DE202020107169U1 - Cooling device and cooling unit with at least one cooling device - Google Patents

Abstract

Cooling device (1), comprising at least one circumferentially liquid-tight closed cooling channel (2) which has an inlet opening (4) at one end and an outlet opening (5) at the other end, with a length of the at least one cooling channel (2) by a Is several times greater than a width and a height of the at least one cooling channel (2), an outer shell of the at least one cooling channel (2) being formed from a liquid-tight polymer film (3), with a carrier textile (6) in the at least one cooling channel (2). is arranged to stabilize the cross-section of the cooling channel (2), and wherein on at least one circumferential side, in particular the broad side, of the at least one cooling channel (2) on the inside of the polymer film (3) is a partially perforated and unperforated sections (7) with the polymer film (3 ) connected, in particular welded, humidifying membrane (8) and a humidifier on the inside of the humidifying membrane (8) gkeitsspeicher (9) is arranged, wherein the carrier textile (6) is arranged adjacent to the inside of the moisture reservoir (9), and an electrically driven fan (10) to the inlet opening (4) and / or to the outlet opening (5) Passing ambient air through the at least one cooling channel (2) is arranged.

Description

The invention relates to a cooling device and a cooling unit with at least one cooling device.

From the prior art, as in the DE 10 2011 016 482 A1 described, a reusable protective textile for objects as well as for the body of humans and animals known. The protective textile consists of passive and active cooling or air-conditioning materials. Their construction is designed in such a way that the body or the object experiences less heat stress compared to previously used protective textiles.

The invention is based on the object of specifying a cooling device that is improved over the prior art and a cooling unit with a cooling device that is improved over the prior art.

The object is achieved according to the invention by a cooling device with the features of claim 1 and a cooling unit with at least one cooling device with the features of claim 6.

Advantageous refinements of the invention are the subject matter of the subclaims.

A cooling device according to the invention comprises at least one cooling channel. This cooling channel is an elongated structure. A length of the at least one cooling channel is therefore several times, in particular many times greater than a width and a height of the at least one cooling channel. For example, its length is at least three times greater than its width and / or its height. The at least one cooling channel is closed on the circumferential side in a liquid-tight manner. An outer shell of the at least one cooling channel is formed from a liquid-tight polymer film, for example from thermoplastic polyurethane. In particular, this means that the at least one cooling channel is closed on the circumferential side in a liquid-tight manner.

The at least one cooling channel has an inlet opening at one end and an outlet opening at the other end. The inlet opening is provided in particular for introducing ambient air into the at least one cooling channel, which air flows through the at least one cooling channel and flows out at its outlet opening.

A carrier textile for stabilizing the cross section of the cooling channel is arranged in the at least one cooling channel in order to maintain the cross section of the cooling channel, i. H. to prevent the cooling channel from collapsing or squeezing, so that air can always flow through the cooling channel.

On at least one circumferential side, in particular the broad side, of the at least one cooling channel, on the inside of the polymer film, there is a humidifying membrane that is perforated in sections and connected to the polymer film with imperforate sections, in particular welded, and a moisture reservoir is arranged on the inside of the humidifying membrane. The carrier textile is arranged adjacent to the inside of the moisture reservoir. At the inlet opening and / or at the outlet opening of the at least one cooling channel, an electrically driven fan for guiding ambient air through the cooling channel is arranged. If the fan is arranged at the inlet opening, it introduces the ambient air via the inlet opening into the cooling duct and it then flows through the cooling duct and out via the outlet opening. If, alternatively or additionally, the fan is arranged at the outlet opening, it sucks in the ambient air through the cooling channel via its inlet opening, into the cooling channel, through it and it then flows out of the cooling channel via the outlet opening and the fan arranged on it . Two fans can thus also be provided on at least one or respective cooling channel, one on the inlet opening and one on the outlet opening.

The solution according to the invention enables the surroundings of the at least one cooling channel to be cooled by evaporative cooling, the evaporation taking place exclusively in the interior of the at least one cooling channel, i. H. no moisture gets from the at least one cooling channel into its surroundings, in particular not over its circumference, since the cooling channel is designed to be liquid-tight on the circumference.

Evaporative cooling is made possible by the fact that liquid, in particular water, is conducted to the moisture reservoir via the humidifying membrane. It flows over the perforated sections of the humidifying membrane, which are positioned between the imperforate sections, into the moisture reservoir. This liquid is stored in the moisture reservoir and evaporates through an air stream of the ambient air flowing into and flowing through the at least one cooling channel by means of the fan, this ambient air flowing past this moisture reservoir while flowing through the cooling channel. This evaporation generates cold, ie a temperature reduction, as a result of which the at least one cooling duct becomes colder than its surroundings and thus cools its surroundings. The circumference of the cooling channel, ie at least one The circumferential side, in particular the broad side, for example opposite circumferential sides, in particular broad sides, or all the circumferential sides of the at least one cooling channel, ie both opposite broad sides and both high sides of the cooling channel connecting the two broad sides, thus forms / form a cooling surface for cooling the surroundings of the at least one cooling channel .

The liquid used, for example the water, is advantageously mixed with an antimicrobial agent in order to advantageously reduce the risk of contamination of the cooling device, i. H. for example, to avoid or at least reduce the formation of bacteria and / or fungi.

For a sufficient air flow through the cooling duct, only a relatively low power of the fan is advantageously required, for example an electrical drive power of 1.5 W is sufficient. For the electrical energy supply of the at least one or the respective fan, for example a battery or an accumulator, i. H. a rechargeable battery is provided. Depending on the application, the fan can alternatively or additionally have, for example, a mains connection for connection to an electrical energy supply network.

In one possible embodiment of the cooling device, on opposite circumferential sides, in particular broad sides, of the at least one cooling channel on the inside of the polymer film, a humidifying membrane that is perforated in sections and connected to the polymer film with unperforated sections, in particular welded, and a moisture reservoir is arranged on the inside of the respective humidifying membrane , wherein the carrier textile is arranged between the two moisture reservoirs, resting against their respective inside. This enables a stronger supply of liquid and an evaporation surface exposed to the air flow through the at least one cooling channel is enlarged, since the air flow of the ambient air introduced into the cooling channel and flowing through it now flows past both moisture stores and liquid is evaporated from both moisture stores.

In one possible embodiment it can be provided, for example, that the humidifying membrane and the moisture reservoir each extend over the entire circumference of the at least one cooling channel, i. H. a humidifying membrane is then arranged over the entire circumference of the at least one cooling channel on the inside of the polymer film, perforated in sections and connected to the polymer film with imperforate sections, in particular welded, and on the inside of the humidifying membrane, likewise over the entire circumference of the cooling channel, arranged a moisture storage. The carrier textile is arranged in the remaining interior space of the cooling channel and rests against the inside of the moisture reservoir. As a result, a maximum evaporation surface of the moisture storage device is achieved, past which the air stream flows, and a moisture storage capacity of the moisture storage device is thereby maximized.

In one possible embodiment, the at least one or the respective moisture reservoir is designed as a fleece, in particular as a superabsorbent fleece. As a result, a very high liquid storage capacity and thus a very long evaporative cooling is achieved before liquid has to be refilled. The superabsorbent nonwoven comprises, for example, a hydrophilic polymer or a plurality of hydrophilic polymers. For example, it is formed from one or more such hydrophilic polymers or the at least one or more hydrophilic polymers is / are incorporated into the fleece, for example connected to it.

The at least one or the respective humidification membrane is in particular perforated and connected to the unperforated sections with the polymer film, in particular welded, in such a way that a humidification channel structure is formed between the humidification membrane and the polymer film along the cooling channel from its inlet opening in the direction of its outlet opening, with a The liquid inlet of the humidification channel structure is advantageously arranged at the inlet opening and wherein the humidification channel structure is advantageously closed at the outlet opening. Alternatively, it can also be provided, for example, that the liquid inlet of the humidification channel structure is arranged at the outlet opening and the humidification channel structure is advantageously closed at the inlet opening. The liquid is thus filled in via the liquid inlet of the humidification membrane and distributed via its humidification channel structure along the cooling channel and thus along the moisture reservoir and penetrates through the perforated sections of the humidification membrane into the moisture reservoir. In this way, a uniform distribution of the liquid and thus a uniform humidification of the moisture reservoir is achieved in a particularly advantageous manner. In particular, local over-humidification and the resultant leakage of liquid from the cooling channel are avoided as a result. Due to the uniform humidification of the moisture reservoir, evaporation of the liquid over the entire area exposed to the air flow is also achieved Area of the moisture storage and thus an optimized cooling effect ensured.

In one possible embodiment, the cooling device comprises a liquid metering unit with a moisture sensor system, which advantageously comprises a plurality of moisture sensors distributed along the at least one cooling channel, and with a liquid supply unit fluidly coupled to the liquid inlet of the at least one or the respective humidification channel structure for the metered supply of liquid via the at least one or respective humidification membrane for the at least one or respective moisture reservoir as a function of a moisture determination by means of the moisture sensor system. As a result, liquid can be supplied to the moisture reservoir in good time before it dries out, so that a constant cooling effect is advantageously achieved. Alternatively, the moisture sensor system can have only one moisture sensor, for example. Alternatively, provision can be made, for example, that the supply of liquid is carried out manually, i. H. not by the above-described liquid metering unit for automatic liquid supply, but manually by means of the liquid supply unit. As a result, the cooling device can, for example, be made smaller and with a lower weight, since in particular the liquid supply unit does not have to be fluidically coupled to the liquid inlet of the at least one or the respective humidification channel structure, but is only coupled accordingly when the manual liquid supply is carried out. In this embodiment, too, the moisture sensor system can be present with one or more moisture sensors, which then signal the requirement of the liquid supply, for example by means of an optical, acoustic and / or haptic signal output.

A cooling unit according to the invention comprises at least one such cooling device. In one possible embodiment, this cooling unit is designed as a cooling textile, in particular as a cooling vest. Such a cooling unit achieves active cooling of a person wearing this cooling unit by means of evaporative cooling, it being particularly advantageous that the moisture which is used for this evaporative cooling does not reach the person, ie. H. the person is not moistened, but only cooled. This is ensured by the circumferentially liquid-tight design of the at least one or the respective cooling channel. In this way, damp clothing, which is uncomfortable to wear, is avoided.

The active cooling is ensured by the fan at the inlet opening of the at least one or the respective cooling channel, since in this way air from the environment is actively passed through the at least one or the respective cooling channel, whereby the evaporation and thus the resulting evaporative cooling in comparison passive evaporative cooling, d. H. without an airflow driven by the fan, is significantly increased. This cooling unit, which is designed as a cooling textile, in particular a cooling vest, can be worn, for example, by a person working on a blast furnace, in order to considerably extend a possible working time at the blast furnace. For example, without the cooling by this cooling unit, only a working time of a maximum of 15 minutes is possible due to the high temperatures. Due to the uniform evaporation of the liquid from the at least one or from the respective moisture reservoir, the cooling unit enables, for example, an operating time of the cooling unit and thus a cooling effect on the person of eight hours, so that a much longer working time, for example eight hours, is achieved by means of the cooling unit cooled person is enabled even at high temperatures.

Alternatively, the cooling textile, in particular the cooling vest, can also be provided for motorcyclists, for example. This enables the person in question to be cooled even in applications in which cooling by means of a conventional air conditioning system is not possible.

In a further possible embodiment, the cooling unit is designed, for example, as a room cooling unit for cooling a room in a building. This enables room cooling in a simple manner, advantageously without a disruptive cool air flow, because in the cooling unit according to the invention the cooling takes place exclusively via the peripheral cold radiation of the at least one or the respective cooling channel and not via the air flow flowing through the cooling channel. This air flow is thus advantageously not used to cool the room, but instead, for example, is diverted from the room or directed back to the inlet opening of the cooling channel. In particular, this avoids the entry of moisture from the evaporated moisture contained in this air flow into the room. In addition, the often disruptive cold air flow of conventional air conditioning systems is avoided. This evaporative cooling is also particularly energy-efficient compared to conventional air conditioning systems, since only electrical energy is required to drive the fan.

In a further possible embodiment, the cooling unit is, for example, as one Vehicle cooling unit designed for cooling a passenger compartment of a vehicle. Here, too, cooling of the passenger compartment is made possible in a simple manner, advantageously without a disruptive cool air flow, because with the cooling unit according to the invention the cooling takes place exclusively via the peripheral cold radiation of the at least one or the respective cooling channel and not via the air flow flowing through the cooling channel. This air flow is therefore advantageously not used to cool the passenger compartment, but instead is diverted from the passenger compartment, for example, or directed back to the inlet opening of the cooling channel. In particular, this avoids the entry of moisture from the evaporated moisture contained in this air flow into the passenger compartment. In addition, the often disruptive cold air flow of conventional air conditioning systems is avoided. This evaporative cooling is also particularly energy-efficient compared to conventional air conditioning systems, since only electrical energy is required to drive the fan. The solution described is therefore also suitable for cooling the passenger compartment when the vehicle is at a standstill, particularly advantageously also for cooling a passenger compartment of vehicles designed as caravans or mobile homes.

In a further possible embodiment, the cooling unit is designed, for example, as a seat, in particular a child seat, in particular as a seat back of such a seat, in particular as a child seat back of such a child seat. This enables direct cooling of the person sitting in the seat, in particular the child seat, and the cold air flow of conventional air conditioning systems, which is often disruptive or not suitable for small children, is avoided. Through direct body contact with the cooling seat, in particular a child seat, particularly energy-efficient cooling is also achieved, since no entire interior, in particular the passenger compartment, has to be cooled.

In the case of the cooling unit designed as a cooling textile or seat, the at least one cooling channel or the respective cooling channel is advantageously oriented vertically or at least substantially vertically, with the inlet opening advantageously being at the top and the outlet opening at the bottom. In particular, the at least one cooling channel or the respective cooling channel is aligned such that the outlet opening is positioned below the inlet opening and advantageously has a height distance from the inlet opening which advantageously corresponds, at least essentially, to a length of the cooling channel or at least a predominant part of the length of the cooling channel . This achieves the particular advantage that gravity is used to distribute the liquid filled in, in particular via the liquid inlet of the humidification membrane, whereby the liquid runs along the humidification channel structure of the humidification membrane and reaches the moisture reservoir through the perforated sections. A uniform distribution of the liquid in the moisture reservoir is thus achieved in a particularly simple manner. Since the inlet opening is arranged at the top, a good flow through the respective cooling channel with the air that is increasingly colder due to the evaporative cooling in the course of the cooling channel is achieved, since the colder air sinks by itself. In particular, this avoids a build-up of air in the respective cooling duct. This also ensures that there is particularly strong evaporation in the area of the inlet opening due to the still very warm air. As a result, a build-up of moisture in this area of the moisture reservoir, to which the filled liquid first reaches and which is therefore particularly moist, is avoided.

Alternatively, it can be provided, for example, that in the cooling unit embodied as a cooling textile or seat and the at least one or respective cooling channel advantageously vertically or at least substantially vertically aligned thereon, the inlet opening is at the bottom and the outlet opening is at the top. In particular, the at least one cooling channel or the respective cooling channel is then aligned in such a way that the inlet opening is positioned below the outlet opening and advantageously has a height distance from the outlet opening which is advantageously, at least substantially, the length of the cooling channel or at least the predominant part of the length of the cooling channel corresponds to. This also has the particular advantage that gravity is used to distribute the liquid filled in, in particular via the liquid inlet of the humidification membrane, whereby the liquid runs along the humidification channel structure of the humidification membrane and reaches the moisture reservoir through the perforated sections. In this case in particular, the liquid inlet of the humidification channel structure is advantageously arranged at the outlet opening and the humidification channel structure is advantageously closed at the inlet opening. In this way, too, a uniform distribution of the liquid in the moisture reservoir is achieved in a particularly simple manner.

In the case of the cooling unit designed as a cooling textile, in particular a cooling vest, the cooling channel or the respective cooling channel covers only a partial area of the cooling textile. For example, several cooling channels are provided, for example several cooling channels of the same cooling device or several cooling devices, each with a cooling channel. The cooling channels are arranged at a distance from one another. In this way, between the Cooling channels allows air and / or liquid to circulate through the cooling textile in order, for example, to be able to discharge body fluid of the person wearing the cooling textile to the outside. Due to the circumferentially liquid-tight design of the respective cooling channel, this is not possible in the area of the respective cooling channel.

In the cooling unit designed as a cooling textile, in particular a cooling vest, the at least one or the respective cooling channel is advantageously arranged on an inside facing the person wearing the cooling unit or between an inner textile layer and an outer textile layer of the two-layer cooling textile. As a result, an optimized cooling of the person is achieved and a loss of cold into the environment is minimized. This arrangement on the inside or between the textile layers is made possible in particular by the circumferentially liquid-tight design of the at least one or the respective cooling channel, since in this way no moisture can reach the person from the at least one or the respective cooling channel. An additional liquid-tight shielding of the at least one or the respective cooling channel in the direction of the person by the cooling textile, d. H. through textile layers of the cooling textile is therefore not necessary. This makes it possible, for example, to use a conventional, in particular non-liquid-tight and for example breathable, piece of textile, for example a conventional vest, and to arrange one or more cooling devices thereon in order to form the cooling unit in this way. This has the advantage that the breathability between the spaced apart cooling channels is maintained, in contrast to a cooling textile with a cooling function that acts over the entire surface or over a substantial area of the cooling textile, since here then either a corresponding full-area or liquid-tight design of the essential area of the Cooling textile would be required and thus no breathability of the cooling textile would be possible, or unpleasant humidification of the person wearing the cooling textile would be unavoidable.

The cooling textile, designed for example as a cooling vest, is advantageously designed in such a way that both the inlet opening and the outlet opening of the at least one or the respective cooling channel are in fluidic connection with an external environment, in particular with the ambient air, for example by having both the inlet opening and the outlet opening of the at least one or the respective cooling channel are arranged on an outside of the cooling textile, for example designed as a cooling vest, or by the inlet opening of the at least one or the respective cooling channel being arranged on the outside of the cooling textile, for example, designed as a cooling vest and the outlet opening between the two textile layers of the two-ply formed cooling textile is arranged and the cooling textile, designed for example as a cooling vest, has at least one outlet opening or several outlet openings in its outer textile layer, so that the air flows through the flow through the respective cooling channel, from the outlet opening of which can flow between the two textile layers and can flow outward from the respective outlet opening of the outer textile layer. Alternatively or additionally, the fluidic connection with the external environment, in particular the ambient air, can be achieved, for example, by arranging the outlet opening of the at least one or the respective cooling channel on the outside of the cooling textile, which is designed, for example, as a cooling vest, and the inlet opening is arranged in two layers between the two textile layers formed cooling textile is arranged and the cooling textile, designed for example as a cooling vest, has at least one inlet opening or several inlet openings in its outer textile layer, so that the air flows through the respective inlet opening of the outer textile layer between the two textile layers, flows into the cooling channel through the inlet opening and flows through it and can flow out from its outlet opening. As an alternative or in addition, the fluidic connection with the external environment, in particular the ambient air, can be achieved, for example, by arranging both the outlet opening and the inlet opening of the at least one or respective cooling channel between the two textile layers of the two-layer cooling textile and which is designed, for example, as a cooling vest Cooling textile has at least one or more inlet openings and at least one or more outlet openings in its outer textile layer, so that the air flows through the respective inlet opening of the outer textile layer between the two textile layers, flows into the cooling channel through the inlet opening and flows through it, from its outlet opening between the two textile layers flow and can flow outwards from the respective outlet opening of the outer textile layer.

In the case of the cooling unit designed as a cooling textile, in particular a cooling vest, the cooling device or the respective cooling device, in particular the at least one or the respective cooling channel, can for example be or be attached subsequently, that is, for example, a conventional piece of textile, for example a vest or jacket be formed simply by attaching the at least one or the respective cooling device, in particular the at least one or the respective cooling channel, as a cooling textile. It can be attached to the textile piece, for example, in a form-fitting and / or cohesive manner, for example not detachable or non-destructively Can be removed non-destructively, for example by sewing and / or gluing to the piece of textile or by means of a zip and / or Velcro fastener. Attaching by means of a zipper and / or Velcro fastener has the particular advantage that the piece of textile, if the cooling function is not required, can also be worn without the cooling device or the respective cooling device, in that it is then removed from the textile piece without being destroyed and at a later point in time can be reattached when the cooling function is needed again.

The cooling unit designed as a room cooling unit is advantageously designed as a room ceiling cooling unit for arrangement on a ceiling of the room. This achieves a particularly effective cooling of the room, since warm air of the room rises in the direction of the ceiling of the room, cools down on the cooling unit designed as a ceiling cooling unit, in particular on its one or more cooling channels, and then sinks again, so that the air in a lower one The area of the room in which people are present has cooled down accordingly. The at least one cooling channel or the respective cooling channel is oriented horizontally or at least essentially horizontally in the cooling unit arranged on the ceiling of the room.

• 1 schematisch eine Längsschnittdarstellung einer Kühlvorrichtung,
• 2 schematisch eine Draufsicht auf eine Befeuchtungsmembran der Kühlvorrichtung,
• 3 schematisch eine Vorderansicht einer als Kühltextil, insbesondere Kühlweste, ausgebildeten Kühleinheit,
• 4 schematisch eine Rückseitenansicht der als Kühltextil, insbesondere Kühlweste, ausgebildeten Kühleinheit, und
• 5 schematisch eine Kühlvorrichtung der als Kühltextil, insbesondere Kühlweste, ausgebildeten Kühleinheit in einer Draufsicht auf eine Breitseite eines Kühlkanals der Kühlvorrichtung.

Embodiments of the invention are explained in more detail below with reference to drawings. Show in it:

• 1 schematically a longitudinal sectional view of a cooling device,
• 2 schematically a top view of a humidifying membrane of the cooling device,
• 3 schematically a front view of a cooling unit designed as a cooling textile, in particular a cooling vest,
• 4th schematically a rear view of the cooling unit designed as a cooling textile, in particular a cooling vest, and
• 5 schematically, a cooling device of the cooling unit designed as a cooling textile, in particular a cooling vest, in a plan view of a broad side of a cooling channel of the cooling device.

Corresponding parts are provided with the same reference symbols in all figures.

1 shows a schematic longitudinal sectional illustration of an embodiment of a cooling device 1 . The cooling device shown here 1 enables active evaporative cooling.

The cooler 1 comprises a cooling channel in the example shown 2 . This cooling duct 2 is an elongated structure. A length of the cooling channel 2 is thus several times, in particular several times, greater than a width and a height of the cooling channel 2 . For example, its length is at least three times greater than its width and / or its height.

The cooling duct 2 is closed on the periphery in a liquid-tight manner. An outer shell of the cooling duct 2 is made of a liquid-tight polymer film 3 educated. In particular, this is the cooling channel 2 circumferentially closed in a liquid-tight manner.

The cooling duct 2 has an inlet opening at one end 4th and an outlet opening at the other front end 5 on. The inlet opening 4th is in particular for introducing ambient air into the cooling duct 2 provided which the cooling channel 2 flows through and at its outlet opening 5 emanates.

In the cooling duct 2 is a carrier textile 6th to stabilize the cross-section of the cooling channel 2 arranged around the cross section of the cooling channel 2 to maintain, ie a collapse or compression of the cooling channel 2 to prevent, so that the flow through the cooling channel 2 is always ensured with air.

In the example shown, the cooling channel is on opposite circumferential sides, here on opposite broad sides 2 on the inside of the polymer film 3 one section perforated and one with imperforate sections 7th with the polymer film 3 welded humidification membrane 8th and on the inside of the respective humidifying membrane 8th a moisture store designed as a fleece, in particular as a superabsorbent fleece 9 arranged.

The carrier textile 6th is between the two moisture stores 9 , adjacent to their respective inside, arranged.

In another embodiment it can be provided, for example, that the humidifying membrane 8th and the moisture storage 9 each over the entire circumference of the cooling channel 2 extends, ie it is then over the entire circumference of the cooling channel 2 on the inside of the polymer film 3 the sections perforated and with imperforate sections 7th with the polymer film 3 welded humidification membrane 8th arranged and on the inside of the humidifying membrane 8th is, also over the entire circumference of the cooling channel 2 , the moisture store 9 arranged. The carrier textile 6th is then in the remaining interior of the cooling channel 2 arranged and lies on the inside of the moisture reservoir 9 at.

In another embodiment it can be provided that only on one circumferential side, in particular the broad side, of the cooling channel 2 on the inside of the polymer film 3 one section perforated and one with imperforate sections 7th with the polymer film 3 welded humidification membrane 8th and on the inside of the humidifying membrane 8th a moisture reservoir 9 is arranged. The carrier textile 6th is then on the inside of the moisture reservoir 9 arranged adjacent.

In each embodiment is at the inlet port 4th of the cooling duct 2 an electrically driven fan 10 for introducing ambient air through the inlet opening 4th in the cooling duct 2 arranged.

2 shows the humidifying membrane 8th in plan view. It is so perforated and with the imperforate portions 7th such with the polymer film 3 that welded between the humidifying membrane 8th and the polymer film 3 a humidification channel structure 11 along the cooling channel 2 from its inlet opening 4th in the direction of its outlet opening 5 is formed, with a liquid inlet 12th the humidification channel structure 11 at the inlet port 4th is arranged and wherein the humidification channel structure 11 at the outlet opening 5 is closed, as shown here, by an imperforate section 7th across the entire width of the humidifying membrane 8th . The liquid is thus via the liquid inlet 12th the humidification membrane 8th filled in and over their humidification channel structure 11 along the cooling channel 2 and thus along the moisture reservoir 9 distributes and penetrates through the perforated sections of the humidifying membrane 8th , which between the imperforate sections 7th are positioned through into the moisture reservoir 9 a. In a particularly advantageous manner, this results in a uniform distribution of the liquid and thus a uniform humidification of the moisture reservoir 9 reached.

The 3 and 4th show a cooling unit designed as a cooling textile in the form of a cooling vest 13th with a plurality of the cooling devices described above 1 . 3 shows a front view and 4th a rear view of this cooling unit 13th . As shown here, this comprises a cooling unit designed as a cooling vest 13th a cooling device on its back 1 with a cooling channel 2 and on their front side, next to one another and at a distance from one another, two cooling devices 1 with one cooling channel each 2 .

By such a cooling unit 13th becomes an active cooling of this cooling unit 13th wearing person achieved by evaporative cooling, it being particularly advantageous that the moisture that is used for this evaporative cooling does not get to the person, ie the person is not moistened, but only cooled. This is achieved through the liquid-tight design of the respective cooling channel on the circumferential side 2 ensured. In this way, damp clothing, which is uncomfortable to wear, is avoided. The active cooling is done by the fan 10 at the inlet port 4th of the respective cooling channel 2 ensures that air from the environment is actively passed through the respective cooling duct in this way 2 is passed through, whereby the evaporation and thus the resulting evaporative cooling compared to a passive evaporative cooling, ie without one by the fan 10 driven airflow, is significantly amplified.

This cooling unit designed as a cooling textile, in particular a cooling vest 13th can, for example, be carried by a person working on a blast furnace in order to considerably extend possible working hours at the blast furnace. For example, there is no cooling by this cooling unit 13th Due to the high temperatures, only a maximum of 15 minutes working time is possible. The cooling unit 13th made possible due to the uniform evaporation of the liquid from the respective moisture reservoir 9 for example, a usage time of the cooling unit 13th and thus a cooling effect of eight hours on the person, so that a considerably longer working time, for example eight hours, is achieved by means of the cooling unit 13th cooled person is enabled even at high temperatures. Alternatively, the cooling unit embodied as a cooling textile, in particular as a cooling vest, can be used 13th for example, be provided for motorcyclists. As a result, cooling of the respective person is made possible even in those applications in which cooling by means of a conventional air conditioning system is not possible.

With this cooling unit designed as a cooling textile, in particular a cooling vest 13th is the respective cooling channel 2 oriented vertically or at least substantially vertically, the inlet opening 4th above and the outlet opening 5 is down. The respective cooling channel 2 is thus oriented such that the outlet opening 5 below the inlet opening 4th is positioned and a height distance to the inlet opening 4th which has a length of the cooling channel 2 or at least a major part of the length of the cooling channel 2 corresponds to.

This achieves the particular advantage that for distributing the, in particular via the liquid inlet 12th the humidification membrane 8th When the liquid is filled, gravity is used, causing the liquid to move along the humidification channel structure 11 the humidification membrane 8th runs and through the perforated sections to the moisture storage 9 got. So it becomes special simple way an even distribution of the liquid in the moisture reservoir 9 reached. As the inlet port 4th is arranged at the top, there is also a good flow through the cooling channel 2 with that of the evaporative cooling in the course of the cooling channel 2 increasingly colder air, as the colder air sinks by itself. In particular, this creates a build-up of air in the respective cooling duct 2 avoided. This also ensures that in the area of the inlet opening 4th a particularly strong evaporation through which then still very warm air takes place. This creates a build-up of moisture in this area of the moisture reservoir 9 , to which the filled liquid reaches first and which is therefore particularly moist, avoided.

In the case of the cooling unit designed as a cooling textile, in particular a cooling vest 13th covers the respective cooling channel 2 only part of the cooling textile, as in the 3 and 4th shown. There are several cooling channels 2 provided, for example several cooling channels 2 same cooler 1 or, as shown here, multiple cooling devices 1 with one cooling channel each 2 . The cooling channels 2 are arranged at a distance from one another. In this way, between the cooling channels 2 allows air and / or liquid to circulate through the cooling textile, for example, in order to be able to discharge body fluid of the person wearing the cooling textile to the outside. I. E. between the cooling channels 2 breathability of the cooling textile can be ensured. Due to the circumferential liquid-tight design of the respective cooling channel 2 this is in the area of the respective cooling channel 2 not possible.

In the case of the cooling unit shown here, designed as a cooling textile, in particular a cooling vest 13th is the respective cooling channel 2 advantageously on one to the cooling unit 13th wearing person facing inside or, as shown in the example shown, between an inner textile layer 14th and an outer textile layer 15th of the two-layer cooling textile arranged in this example. As a result, an optimized cooling of the person is achieved and a loss of cold into the environment is minimized. This arrangement on the inside or between the textile layers 14th , 15th is in particular due to the circumferential liquid-tight design of the respective cooling channel 2 allows, since in this way no moisture from the respective cooling channel 2 can get to the person. An additional liquid-tight shield of the respective cooling channel 2 in the direction of the person through the cooling textile, ie through textile layers of the cooling textile, is therefore not necessary. This makes it possible, for example, to use a conventional, in particular non-liquid-tight and for example breathable, piece of textile, for example a conventional vest, and one or, as in the example shown, several cooling devices on it 1 to arrange in this way the cooling unit 13th to train. This has the advantage already described above that the breathability between the spaced apart cooling channels 2 is retained, in contrast to a cooling textile with a cooling function that acts closed over the entire surface or over a substantial area of the cooling textile, since here then either a corresponding full-surface or liquid-tight design of the cooling textile would be required and thus no breathability of the cooling textile would be possible, or unpleasant humidification of the person wearing the cooling textile would be unavoidable.

The cooling textile designed as a cooling vest is advantageously designed in such a way that both the inlet opening 4th as well as the outlet opening 5 of the respective cooling channel 2 are in fluidic connection with an external environment, in particular with the ambient air, for example by both the inlet opening 4th as well as the outlet opening 5 of the respective cooling channel 2 are arranged on an outside of the cooling textile designed as a cooling vest, or, as in the example shown here, by the inlet opening 4th of the respective cooling channel 2 is arranged on the outside of the cooling textile designed as a cooling vest and the outlet opening 5 between the two textile layers 14th , 15th of the two-layer cooling textile in this example is arranged and the cooling textile designed as a cooling vest in its outer textile layer 15th at least one outlet opening 16 or, as shown here, several outlet openings 16 has so that the air through the respective cooling channel 2 flow through, from its outlet opening 5 between the two textile layers 14th , 15th flow and out of the respective outlet opening 16 the outer textile layer 15th can flow out to the outside. This creates an additional flow of cold air between the two textile layers 14th , 15th reached and at the same time moisture is avoided in the direction of the person wearing the cooling textile, since that from the respective cooling channel 2 escaping air does not get directly to the person.

In the case of the cooling unit designed as a cooling textile, in particular a cooling vest 13th can the respective cooling device 1 , especially the respective cooling channel 2 , for example, can be or be attached subsequently, that is to say, for example, a conventional, for example also breathable, piece of textile, for example a vest or jacket, can be simply attached by attaching the respective cooling device 1 , in particular of the respective cooling channel 2 , be designed as a cooling textile. It can be attached to the textile piece, for example, in a form-fitting and / or cohesive manner, for example non-destructively detachable or non-destructively detachable again, for example by sewing and / or gluing to the textile piece or by means of Zip and / or Velcro fastener. Attachment by means of a zip fastener and / or Velcro fastener has the particular advantage that the textile piece, when the cooling function is not required, even without the respective cooling device 1 can be worn in that it is then removed from the piece of textile again without being destroyed and can be attached again at a later point in time when the cooling function is needed again.

5 shows one of the cooling devices 1 the cooling unit designed as a cooling textile, in particular a cooling vest 13th in a plan view of a broad side of the cooling channel 2 . This is also where the dimensioning of the cooling duct is made 2 clearly as an elongated structure. The cooling duct 2 has, for example, a width of 10 cm and a length including the fan 10 of 39 cm, ie the length of the cooling channel 2 is much larger than its width.

If the cooling vest is worn, for example, to cool a person working on the blast furnace, the person can wear an aluminum-coated protective jacket over it, for example. This protective jacket advantageously has openings around the air inlet in the respective cooling duct 2 and the air outlet from the respective cooling duct 2 to enable the cooling vest worn underneath. These openings are advantageously covered with flaps in order to allow air to flow but to avoid direct heat radiation.

The solution described and illustrated here enables the surroundings of the respective cooling channel to be cooled 2 and thus, in the exemplary embodiment of the cooling textile designed as a cooling vest, cooling of the person wearing this cooling textile by evaporative cooling, the evaporation exclusively in the interior of the respective cooling channel 2 takes place, ie no moisture comes out of the respective cooling channel 2 in its surroundings, in particular not over its circumference, as the cooling channel 2 is formed liquid-tight on the circumference.

The evaporative cooling is made possible by liquid, in particular water, over the humidifying membrane 8th for moisture storage 9 is directed. It flows over the perforated sections of the humidifying membrane 8th in the moisture reservoir 9 . In the moisture reservoir 9 this liquid is stored and evaporated by a stream of air by means of the fan 10 in the cooling duct 2 ambient air flowing in and flowing through it, this ambient air being flowing through the cooling channel 2 on this moisture reservoir 9 flows past. This evaporation creates cold, ie a temperature reduction, which causes the cooling duct 2 becomes colder than its surroundings and thus cools its surroundings.

The scope of the respective cooling channel 2 thus forms a cooling surface for cooling the surroundings of the respective cooling channel 2 . For a sufficient flow of air through the respective cooling duct 2 through this is only a relatively low power of the respective fan 10 required, for example an electrical drive power of 1.5 W is sufficient. For the electrical energy supply of the respective fan 10 For example, a battery or an accumulator, ie a rechargeable battery, is provided. Depending on the application, the fan can 10 , alternatively or additionally, for example, have a network connection for connection to an electrical energy supply network.

List of reference symbols

1

Cooling device

2

Cooling duct

3

Polymer film

4th

Inlet opening

5

Outlet opening

6th

Carrier textile

7th

imperforate section

8th

Humidifying membrane

9

Moisture storage

10

fan

11

Humidification channel structure

12th

Liquid inlet

13th

Cooling unit

14th

Inner textile layer

15th

Outer textile layer

16

Outlet opening

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102011016482 A1 [0002]

Claims (10)

Cooling device (1), comprising at least one circumferentially liquid-tight closed cooling channel (2) which has an inlet opening (4) at one end and an outlet opening (5) at the other end, with a length of the at least one cooling channel (2) by a Is several times greater than a width and a height of the at least one cooling channel (2), an outer shell of the at least one cooling channel (2) being formed from a liquid-tight polymer film (3), with a carrier textile (6) in the at least one cooling channel (2). is arranged to stabilize the cross-section of the cooling channel (2), and wherein on at least one circumferential side, in particular the broad side, of the at least one cooling channel (2) on the inside of the polymer film (3) is a partially perforated and unperforated sections (7) with the polymer film (3 ) connected, in particular welded, humidifying membrane (8) and a humidifier on the inside of the humidifying membrane (8) gkeitsspeicher (9) is arranged, wherein the carrier textile (6) is arranged adjacent to the inside of the moisture reservoir (9), and an electrically driven fan (10) to the inlet opening (4) and / or to the outlet opening (5) Passing ambient air through the at least one cooling channel (2) is arranged. Cooling device (1) after Claim 1 , whereby on opposite circumferential sides, in particular broad sides, of the at least one cooling channel (2) on the inside of the polymer film (3) there is in each case a partially perforated and with imperforate sections (7) connected, in particular welded, humidifying membrane (8) to the polymer film (3) and a moisture storage (9) is arranged on the inside of the respective humidification membrane (8), the carrier textile (6) being arranged between the two moisture storage (9), adjacent to the respective inner side. Cooling device (1) according to one of the preceding claims, wherein the at least one or the respective moisture storage (9) is designed as a fleece, in particular as a superabsorbent fleece. Cooling device (1) according to one of the preceding claims, wherein the at least one or the respective humidifying membrane (8) is perforated and connected with the imperforate sections (7) to the polymer film (3), in particular welded, in such a way that between the humidifying membrane ( 8) and the polymer film (3) a humidification channel structure (11) is formed along the at least one cooling channel (2) from its inlet opening (4) in the direction of its outlet opening (5), a liquid inlet (12) adjoining the humidification channel structure (11) the inlet opening (4) is arranged and wherein the humidification channel structure (11) is closed at the outlet opening (5). Cooling device (1) after Claim 4 , comprising a liquid metering unit with a moisture sensor system, comprising a plurality of moisture sensors arranged along the at least one cooling channel (2) distributed in this, and with a liquid supply unit fluidly coupled to the liquid inlet (12) of the at least one or the respective humidification channel structure (11) for the metered supply of Liquid via the at least one or respective humidification membrane (8) to the at least one or respective moisture reservoir (9) as a function of a moisture determination by means of the moisture sensor system. Cooling unit (13) with at least one cooling device (1) according to one of the preceding claims. Cooling unit (13) Claim 6 , designed as a cooling textile, in particular as a cooling vest, or as a room cooling unit for cooling a room in a building, or as a vehicle cooling unit for cooling a passenger compartment of a vehicle, or as a seat, in particular a child seat, in particular as a seat back, in particular a child seat back. Cooling unit (13) Claim 7 wherein the at least one cooling channel (2) in the cooling unit (13) designed as a cooling textile or seat is oriented vertically or at least substantially vertically. Cooling unit (13) Claim 7 or 8th , wherein the at least one cooling channel (2) in the cooling unit (13) designed as a cooling textile, in particular a cooling vest, is arranged on an inside of the cooling textile or between an inner textile layer (14) and an outer textile layer (15) of the two-layer cooling textile. Cooling unit (13) Claim 7 , wherein the cooling unit (13) designed as a room cooling unit is designed as a room ceiling cooling unit for arrangement on a ceiling of the room, the at least one cooling channel (2) being oriented horizontally when the cooling unit (13) is arranged on the ceiling of the room.

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