Disclosed is a clothing steam ironing apparatus, comprising an ironing component (3) with an ironing panel, steam ejection holes (7) for ejecting steam to iron a clothing and air suction holes (8) for generating a suck force to the clothing are provided in the ironing panel.

Disclosed is a clothing steam ironing apparatus, comprising an ironing component (3) with an ironing panel, steam ejection holes (7) for ejecting steam to iron a clothing and air suction holes (8) for generating a suck force to the clothing are provided in the ironing panel.

A smoothing head includes a steam distribution circuit containing an inlet duct including an inlet opening connected to a steam pipe; and a front wall equipped with a treatment face including at least one steam outlet hole and intended to face a garment to be smoothed. The inlet duct includes an outlet opening leading to an inner chamber belonging to the steam distribution circuit, the inner chamber including a condensate evacuation opening communicating with a condensate return circuit leading to the steam pipe or to the inlet duct.

A smoothing head includes a steam distribution circuit containing an inlet duct including an inlet opening connected to a steam pipe; and a front wall equipped with a treatment face including at least one steam outlet hole and intended to face a garment to be smoothed. The inlet duct includes an outlet opening leading to an inner chamber belonging to the steam distribution circuit, the inner chamber including a condensate evacuation opening communicating with a condensate return circuit leading to the steam pipe or to the inlet duct.

The present application relates to a steam iron head (30). The steam iron head (30) has a steam inlet (36), a steam pathway (40), and at least one steam vent through which steam is discharged from the steam iron head. The steam pathway (40) has a first steam flow section (50) and a second steam flow section (60). The first steam flow section (50) defines an indirect flow path between the steam inlet (36) and a second steam flow section (60). The second steam flow section (60) defines a cyclonic flow path between the first steam flow section (50) and the at least one steam vent. The present application also relates to a steam system iron (10) having a steam iron head (30). This invention helps remove any water droplets, for example formed by condensation, from the steam flow passing through the steam iron head from the steam inlet to the at least one steam vent.

The present application relates to a steam iron head (30). The steam iron head (30) has a steam inlet (36), a steam pathway (40), and at least one steam vent through which steam is discharged from the steam iron head. The steam pathway (40) has a first steam flow section (50) and a second steam flow section (60). The first steam flow section (50) defines an indirect flow path between the steam inlet (36) and a second steam flow section (60). The second steam flow section (60) defines a cyclonic flow path between the first steam flow section (50) and the at least one steam vent. The present application also relates to a steam system iron (10) having a steam iron head (30). This invention helps remove any water droplets, for example formed by condensation, from the steam flow passing through the steam iron head from the steam inlet to the at least one steam vent.

A steam iron (10) comprising a soleplate (13), a heating element (14) for heating the soleplate (13), an inlet junction(16) comprising a first inlet (28) for receiving input steam from a steam generator and a second inlet (29), a water-steam separator (18) connected to the inlet junction (16) to receive steam from the inlet junction (16) and separate steam from condensed water entrained in the steam. The steam iron also includes an evaporation chamber (19) connected to the water-steam separator (18) to receive condensed water from the water-steam separator (18) and which includes a surface heated by the heating element (14) to generate evaporated water from the condensed water. The evaporation chamber (19) is connected to the second inlet (29). The inlet junction (16) comprises a venturi effect nozzle (31) for expelling the input steam and to generate a reduced pressure in the region of the second inlet (29) to draw the evaporated water into the inlet junction (16). The venturi nozzle (31) is disposed within an outer tube (32) of the inlet junction (16) and the second inlet (29) is positioned upstream of the end of the venturi nozzle (31) from which the input steam is expelled, with respect to the flow direction of the steam.

A steam iron (10) comprising a soleplate (13), a heating element (14) for heating the soleplate (13), an inlet junction(16) comprising a first inlet (28) for receiving input steam from a steam generator and a second inlet (29), a water-steam separator (18) connected to the inlet junction (16) to receive steam from the inlet junction (16) and separate steam from condensed water entrained in the steam. The steam iron also includes an evaporation chamber (19) connected to the water-steam separator (18) to receive condensed water from the water-steam separator (18) and which includes a surface heated by the heating element (14) to generate evaporated water from the condensed water. The evaporation chamber (19) is connected to the second inlet (29). The inlet junction (16) comprises a venturi effect nozzle (31) for expelling the input steam and to generate a reduced pressure in the region of the second inlet (29) to draw the evaporated water into the inlet junction (16). The venturi nozzle (31) is disposed within an outer tube (32) of the inlet junction (16) and the second inlet (29) is positioned upstream of the end of the venturi nozzle (31) from which the input steam is expelled, with respect to the flow direction of the steam.

The present application relates to a steam generator (40) for a steaming device (10) comprising a chamber (42) having a base (46) and a liquid receiving space (47) above the base (46), a heater (50) for heating water in the liquid receiving space (47), a steam outlet (49), and a foaming restriction barrier (70) disposed between the steam outlet (49) and the base (46). The foaming restriction barrier (70) comprises a first barrier section (71) spaced from the liquid receiving space (47) between the steam outlet (49) and the liquid receiving space (47). The first barrier section (71) is configured to prevent foam from passing into the steam outlet (49). The foaming restriction barrier (70) also comprises a second barrier section (72) spaced from the first barrier section (71) between the first barrier section (71) and the liquid receiving space (47). The second barrier section (72) is configured to prevent foam from passing from the liquid receiving space (47) into an intermediate space (85) between the first and second barrier sections (71, 72). The second barrier section (72) is configured so that all the steam generated from heating water in the liquid receiving space (47) below the second barrier section (72) passes through the second barrier section (72) into the intermediate space (85) and, from the intermediate space (85) through the first barrier section (71), before passing through the steam outlet (49).

The present application relates to a steam generator (40) for a steaming device (10) comprising a chamber (42) having a base (46) and a liquid receiving space (47) above the base (46), a heater (50) for heating water in the liquid receiving space (47), a steam outlet (49), and a foaming restriction barrier (70) disposed between the steam outlet (49) and the base (46). The foaming restriction barrier (70) comprises a first barrier section (71) spaced from the liquid receiving space (47) between the steam outlet (49) and the liquid receiving space (47). The first barrier section (71) is configured to prevent foam from passing into the steam outlet (49). The foaming restriction barrier (70) also comprises a second barrier section (72) spaced from the first barrier section (71) between the first barrier section (71) and the liquid receiving space (47). The second barrier section (72) is configured to prevent foam from passing from the liquid receiving space (47) into an intermediate space (85) between the first and second barrier sections (71, 72). The second barrier section (72) is configured so that all the steam generated from heating water in the liquid receiving space (47) below the second barrier section (72) passes through the second barrier section (72) into the intermediate space (85) and, from the intermediate space (85) through the first barrier section (71), before passing through the steam outlet (49).