DE102018119566A1 - Vaporizing element for an electric cigarette and method for producing the vaporizing element - Google Patents

Abstract

The present invention relates to an evaporation element for an evaporator (7) in an electric cigarette (1), the evaporation element (22) comprising a base (31), a ceiling (32) and a wall (33), the evaporation element (22 ) consists of a porous element, the porous element serving as an electrical heating element and as a liquid carrier.

Description

The present invention relates to an evaporation element for an electrical cigarette and a method for producing the evaporation element for the electrical cigarette. An electric cigarette according to the prior art comprises a battery carrier, in which a battery for the power supply is arranged and a mouth part. The mouthpiece is attached to the battery holder. The mouthpiece comprises a container in which a consumable liquid, hereinafter referred to as liquid, is stored. The container includes an evaporator, which is electrically connected to the battery and which evaporates the liquid into aerosol. The vaporized liquid or the aerosol is mixed with fresh air and the aerosol-fresh air mixture is then supplied to the user of the electric cigarette for inhalation via a chimney arranged in the mouth part.

An evaporator from the prior art consists of a heating element, usually an electrical coil, and a liquid carrier, usually a cotton wool. The coil can be heated electrically. The cotton wool is pulled through the spool and protrudes from the side ends of the spool. The side ends of the cotton are completely in liquid. As a result, the cotton wool is saturated with liquid. The liquid in the cotton wool is heated and evaporated in the area in which the cotton wool is surrounded by the coil. In proper condition, new liquid flows over the side ends of the cotton wool after evaporation or during evaporation.

If the liquid is running low and / or the cotton is no longer pumping the liquid properly within the cotton, it can happen that a so-called dry hit occurs. With the dry hit, the cotton is no longer properly wetted with liquid, particularly in the area of the spool, and in particular no new, fresh liquid is conveyed into the cotton. As the coil heats the cotton wool, the temperature in the cotton wool rises sharply. The liquid can decompose and taste unpleasant for the user.

It is therefore an object of the invention to provide an evaporation element for an electric cigarette and a method for producing the evaporation element which largely and in particular completely avoids a dry hit.

This object is achieved by an evaporation element with the features of claim 1 and with a method with the features of claim 10. Advantageous developments of the invention are the subject of the corresponding dependent claims and described in the description and shown in the drawings.

According to the invention, the evaporation element consists of a porous element, the porous element serving as an electrical heating element and as a liquid carrier. The liquid carrier and heating element are thus formed in one piece in the evaporation element according to the invention. In particular as a liquid carrier, the porous element sucks in liquid via capillary effects and distributes it largely uniformly in the porous element. The liquid can also flow into the porous element via other forces, for example gravity, fluid mechanical forces or the like.

It may be appropriate to provide at least one pipeline in the porous element. The pipeline is expediently used for the targeted delivery of liquid in the porous element. In this expedient variant, the liquid can be distributed unevenly in the porous element.

The porous element is advantageously electrically conductive. Due to the electrical conductivity, the porous element can be heated electrically, so that the porous element serves as an electrical heating element. This creates a uniform heat or a largely constant temperature in the porous element over the porous element, so that local overheating is largely prevented. A dry hit is largely prevented. In contrast to cotton wool, which degenerates or is permanently damaged in a dry hit and thus becomes unusable, in particular damage to the evaporation element specified in this invention is largely prevented. There is advantageously little or no wear of the evaporation element. The service life is thus extended in comparison to an evaporator consisting of cotton wool and coil known from the prior art.

The porous element is expediently electrically conductive. The porous element is particularly advantageously a metal foam.

According to the invention, the evaporation element comprises a floor, a ceiling and a wall. In particular, the evaporation element is cylindrical.

The porous element advantageously has an inhomogeneous density. The density of the porous element in the interior of the evaporation element is particularly advantageously lower than the density of the porous element close to the wall. In other words, in particular the porosity of the porous element close to the wall is less than the porosity of the porous element inside the evaporation element. This increases the capillary effect, which conveys liquid from the wall of the evaporation element into the interior of the evaporation element. Close to the wall in the sense of Invention is the area that extends over at most about 40%, in particular at most about 30%, expediently at most about 20%, particularly expediently about 10% and advantageously about 5% of that from the wall to the center of the body, for example the center of gravity or geometric center, in particular Cylinder center, measured distance extends. The interior of the porous element expediently adjoins the area close to the wall.

Preferably the wall is permeable to a liquid, and in particular the bottom and the ceiling are liquid impermeable to the liquid. This allows liquid to flow into the interior of the evaporation element via the wall. No liquid can enter or exit the floor and ceiling. In particular, electrical contacts are arranged on the floor and ceiling, which supply the evaporation element with current. Due to a liquid-impermeable bottom and a liquid-impermeable wall, the electrical contacts are not wetted with liquid. This ensures good electrical conductivity between the electrical contacts and the porous element. In particular, each of the electrical contacts is in full contact with the floor or ceiling.

It may be appropriate for the floor and the ceiling to be liquid-permeable and for the wall to be liquid-impermeable. Here, the electrical contacts are expediently placed on the wall and the liquid is introduced into the porous element via the floor and ceiling.

The floor is expediently flat. The ceiling is expediently largely, in particular completely flat. This allows the electrical contacts to be attached to the floor or ceiling easily and flatly. The wall is preferably at least partially flat. At least one electrical contact can be attached to the wall well and flat. At least one pin is advantageously provided on the porous element. Two pins are advantageously provided on the porous element. The electrical contact can thus be made on at least one pin.

The porous element, in particular the metal foam, expediently consists of a corrosion-resistant nickel-based alloy, in particular of an Inconel alloy. A temperature of about 220 ° C to about 230 ° C is required to evaporate liquid. A corrosion-resistant nickel-based alloy and in particular an Inconel alloy has a high temperature resistance. Burning through of the metal foam, in particular in the above-mentioned temperature range between approximately 220 ° C. and 230 ° C., is thereby largely prevented. The Inconel alloy advantageously has up to 65% higher specific resistance than stainless steel. It may be appropriate for the porous element to be made of stainless steel. The porous element preferably consists of a ceramic, in particular of a doped ceramic. The ceramic is expediently doped with rare earths, for example antimony, germanium, or the like. The porous element can preferably consist of Kanthal.

The inner surface of the evaporation element is advantageously at least approximately 20 mm ² , particularly advantageously at least approximately 40 mm ² , and at most approximately 60 mm ² , particularly advantageously at most approximately 50 mm ² . A coil from the prior art with a wire diameter of approximately 0.2 mm has, for example, a surface area of only approximately 18 mm ² . The inner surface of the evaporation element according to the invention is thus larger than the inner surface of a coil known from the prior art, in some cases approximately twice as large. This means that a lot more liquid is in contact with the heating element, so that the liquid can be evaporated with little energy consumption.

The total volume of the evaporation element is preferably less than 1 cm ³ , in particular less than 0.5 cm ³ , in particular less than 0.2 cm ³ .

The cylindrical evaporation element advantageously has a diameter of approximately 1 mm, particularly advantageously approximately 2 mm, and a height of approximately 0.8 mm, particularly advantageously approximately 1.2 mm. It may be appropriate for the diameter to be between approximately 0.5 mm and approximately 5 mm, particularly advantageously between approximately 1 mm and approximately 3 mm. It may be appropriate for the height to be between approximately 0.5 mm and approximately 8 mm, in terms of wake-up between approximately 0.5 mm and approximately 4 mm, particularly advantageously between approximately 1 mm and approximately 2 mm.

The evaporation element is preferably an additively manufactured component. An additively manufactured component is in particular a component that is advantageously produced using the foam process, the powder sintering process, the 3D printing process, in particular 3D printing, porous SLM (selective laser melting), 3D printing, powder-infused SLA (stereolithography), or the like.

In particular when using a corrosion-resistant nickel-based alloy, in particular from an Inconel alloy, the evaporation element can be produced from the material, which is actually difficult to process, in an additive process. In addition, the inhomogeneous density of the evaporation element can be controlled in the additive manufacturing process. In addition, it is largely, in particular completely, fully automatic Production of the evaporation element possible in the additive manufacturing process. The evaporation element is expediently a 3D printed part.

In the process for producing the one-part evaporation element for the vaporizer in the electric cigarette, the evaporation element is printed in layers in an additive manufacturing process, in particular using a 3D printer, a corrosion-resistant nickel-based alloy, in particular an Inconel alloy, being used as the printing material becomes. The evaporation element is printed in the additive manufacturing process in such a way that the density of the resulting porous element becomes inhomogeneous, in particular the density in the interior of the evaporation element being lower than close to a wall of the evaporation element.

When printing to hold the evaporation element in the 3D printing machine, feet are advantageously printed. The feet are expediently removed after printing, in particular the feet are removed by eroding or by laser cutting or by filing or the like. It is particularly useful to print predetermined breaking points on the feet when printing. This means that the feet can be broken at the predetermined breaking points after printing and then removed.

The feet are preferably printed on the floor or on the ceiling. This allows the evaporation element to be printed particularly well. It may be advantageous for the feet to be printed on the wall of the evaporation element. This may simplify later removal of the feet.

• 1: eine schematische Ansicht einer elektrischen Zigarette mit einer Kapsel in einer ersten Position,
• 2: eine Schnittansicht der elektrischen Zigarette mit der Kapsel in der ersten Position,
• 3: eine schematische Ansicht der elektrischen Zigarette mit der Kapsel in einer zweiten Position,
• 4: eine Schnittansicht der elektrischen Zigarette mit der Kapsel in der zweiten Position,
• 5: eine Explosivdarstellung der elektrischen Zigarette mit ausgewählten Bauteilen,
• 6: eine Schnittansicht der elektrischen Zigarette mit ausgewählten Bauteilen in Explosivdarstellung,
• 7: eine schematische Ansicht auf ein aufgeschnittenes Teilmodell der elektrischen Zigarette,
• 8: eine schematische Ansicht eines Verdampers und eines Verschiebers,
• 9: eine Schnittansicht entlang der in 8 angedeuteten Ebene E-E des Verdampfers und des Verschiebers,
• 10: eine Explosivdarstellung des Verdampfers und des Verschiebers,
• 11: eine Schnittansicht entlang der in 10 angedeuteten Ebene F-F des Verdampfers und des Verschiebers in Explosivdarstellung,
• 12: eine schematische Darstellung des Verdampfers,
• 13: eine Explosivdarstellung des Verdampfers und des Rückstellelements,
• 14: eine schematische Ansicht zur Darstellung eines ersten Schnitts durch das Verdampfungselement, und
• 15: eine schematische Ansicht zur Darstellung eines zweiten Schnitts durch das Verdampfungselement.

Advantageous embodiments of the invention are described below with reference to the accompanying figures. Show it

• 1 : a schematic view of an electric cigarette with a capsule in a first position,
• 2 : a sectional view of the electric cigarette with the capsule in the first position,
• 3 : a schematic view of the electric cigarette with the capsule in a second position,
• 4 : a sectional view of the electric cigarette with the capsule in the second position,
• 5 : an exploded view of the electric cigarette with selected components,
• 6 : a sectional view of the electric cigarette with selected components in an exploded view,
• 7 : a schematic view of a cut-open partial model of the electric cigarette,
• 8th : a schematic view of an evaporator and a shifter,
• 9 : a sectional view along the in 8th indicated plane EE of the evaporator and the shifter,
• 10 : an exploded view of the evaporator and the shifter,
• 11 : a sectional view along the in 10 indicated plane FF of the evaporator and the shifter in an exploded view,
• 12 : a schematic representation of the evaporator,
• 13 : an exploded view of the evaporator and the reset element,
• 14 : a schematic view showing a first section through the evaporation element, and
• 15 : A schematic view showing a second section through the evaporation element.

In the 1 to 6 shown electric cigarette 1 includes a battery carrier 2 , In the battery carrier 2 is a battery, not shown in the figures, for powering the electric cigarette 1 arranged. The electric cigarette 2 includes one capsule 3 , The capsule 3 encloses you in 7 illustrated pantry 4 , The pantry 4 is intended to liquid 5 record and stockpile. Through an opening 6 , In the exemplary embodiment there are two openings 6 provided, Liquid 5 from the pantry 4 escape. The openings are particularly advantageous 6 identical in construction. The two openings are expedient 6 offset by about 180 °. Each of the openings 6 has a diameter of at most about 5 mm, in particular at most about 3.5 mm, in the exemplary embodiment in particular at most about 1 mm.

The liquid 5 includes in particular propylene glycol, in particular vegetable glycerin and flavoring agents, preferably naturally vegetable flavoring agents and optionally nicotine. The leaking liquid 5 flows into an evaporator 7 , The evaporator 7 is electrically heated, whereby the electrical energy comes from the battery. In the evaporator 7 evaporates the liquid 5 , Evaporation in the sense of the invention can be understood to mean complete evaporation, but also the production of tiny liquid droplets, so that an aerosol can be produced. In the evaporator 7 mix air and evaporated liquid 5 to an exhaust air, where the exhaust air can be referred to as aerosol and / or steam. The precise evaporation and mixing of air and vaporized liquid 5 will be explained later.

The exhaust air flows through a chimney 8th in a calming chamber 9 , The calming chamber 9 is in the area of a mouthpiece 10 the electric cigarette 1 arranged. In the mouthpiece 10 there is at least one, in the exemplary embodiment two outputs 11 , through which the exhaust air from the electric cigarette 1 preferably flows into a user's mouth. In a further embodiment, the calming chamber 9 omitted and the outputs 11 are right by the fireplace 8th arranged. The air flow, especially that of the exhaust air and the supply air, is caused by the user at the mouthpiece 10 pulls and thereby creates a suction or a vacuum.

The following is the structure of the capsule 3 are described in more detail. The capsule 3 includes one in the 5 . 6 and 8th . 9 shown slide 12 , The slider 12 is essentially cylindrical with an in 8th and 9 shown slide bottom 13 , a blanket 14 and a wall 15 , On the ceiling 14 is a reset element 16 arranged in the form of a spring. In a further embodiment, not shown in the figures, the slide can 12 also be carried out inside.

As in the 2 . 4 and 7 The capsule is clearly visible 3 a floor 17 , The floor 17 is on the battery carrier 2 attached capsule 3 the battery carrier 2 facing. The floor 17 one points approximately in the direction of the pantry 4 extending, in particular cylindrical, indentation 18 on. In the indentation 18 is the opening 6 arranged.

4 shows the slider 12 in a second position 19 , In the second position 19 the slide blocks 12 in the 7 shown opening 6 , So no liquid 5 out of the opening 6 escape.

2 shows the slider 12 in a first position 20 , In the first position 20 gives the slider 12 in the 7 shown opening 6 free. Liquid 5 out of the opening 6 exit and into the evaporator 7 enter.

The structure of the evaporator is shown below 7 are described in more detail. The evaporator 7 includes one in the 5 . 6 and 10 to 13 shown insulator 21 , The evaporator 7 comprises an evaporation element 22 , The evaporator 7 includes a first electrical contact 23 and a second electrical contact 24 ,

The essentially cylindrical insulator in the exemplary embodiment 21 encloses you in 13 shown evaporation space 25 , In a further exemplary embodiment, not shown in the figures, it may be expedient for the insulator 21 deviates from the cylindrical shape. It may be advantageous for the insulator 21 is ring-shaped, pyramid-shaped, prismatic, cuboid, cubic, spherical, in the form of a donut or the like. In in 12 shown operating state of the evaporator 7 are the in 13 Components shown in an explosive representation first electrical contact 23 , Evaporation element 22 and second electrical contact 24 in the evaporation room 25 arranged.

The in 13 isolator shown 21 includes a liquid inflow well 26 , The liquid inflow well 26 is arranged on the outside of the cylinder and provides a connection from the outside of the cylinder to the evaporation chamber 25 ago. The liquid inflow well 26 opens approximately at the level of the evaporation chamber 25 arranged evaporation element 22 (see. 12 and 13 ). In the exemplary embodiment, the isolator comprises 21 two liquid inflow wells 26 , The two liquid inflow wells 26 lie opposite to each other, so they are in particular offset by approximately 180 °. Liquid 5 through the insulator on both sides 21 in the evaporation room 25 and in particular on two sides in the evaporation element 22 stream. This is a good supply of liquid in the evaporation element 22 allows.

The isolator 21 includes a supply air hole 27 , In the exemplary embodiment is the supply air hole 27 designed as an elongated hole. The supply air hole 27 serves to supply air to the evaporation chamber 25 and especially in the evaporation element 22 , In the exemplary embodiment, the isolator comprises 21 two supply air holes 27 , The two supply air holes 27 lie opposite to each other, so they are in particular offset by approximately 180 °. This allows supply air to pass through the insulator on both sides 21 in the evaporation room 25 and in particular on two sides in the evaporation element 22 stream. This ensures a good supply of air to the evaporation element 22 allows.

The isolator 21 includes an exhaust hole 28 , In the exemplary embodiment, the exhaust air hole 28 designed as an elongated hole. The exhaust hole 28 is used to remove exhaust air, i.e. a mixture of supply air and vaporized liquid 5 , from the evaporation room 25 and in particular from the evaporation element 22 , In the exemplary embodiment, the exhaust air flows via one in the slide 12 arranged exhaust air hole 29 ( 8th ) in the fireplace 8th ( 2 ).

In the exemplary embodiment, the isolator comprises 21 two exhaust holes 28 , The two exhaust holes 28 lie opposite to each other, so they are in particular offset by approximately 180 °. This allows exhaust air to pass through the insulator on both sides 21 from the evaporation room 25 and in particular from both sides of the evaporation element 22 stream. This ensures good exhaust air removal from the evaporation element 22 allows. In the exemplary embodiment, the slide comprises 12 two exhaust holes 29 , The two exhaust holes 29 in the slide 12 lie opposite to each other, so they are in particular offset by approximately 180 °. This allows exhaust air to pass through the slide on both sides 12 in the fireplace 8th stream. This ensures good exhaust air removal from the evaporation element 22 and in the fireplace 8th allows.

The evaporation element 22 comprises an electric heating element and a liquid carrier. In the exemplary embodiment there is the evaporation element 22 from a porous element. In the exemplary embodiment, a metal foam or metal wadding or the like is used as the porous element. In the exemplary embodiment, the porous element serves as a liquid carrier and as a heating element, as a result of which the liquid carrier and heating element are made in one piece in the exemplary embodiment. Accordingly, there is the evaporation element in the exemplary embodiment 22 from just one component.

The cylindrical evaporation element in the exemplary embodiment 22 includes an in 15 schematically represented floor 31 , A blanket 32 and a wall 33 , The cylindrical evaporation element 22 has a diameter D of about 1 mm, particularly advantageously of about 2 mm. The cylindrical evaporation element 22 has a height H of about 0.8 mm, particularly advantageously of about 1.2 mm.

The floor 31 of the evaporation element 22 , the blanket 32 of the evaporation element 22 and the wall 33 of the evaporation element 22 limit one in the 14 and 15 schematically shown interior 30 , In the 14 and 15 the edges of the porous element are schematically represented by a solid line. In the real embodiment, the limitation is in particular non-linear, in particular due to the porous structure of the porous element. Shapes other than that of the cylinder are also for the evaporation element 22 conceivable. For example, the evaporation element 22 prismatic, cuboid, cube-shaped, cylindrical, truncated cylindrical, in the form of a donut or the like.

In the exemplary embodiment, the wall 33 of the evaporation element 22 liquid permeable. Liquid gets through the porosity of the metal foam 5 in the interior 30 of the metal foam, in particular the liquid fills the interior 30 of the metal foam largely, in particular completely. The penetration of liquid 5 in the interior 30 of the metal foam is caused by the capillary effect. As shown in the exemplary embodiment, the capillary effect increases because the density in the region of the wall 33 of the metal foam is higher than further inside the metal foam. In other words, the porosity of the metal foam in the area of the wall 33 less than further inside the metal foam. In the exemplary embodiment, the porosity is from approximately 60% to approximately 65%. It may be advantageous that the porosity is from about 20% to about 90%, in particular from about 30% to about 80%, particularly advantageously from approximately 50% to approximately 70%, very particularly advantageously from approximately 60% to approximately 65% ,

In the embodiment, the bottom 31 of the evaporation element 22 and the blanket 32 of the evaporation element 22 largely, especially completely, liquid-impermeable. On the ground 31 and blanket 32 of the cylindrical metal foam are the in 13 electrical contacts shown 23 . 24 created. In the exemplary embodiment, the electrical contacts, which are in particular at least partially circular, are located 23 . 24 each flat on the in 15 shown floor 31 and the ceiling 32 of the metal foam. It may be appropriate to the wall 33 at least partially flat, so that at least one of the electrical contacts 23 . 24 is placed on the wall. A wide-area current supply can be ensured by the flat support. This can also largely burn or locally overheat the liquid 5 be ensured. Now there is a voltage provided by the battery between the electrical contacts 23 . 24 on, the metal foam and the liquid in the metal foam heat up 5 evaporates and is replaced by new ones from the openings 26 inflowing liquid 5 replaced. In a further exemplary embodiment, which is not shown in the figures, the contacting takes place with the aid of at least one pin. This allows the electrical contact to be set in a targeted manner. Other forms of contact can be useful.

The temperature of the metal foam during operation is approximately 220 ° C to 230 ° C. The temperature of the metal foam that occurs during operation is largely homogeneously distributed in the metal foam.

A charge of approximately 260 mAh is required to evaporate 1 g of liquid. Due to the comparatively large surface area and the homogeneous temperature distribution in the porous element, the liquid is heated much more efficiently and therefore requires less electrical energy to fulfill the evaporation task than conventional evaporators, which consist of cotton wool and a coil.

In the exemplary embodiment there is the isolator 21 made of plastic. The evaporation element 22 consists of metal foam made of corrosion-resistant nickel-based alloy, especially an Inconel alloy. Inconel alloys are also known under the name Inco and Chronin, Altemp, Haynes, Nickelvac, Nicrofer, or the like. The Inconel alloy is suitable for high temperature applications. It has surprisingly been found that, for example, commercially available stainless steel alloys can be damaged, in particular smoke, at the temperatures of 220 ° C. to 230 ° C. described. In the Inconel alloy used in the exemplary embodiment, on the other hand, there was no burning through and therefore no damage to the metal foam or the evaporation element 22 be determined. This is probably not only due to the higher temperature resistance of the Inconel alloy, but also due to the lower specific resistance of the stainless steel. With the same metal structure and the same tension, a stainless steel element will release between 39% and 74% more power, especially depending on the exact Inconel alloy composition.

The Inconel alloy comprises nickel as the main component and chrome as the secondary component. The Inconel alloy can also include the following elements: iron, molybdenum, niobium, cobalt, manganese, copper, aluminum, titanium, silicon, carbon, sulfur, phosphorus and / or boron. In a further exemplary embodiment, the porous element can be made of stainless steel , consist of a particularly doped, ceramic, Kanthal or the like. Rare earths, for example antimony, germanium, or the like, are particularly suitable for doping the ceramic.

The Inconel alloy used in the exemplary embodiment is largely, in particular completely, corrosion-resistant. In particular, the Inconel alloy used is corrosion-resistant to the liquid 5 , In particular, the Inconel alloy has a high specific resistance compared to stainless steel and other corrosion-resistant alloys.

The strength of the Inconel alloy used in the exemplary embodiment remains over a wide temperature range, in particular in the temperature range between approximately -10 ° C., preferably approximately 15 ° and up to approximately 300 ° C., preferably up to approximately 250 ° C., particularly preferably up to approximately 240 ° C obtained.

The electrical contacts 23 . 24 consist in the embodiment of a metal, for example copper, aluminum, steel or the like.

In the manufacture of the one-piece evaporation element in particular 22 for the evaporator 7 in the electric cigarette 1 a 3D printer, not shown in the figures, is used. The corrosion-resistant nickel-based alloy, in particular the Inconel alloy, is used in particular as the printing material. It is printed in such a way that the density of the resulting metal foam becomes inhomogeneous, in particular the density in the interior of the evaporation element 22 is less than close to a wall 33 of the evaporation element 22 ,

To hold the evaporation element 22 becomes an in when printing in the 3D printing machine 15 schematically shown foot 34 printed. In the embodiment, two feet 34 printed. In the embodiment, the feet 34 on the ground 31 printed. In a further embodiment, the feet can also be on the ceiling 32 be printed. In a further embodiment, the feet 34 also on the wall 33 be printed. The feet 34 are removed after printing, in particular the feet are removed by eroding or by laser cutting or by filing or the like. A predetermined breaking point on the feet is particularly useful 34 printed. So that the feet 34 be removed particularly well. Alternatively, the foot 34 can be used as an electrical contact, for example as a pin. In this case the foot 34 not removed.

Claims (11)

Vaporizing element for a vaporizer (7) in an electric cigarette (1), the vaporizing element (22) comprising a base (31), a ceiling (32) and a wall (33), the vaporizing element (22) consisting of a porous element consists, wherein the porous element serves as an electrical heating element and as a liquid carrier. Evaporation element after Claim 1 , characterized in that the porous element has an inhomogeneous density. Evaporation element after Claim 1 or 2 , characterized in that the density of the porous element inside the evaporation element (22) is less than the density of the porous element close to the wall (33). Evaporation element according to one of the Claims 1 to 3 , characterized in that the wall (33) is permeable to a liquid (5), and in particular that the bottom (31) and the ceiling (32) are impermeable to liquids (5). Evaporation element according to one of the Claims 1 to 4 , characterized in that the porous element made of a corrosion-resistant nickel-based alloy, in particular an Inconel alloy. Evaporation element according to one of the Claims 1 to 5 , characterized in that the evaporation element (22) has an inner surface, the inner surface of the evaporation element (22) at least approximately 20 mm ² , particularly advantageously at least approximately 40 mm ² , and at most approximately 60 mm ² , particularly advantageously at most approximately 50 mm ² . Evaporation element according to one of the Claims 1 to 6 , characterized in that the evaporation element (22) is cylindrical, in particular that the cylindrical evaporation element (22) has a diameter (D) of about 1 mm, particularly advantageously of about 2 mm, and in particular that the cylindrical evaporation element (22) has a Has height (H) of about 0.8 mm, particularly advantageously of about 1.2 mm. Evaporation element according to one of the Claims 1 to 7 , characterized in that the evaporation element (22) is a 3D printed part. Evaporation element according to one of the Claims 1 to 8th , characterized in that the porous element is a metal foam. Method for producing an in particular one-part evaporation element (22) for an evaporator (7) in an electric cigarette (1), the evaporation element (22) being printed in layers in an additive manufacturing process, in particular with a 3D printer, the printing material in particular a corrosion-resistant nickel-based alloy, in particular an Inconel alloy, is used, printing being carried out in such a way that the density of the resulting porous element becomes particularly inhomogeneous, the density in the interior of the evaporation element (22) in particular being less than close to a wall (33) of the evaporation element (22). Method for producing an evaporation element according to Claim 10 , characterized in that when printing to hold the evaporation element (22), in particular in the 3D printing machine, a foot (34) is printed, the foot (34) being removed after printing, in particular that the foot (34) is removed Eroding or removed by laser cutting or by filing or by cutting at a predetermined breaking point or the like.

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