;
• solenoid valves that can be operated by programs to allow or not the passage of fluids in the pipes leading to either the steam assembly or the vaporization chamber of the iron.

Other variants may be envisaged with their association with solenoid valves or other pinch valves.

In particular, it can be realized a system allowing to use only a pump and a mechanical system by pinching the pipes directing the pumped water to either the vaporization chamber of the iron, or to the instantaneous generator, this economical solution is controlled manually.

It can also be used a pump and two mechanical shutters (valves) also controlled manually. It can also be used a single pump and a single connecting pipe between the instantaneous generator and the iron using a mechanical shutter after the pump to direct the water to one or other of the two evaporation systems but in making the water pipe meet the one of the Steam output from instant generator to drive in the same conduit or water, or steam to the iron. It will be necessary to interpose a mechanical or electromechanical shutter between the output of the generator and the junction of the two ducts to prevent water from returning to the generator.

Other fluids may be used for ironing such as perfume, starch, fabric softeners, or any other ironing product. These fluids may be stored in one or more tanks independent of that of the water, means for controlling the injection of these fluids and their diffusion by organs placed on the iron as the spray, should be used.

These means may for example be pumps or vacuum systems sucking these fluids to mix with others such as water or steam.

These tanks may be put in place either in the iron, or in the housing containing the separate steam production unit, or in both, with the necessary means to ensure their transport and distribution.

Other means may also be used to prohibit mixing non-missile fluids.

• la figure 1 illustre un premier mode de réalisation d'un appareil de repassage selon l'invention composé d'un fer à repasser et d'une chaudière de production de vapeur,
• la figure 2 illustre un second mode de réalisation d'un appareil de repassage selon l'invention composé d'un fer à repasser et d'un générateur de vapeur instantané,
• la figure 3 montre différentes courbes de température et de débit relatives au fonctionnement de l'appareil de repassage selon l'invention,
• les figures 4 et 5 illustrent une variante de réalisation de l'appareil de repassage des figures 1 et 2 intégrant une cassette déminéralisante,
• les figures 6 et 7 illustrent une variante de réalisation de l'appareil de repassage des figures 1 et 2 intégrant un conduit unique de passage des flux eau et vapeur,
• la figure 8 illustre une autre variante de réalisation de l'appareil de repassage de la figure 2 intégrant deux réservoirs d'alimentation en eau,
• la figure 9 illustre encore une autre variante de réalisation de l'appareil de repassage de la figure 2 comportant une pompe unique pour l'alimentation en eau et en vapeur,
• la figure 10 montre un organe mécanique pouvant être mis en oeuvre dans l'appareil de repassage de la figure 9,
• les figures 11 et 12 illustrent une variante de réalisation de l'appareil de repassage des figures 1 et 2 dans lequel il est ajouté un circuit supplémentaire de délivrance d'un fluide additionnel,
• les figures 13 et 14 illustrent une variante de réalisation de l'appareil de repassage des figures 6 et 7 dans lequel il est ajouté un circuit supplémentaire de délivrance d'un fluide additionnel,
• les figures 15 et 16 illustrent une variante de réalisation de l'appareil de repassage des figures 1 et 2 intégrant un conduit unique de passage des flux d'eau, de vapeur et d'un fluide additionnel,
• les figures 17 et 18 illustrent une autre variante de réalisation de l'appareil de repassage dans lequel il est possible d'adjoindre plusieurs fluides additionnels aux flux d'eau et de vapeur,
• la figure 19 montre un premier exemple de réalisation d'un fer à repasser utilisé dans un appareil de repassage selon l'invention,
• la figure 20 montre un deuxième exemple de réalisation d'un fer à repasser utilisé dans un appareil de repassage selon l'invention,
• la figure 21 montre un organe de mélange des flux eau et vapeur pouvant être mis en oeuvre dans le fer à repasser de la figure 20, et
• la figure 22 montre un autre exemple de réalisation d'un fer à repasser utilisé dans un appareil de repassage selon l'invention.

The invention will be better understood thanks to the following detailed description given, by way of illustration and without limitation, with reference to the appended drawings in which:

• FIG. 1 illustrates a first embodiment of an ironing apparatus according to the invention composed of an iron and a boiler for producing steam,
• FIG. 2 illustrates a second embodiment of an ironing apparatus according to the invention composed of an iron and an instant steam generator,
• FIG. 3 shows different temperature and flow curves relating to the operation of the ironing apparatus according to the invention,
• FIGS. 4 and 5 illustrate an alternative embodiment of the ironing apparatus of FIGS. 1 and 2 incorporating a demineralizing cassette,
• FIGS. 6 and 7 illustrate an alternative embodiment of the ironing apparatus of FIGS. 1 and 2 incorporating a single conduit for the passage of the water and vapor streams,
• FIG. 8 illustrates another alternative embodiment of the ironing apparatus of FIG. 2 integrating two water supply tanks,
• FIG. 9 illustrates yet another alternative embodiment of the ironing apparatus of FIG. 2 comprising a single pump for supplying water and steam,
• FIG. 10 shows a mechanical member that can be implemented in the ironing apparatus of FIG. 9,
• FIGS. 11 and 12 illustrate an alternative embodiment of the ironing apparatus of FIGS. 1 and 2 in which an additional circuit for delivering an additional fluid is added,
• FIGS. 13 and 14 illustrate an alternative embodiment of the ironing apparatus of FIGS. 6 and 7 in which there is added an additional circuit for delivering an additional fluid,
• Figures 15 and 16 illustrate an alternative embodiment of the ironing apparatus of Figures 1 and 2 incorporating a single conduit for the flow of water, steam and an additional fluid,
• FIGS. 17 and 18 illustrate another alternative embodiment of the ironing apparatus in which it is possible to add several additional fluids to the water and vapor streams,
• FIG. 19 shows a first embodiment of an iron used in an ironing appliance according to the invention,
• FIG. 20 shows a second embodiment of an iron used in an ironing appliance according to the invention,
• FIG. 21 shows a device for mixing the water and vapor streams that can be used in the iron of FIG. 20, and
• Figure 22 shows another embodiment of an iron used in an ironing appliance according to the invention.

FIGS. 1 and 2 illustrate two exemplary embodiments of an ironing appliance according to the invention composed of an iron 10 and a separate steam production unit 12, these two elements being connected by an electrical connection and hydraulic 14.

In the embodiment of FIG. 1, the steam production assembly comprises a conventional boiler, or boiler 20, closed by a filling plug 22 and whose water that it can contain is brought to boiling by an element. heater 24 provided with a pressure regulator 26 and connected to the electrical mains. The steam produced is directed via a steam duct 36 to the iron 10 through a normally closed solenoid valve 28 and whose opening is controlled by a programmable control unit 30 actuated via the link 14 from the steam control gate disposed. on the iron. Of course, an on / off switch 32 and status indicators (for example 34), preferably arranged at the level of the steam production assembly, are also provided for commissioning and control of the operation of the steam generator. ironing apparatus.

In the embodiment of FIG. 2, the steam production assembly comprises a water tank at ambient temperature 40 closed by a filling plug 42 and at the outlet of which an electric pump 44, preferably electromagnetic vibrating, is connected. , sending the pumped water into an instantaneous steam generator 46 provided with its heating element 48, the steam produced as it is produced being sent directly into the iron 10 via the steam duct 36 via the connection 14 The operation of the pump is ensured by a unit of programmable control 50 actuated via the link 14 from the steam control trigger of the iron. As in the previous embodiment, an on / off switch 52 and status indicators (for example 54), preferably arranged at the level of the steam production assembly, are also provided for the start-up and operation. control of the operation of the ironing apparatus.

The iron is a relatively light iron with a sole 60 provided with a heating element 62 and a temperature probe 64, this sole further closing a vaporization chamber 66 ensuring the generation of steam and its diffusion through the soleplate from water fed to the iron through the link 14. A steam control trigger 68 preferably located under the handle of the iron allows its user by establishing a contact advantageously present in the programmable control unit 30 or 50 to control the steam supply solenoid valve 28 or the electric pump of the steam generator 44 according to a given instruction by a thermostat 70 preferably disposed at the iron.

According to the invention, the water is no longer contained in a reservoir on the iron as in a conventional steam iron, which makes it heavy and requires frequent refilling because of its low capacity, but on the contrary in a large capacity tank disposed at the steam generating assembly 12 which therefore includes in addition to its steam production circuit an independent water supply circuit for the iron. This large capacity tank is constituted according to the embodiment envisaged either by the water tank 40 supplying the instantaneous generator 46 (embodiment of FIG. 2) or by a water tank at room temperature 72 independent of the boiler. (embodiment of Figure 1) and provided with its own filler cap 74. The water of the tank is pumped by an electric pump 76, preferably electromagnetic vibrating, to be fed through a tubing (flexible hose 78) into the vaporization chamber of the soleplate of the iron. In this iron, a check valve 80 is advantageously arranged on the water inlet pipe to prevent the suction of water in the pipe during the depression created by the vaporization of this water in the vaporization chamber. The control of the electric pump 76 is provided by the steam control gate 68 mounted on the iron, via the unit 30 or 50 which therefore controls the production of steam without reference to the system that will supply it.

The variations as a function of time, on the one hand, of the temperature at the iron level (curve 3A) and the steam production assembly (curve 3B) and, secondly, the flow rate in the iron feed pump 76 to iron (curve 3C) are described with reference to FIG.

On the curves 3A and 3B, the rise in temperature of the iron is observed to arrive at the value Tvf which is the programmed temperature from which the vaporization in the soleplate can be started, even if the programmed temperature Tp of the iron soleplate is not reached. From the moment when this temperature Tp is reached by the soleplate of the iron, the probe set to this value will stop the heating of the iron and the heating of the steam production unit, boiler or generator, can begin. Whenever the temperature of the iron falls to a predetermined level Tb measured by the probe, the heating of the boiler or generator will be stopped and heating of the iron will be resumed. When the boiler or generator has reached its proper temperature then the steam will come from this generator, except for higher steam production demand in which case the two systems will be engaged to give this extra steam requested.

Curve 3C illustrates the variation of the flow rate of the water supply pump 76 as a function of time. This is started when the temperature of the sole of the iron reaches the temperature Tvf, the flexible hose 78 connecting the large capacity tank and the iron will then fill very quickly to achieve a Dv optimized rate based on the heat capacity of the sole to evaporate the water received. When the boiler or generator has reached its proper temperature the pump will be stopped.

Thus, when the maximum heating power is allocated to heating the iron, it becomes possible to start ironing much faster with the steam produced in the iron than with the steam produced in the separate steam production unit, particularly it is a boiler. Of course, when this power is shared between the heating of the iron and that of the boiler or the tank, the amount of water that can be vaporized in the iron will be less than that produced with a maximum installed power.

It is thus possible automatically, as soon as the temperature of the iron Tp is reached, to begin the heating of the boiler or the generator, whatever its power, alternating with the iron which remains a priority, that is to say that when a set temperature which can be that Tb of reclosing of the thermostat of the iron is reached, it is the heating of the iron which is carried out until reaching the desired temperature Tp, then it is again the heating of the generator which will be switched on until the operating temperature of the steam production unit is reached. From this moment, it is the boiler or generator alone that will supply the steam to the iron in the programmable volumes.

It is clear that this arrangement allows to use the iron alone very quickly, twenty to thirty seconds may be sufficient to start, and especially if all the arrangements have been made to work as quickly as possible and in particular using the greatest power available on the electric sector to supply the iron and the boiler or the generator in separate time.

Indeed, feed the two elements iron and boiler or generator at the same time forces to divide the total power on these two elements. It follows a lower speed of rise in temperature of one and the other of these two elements, so a longer time than previously, especially for the iron, always the fastest to heat, is able to to be used. In addition, when the powers installed in the iron and the steam generating assembly are at maximum compatible with the electrical network or the sum of the powers of each of its elements is greater than the power available on the electrical network for a family use, it is necessary to alternately feed each of the two elements, however giving priority to the iron.

Figures 4 and 5 illustrate an alternative embodiment in which the water is treated against scale through its passage in a water treatment system, for example a demineralizing cassette 82, disposed directly at the outlet of the water tank 40 or 60 and with which is associated a system 84 for controlling the limestone content (minerality of the water) by measuring the conductivity of the water or any other equivalent physical measurement giving for example an indication of "end of cassette" .

In FIGS. 6 and 7, the steam outlet pipe of the boiler 20 or of the generator 46 and that of the water outlet of the pump 76 are joined together into a common pipe 86 by means of a hydraulic junction box 88. the embodiment of Figure 7, to prohibit water from entering the instantaneous generator 46 when the pump 76 is in operation, it is expected to have a solenoid valve or a mechanical valve 90 output of the generator. The water to be evaporated in the vaporisation chamber of the iron is sent into the pipe 86 downstream of the valve, against the steam produced by the generator 46 will be sent in the vaporization chamber of the iron through this solenoid valve or mechanical valve open in this case.

FIG. 8 illustrates a mode of operation similar to that of FIG. 7 with two separate room temperature water tanks 40A and 40B for supplying the generator 46 with the iron vaporization chamber via the pump 76. on the other hand, with or without a water treatment system 82 and its control system 84.

In FIG. 9, the water supply pump 76 is omitted and the iron is then supplied from the electric pump 44 supplying the generator 46. For this purpose, there are provided on the two conduits coming from this pump 44 valves 92A and 92B for alternately feeding or together the iron and the generator a mechanical member detailed in Figure 10 to supply the iron assembly. The control of these valves can be performed from a three-position switch (not shown) disposed on the steam generating assembly or preferably on the iron and thus obtaining three different steam flow rates. using the water tank feeding the vaporization chamber of the iron or the tank supplying the steam generator or both sets.

The valves 92A and 92B may advantageously be replaced by a single mechanical member such as that illustrated schematically in FIG. 10 and making it possible to select the passage of two fluids 1 and 2 by the simple rotation of a cam K crushing flexible hoses. Indeed, depending on its position, the cam can allow any passage (position A), allow one or the other of the two fluids (positions B or C) or prohibit any passage (position D).

Figures 11 to 16 describe different configurations of the steam production assembly allowing the use of perfumes, softeners or thickeners, such as starch, during ironing. For this and as shown in Figures 11 and 12, it is expected that this steam generating assembly 12 further comprises, in addition to the pump 76 leading the water to the vaporization chamber of the iron, another pump 94 drawing its fluid into another reservoir 96 containing the perfume or softener to be used and sending it by a clean tubing 98 in the iron, for example at a diffusion member (spray 100) at the front (as shown) or at the rear of this iron or in the chamber of vaporization whose control is actuated by a push button 102 advantageously disposed at the front of the iron.

This configuration with an additional pump is found in Figures 13 and 14 which show the two single-pipe variants of Figures 6 and 7.

Finally, in FIGS. 15 and 16, the hydraulic junction box 88 receiving the two streams of steam and water has an additional inlet which receives the output of the pump 94 so that all the streams formed by the steam, the water and the additional fluid pass through the same single pipe 104 which ends as previously in the steam chamber of the iron.

In FIGS. 17 and 18, several additional fluids are provided, each available in its own reservoir 96A, 96B, 96C connected directly to the pump 94, at which fluid selection is performed by selectively turning on the reservoir chosen for connect it to the pump. This pump thus offers the possibility according to the selection made to transport the flows of these additional fluids stored in interchangeable tanks by mixing them or not with the steam flow to distribute them to the choice in the iron where these fluids are fed by a single pipe for the broadcast according to the position of a dispensing member 106 by the sole or the spray or any other diffusion member whose control is performed this time by a button multifunctional control 102 and not only monofunction as before (supply of the only spray).

In FIGS. 19 and 20, the junction of the different additional fluids is no longer performed at the level of the steam production unit but directly in the iron. The streams of water and steam received from the steam production unit 12 are injected into a hydraulic bifurcation system 108 installed in the iron and also receiving the different additional fluids injected by individual pumps 110A, 110B, 110C in connection with each other. with independent reservoirs 112A, 112B, 112C arranged on the iron. The injection can also be made at a venturi system 114 which will ensure a mixture with either water or steam, and will diffuse via the dispensing member 106 by the sole of the iron, by the spray of iron or any other diffusion member disposed on this iron.

An example of a venturi system that can be used on the steam circuit to create a low-pressure zone and draw the liquid from any tank 112A to 112C in connection with this low-pressure zone and mix it with the vapor flow is illustrated in FIG. .

To favor the evaporation of the water arriving in the vaporization chamber 66 or in any case to favor evaporation seeds, it is advantageous to deposit on the walls of this chamber a fluorinated carbon coating 116 with a low coefficient of friction and possessing excellent non-wetting and non-sticking properties so that very few liquid or solid substances can adhere to it permanently. A typical example of such a coating is XYLAN®. The evaporation will also be favored by performing the injection in this chamber at several points 66A to 66C as illustrated in FIG. 22 so as to widen the evaporation surface and not to concentrate any scaling at an entry point. unique.

• poids du fer identique à celui d'un fer à sec ;
• même production de vapeur qu'un fer à vapeur ordinaire au départ ;
• utilisation d'eau traitée antitartre avec les moyens mis en oeuvre pour la contrôler et supprimer les risques d'entartrage ;
• remplissage beaucoup moins fréquent grâce au volume pouvant être mis en oeuvre dans le réservoir d'eau indépendant du fer et pouvant être réalisé à tout moment sans interruption du fonctionnement, lui conférant ainsi une autonomie illimitée ;
• possibilité d'utiliser le débit vapeur du fer comme premier niveau de débit ;
• possibilité d'utiliser le débit puissant de l'ensemble de production de vapeur séparé quelle que soit sa forme : générateur instantané ou chaudière rechargeable ou non, grâce à son raccordement à la chambre de vaporisation comme deuxième débit vapeur ; et
• possibilité d'utiliser la somme des quantités de vapeur produites à la fois par le fer et l'ensemble de production de vapeur.

The various embodiments of the invention described above thus have the following advantages for steam ironing as fast as ironing with a dry iron:

• weight of iron identical to that of a dry iron;
• same steam production as a regular steam iron;
• use of anti-scale treated water with the means used to control it and eliminate the risk of scaling;
• filling much less frequent thanks to the volume that can be implemented in the water reservoir independent of iron and can be achieved at any time without interruption of operation, giving it an unlimited autonomy;
• possibility of using the iron vapor flow as the first flow level;
• possibility of using the powerful output of the separate steam production unit whatever its form: instantaneous generator or boiler, rechargeable or not, thanks to its connection to the vaporization chamber as a second steam flow; and
• possibility of using the sum of the quantities of steam produced by both the iron and the steam generating assembly.

Claims (23)

Ironing apparatus comprising an iron (10) having a sole (60) provided with a vaporization chamber (66) and a steam generating assembly (12) actuated by a control unit (30; 50) and connected by an electrical and hydraulic connection (14) having a steam duct (36), said steam generating assembly further comprising a pump (76) and a water supply tank (40; 72), water pumped from said water supply tank being fed through a conduit (78) to said vaporization chamber, characterized in that said control unit is adapted to supply water to the iron by controlling said pump to provide a high flow of water as soon as a temperature (Tvf) of said soleplate is sufficient to ensure the evaporation of this water and thus very quickly fill said connecting duct between said water supply tank and said vaporization chamber and to supply vap said iron to be ironed as soon as the steam generating assembly has reached a determined temperature (Tg) of operation, the water flow being then brought back to a determined flow rate (Dv) so as not to exceed the evaporation capacities. the sole of the iron. Ironing apparatus according to claim 1, characterized in that said vaporization chamber comprises a plurality of injection points for injecting in order to vaporize the water pumped from said water supply tank. Ironing apparatus according to claim 1 or claim 2, characterized in that said vaporization chamber is covered on all its walls with a fluorocarbon coating (116) to facilitate the evaporation of the water pumped from said reservoir. water supply. Ironing appliance according to any one of claims 1 to 3, characterized in that it further comprises a flap non-return valve (80) mounted on said connecting pipe bringing water from said water supply tank to said vaporization chamber. An ironing apparatus according to any one of claims 1 to 4, characterized in that said steam generating assembly comprises an instantaneous steam generator (46) supplied with water from a tank (40) via a pump (44) said tank then also serving to supply water to said vaporization chamber. Ironing apparatus according to claim 5, characterized in that said processing unit (50) is, according to the determined position of one or more switches, adapted to control the pump (44) sending water from the reservoir into the instantaneous generator steaming or controlling the pump (76) sending water from the tank to the vaporization chamber of the iron or both sets. Ironing apparatus according to claim 6, characterized in that said switch is a 3-position switch to fulfill one of the following functions: use of the instantaneous steam generator or the vaporization chamber or both simultaneously. Ironing apparatus according to any one of claims 1 to 7, characterized in that it further comprises a mechanical shutter for closing by clamping one or the other or both or both of the ducts bringing the water and steam to the iron. Ironing apparatus according to any one of claims 1 to 7, characterized in that it comprises two mechanical valves placed on the two water and steam ducts for closing or not these two ducts bringing the water and the water. steam iron. Ironing appliance according to any one of claims 1 to 7, characterized in that it comprises two solenoid valves (92A, 92B) arranged on each of the two water and steam ducts and to seal or not these two ducts bringing water and steam to the iron. Ironing apparatus according to claim 10, characterized in that said solenoid valves are controlled by said processing unit. Ironing appliance according to any one of claims 1 to 11, characterized in that said iron has dispensing means (106) for, according to a determined position of a selection means (102), to direct the steam and or water in a spray (100) placed in front of the iron, in said vaporization chamber or in both. Ironing apparatus according to claim 12, characterized in that said bypass means comprise solenoid valves or mechanical valves acting by closing or by pinching the steam or water pipes. Ironing apparatus according to any one of claims 1 to 12, characterized in that it comprises a single duct (86) for driving alternatively or together the steam of the steam production assembly and the water of said storage tank. water supply. Ironing apparatus according to claim 14, characterized in that it further comprises a solenoid valve (90) disposed at the outlet of the instantaneous steam generator to prohibit the entry of water into the generator when the water is sent to the chamber vaporizing the iron by said single conduit. Ironing apparatus according to any one of claims 1 to 15, characterized in that it comprises a common pump (44) for sending the water either into the instantaneous steam generator or into the steam chamber of the iron, a shut-off system (92A, 92B) being provided at the outlet of this pump on the two water and steam ducts for under the action of the control unit shut off or not one or both or both of these ducts bringing water and steam to the iron. Ironing apparatus according to claim 16, characterized in that said closure system comprises one or more mechanical valves or one or more solenoid valves allowing by closing or by pinching to seal or not the two ducts bringing the water and the steam to iron. Ironing apparatus according to any one of claims 1 to 17, characterized in that it further comprises a water treatment system formed by a demineralizing cassette (70) associated with a system for measuring the minerality of the water. water (72) to provide control of water from the water supply tank. Ironing appliance according to any one of claims 1 to 18, characterized in that it comprises two water supply tanks (40A, 40B) for supplying the iron vaporization chamber and the instantaneous steam generator in the case where one of the two volumes of water must be treated and not the other. Ironing apparatus according to any one of claims 1 to 19, characterized in that it further comprises one or more additional reservoirs (96A, 96B, 96C, 112A, 112B, 112C) containing additive liquids and which may or may not be injected into the conduits of water or vapor to be diffused by a spray, by the vaporization chamber or by other diffusing organs. An ironing apparatus according to claim 20, characterized in that said iron comprises a bifurcation system (108) for feeding the fluxes into areas such as the iron vaporization chamber, the spray or other areas by use of fluids different from water and stored in said additional tanks. Ironing apparatus according to claim 21, characterized in that it further comprises a venturi system for creating a low pressure zone on the steam circuit in connection with one or the other liquid stored in said additional tanks. Ironing apparatus according to any one of Claims 1 to 22, characterized in that it comprises a pump in relation to the additional tanks containing the additive products for injecting, depending on the selection of this additive product in the water or steam duct to be diffused by the various diffuser members of the device, such as the sole, the spray or other.

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