DE102020200799A1 - Distance heating device - Google Patents

Abstract

The invention is based on a distance heating device (10a; 10b), in particular a hot air gun device, with a heat output unit (12a; 12b) for heating a surface (14a; 14b), with a sensor unit (16a; 16b) for determining at least one piece of information (18a; 18b) in relation to the surface (14a; 14b) and with a control unit (20a; 20b) at least for controlling the heat emission unit (12a; 12b). It is proposed that the information (18a; 18b) at least one of a surface temperature of the surface (14a; 14b) has different components and the control unit (20a; 20b) in at least one operating state based on the information (18a; 18b) triggers at least one function.

Description

A hot air gun device with a measuring unit has already been proposed, which is provided for measuring a surface temperature of a surface to be heated.

Disclosure of the invention

The invention is based on a distance heating device, in particular a hot air gun device, with a heat output unit for heating a surface, with a sensor unit for determining at least one piece of information in relation to the surface and with a control unit at least for controlling the heat output unit.

It is proposed that the information has at least one component different from a surface temperature of the surface and that the control unit triggers at least one function in at least one operating state based on the information.

A “distance heating device”, in particular a “hot air gun device”, is to be understood as meaning, in particular, an, in particular functional, component, in particular a construction and / or functional component, of a distance heating device, in particular a hot air gun. For example, the distance heating device could also include the entire distance heating.

In this context, a “distance heating” is to be understood as a heater which is provided to heat a surface which is arranged at a distance from the distance heating, in particular in order to produce a specific result. For example, a distance heater having the distance heating device could be a radiant heater, advantageously a convection heater. A distance heater having the distance heating device is advantageously a hot air gun. Alternatively, a distance heater having the distance heating device could be a heating plate, for example an infrared heating plate. As an alternative or in addition, the distance heating could be designed, for example, as a rod-shaped hot air blower.

The distance heating device has a heat dissipation unit which is provided to dissipate heat, specifically for heating at least the surface. For example, the heat emitting unit could emit heat in the form of hot air and / or thermal radiation. In particular, the heat output unit is intended to deliver hot air with a hot air quantity of, for example, at least 50 ° l / min, advantageously at least 100 ° l / min, particularly advantageously at least 150 ° l / min, preferably at least 250 ° l / min and particularly preferably at least 400 ° l / min. In particular, the heat output unit is intended to deliver hot air with a hot air quantity of, for example, a maximum of 1000 ° l / min, advantageously a maximum of 800 ° l / min, particularly advantageously a maximum of 600 ° l / min, preferably a maximum of 400 ° l / min and particularly preferably a maximum of 300 ° l / min. In particular, the hot air released by the heat release unit has a temperature of, for example, at least 30 ° C., advantageously at least 50 ° C., particularly advantageously at least 70 ° C., preferably at least 100 ° C. and particularly preferably at least 200 ° C. In particular, the hot air emitted by the heat release unit has a temperature of, for example, a maximum of 1200 ° C., advantageously a maximum of 1000 ° C., particularly advantageously a maximum of 900 ° C., preferably a maximum of 750 ° C. and particularly preferably a maximum of 600 ° C.

In this context, a “sensor unit” is to be understood in particular as a unit that is provided to determine at least one item of information and / or one physical property with respect to the surface. The determination can take place actively, such as in particular by generating and transmitting an electrical measurement signal, and / or passively, such as in particular by determining changes in properties of a sensor component. Various sensor units that appear useful to a person skilled in the art are conceivable. In particular, the sensor unit could be designed as a permanently integrated unit or, for example, as a detachably plug-in module. The information has at least one component different from a surface temperature of the surface, wherein advantageously all components of the information are different from a surface temperature of the surface.

An “operating state” is to be understood in particular as a state in which the distance heating device heats the surface by means of the heat output unit, in particular to a certain temperature. For example, there could be a large number of operating states which differ from one another with regard to the temperature to which the surface is to be heated. As an alternative or in addition, there could be a large number of operating states which differ from one another with regard to the information determined by the sensor unit with regard to the surface.

“Provided” is to be understood in particular as specifically programmed, designed and / or equipped. Including that an object is provided for a specific function, it should be understood in particular that the object fulfills and / or executes this specific function in at least one application and / or operating state.

The configuration according to the invention enables, in particular, improved properties with regard to effectiveness to be achieved. In particular, a task for which it is intended can be carried out with increased efficiency by means of the distance heating device. This means that by means of the configuration of the distance heating device according to the invention, in particular errors, for example in the form of damage due to working temperatures that are too high and / or too low, are avoided. In addition, a surface in particular can be quickly heated to a desired temperature by means of the distance heating device. In particular, with regard to surfaces to be heated, improved efficiency, i.e. in particular a desired temperature, in particular more precisely and / or more quickly, can be achieved.

It is also proposed that the information includes at least a distance between the heat emitting unit and the surface. In this way, in particular, improved properties with regard to the heating of the surface can be achieved. In particular, the at least one component of the information that is different from a surface temperature of the surface could include the distance. Alternatively or additionally, the information could include at least a distance between the sensor unit and the surface.

It is also proposed that the information include at least image information of the surface. In particular, this makes it possible to provide a distance heating device with particularly advantageous properties with regard to safety. In particular, user safety and / or process safety, in particular with regard to the surface to be heated, can be achieved. In particular, the at least one component of the information which is different from a surface temperature of the surface could in particular comprise the image information. In this context, “image information of the surface” is to be understood as meaning, in particular, digital image content and / or information relating to the surface derived from digital image content. In particular, the image information is not visible to a user. For example, the image information could be determined regularly and designed, for example, as an, in particular regularly, recorded image of the surface.

It is also proposed that the information includes at least one surface condition of the surface. In particular, this makes it possible to provide a distance heating device with particularly advantageous properties with regard to safety. In particular, this can prevent damage to the surface. In this way, in particular, an undesired change in surface properties can be avoided. In particular, the component of the information which is different from the surface temperature of the surface comprises the surface state of the surface. In particular, the surface condition of the surface can be derived from the image information. For example, the surface condition of the surface can be embodied as a surface color and / or, in particular, when the image information is regularly determined, as a surface color change.

It is further proposed that the function include at least an adaptation of at least one operating parameter of the heat dissipation unit. In particular, it can thereby be achieved that the heating by means of the distance heating device takes place with improved effectiveness, since in particular the operating parameters can be adapted to the given circumstances, such as material properties or target temperature of the surface. An “operating parameter” should be understood to mean, in particular, a parameter with regard to the function of the heat dissipation unit, which can be influenced in particular by means of the control unit. In particular, a plurality of operating parameters can exist. In particular, the operating state changes a way in which the distance heating device, in particular the heat output unit, carries out the heating. In particular, at least one of the operating parameters is a heating output, specifically in particular the heat output unit. For example, the heating output could be determined on the basis of a determined current consumption of the heat output unit. Alternatively or additionally, at least one of the operating parameters could be the distance between the heat dissipation unit and the surface, in particular if, for example, the heat dissipation unit and / or the entire distance heating device is movably installed and the distance can be actively changed, for example by means of actuators . For example, the heat dissipation unit and / or the entire distance heating device could be mounted on a movable, electric motor-driven slide. For example, the adaptation of the at least one operating parameter could take place based on a relationship between the heating power and the distance between the heat output unit and the surface, in particular because this relationship is based on a Surface temperature can be closed. For example, a user could set a surface temperature to be achieved, which can be achieved at a specific distance, in particular by means of a specific heating power that can be regulated by means of the control unit and / or by means of a specific temperature of the hot air. For example, if the distance between the heat emitting unit and the surface is increased, the control unit could correspondingly increase a heating power and / or a temperature of the hot air, in particular in order to reach the temperature set by the user. For example, this could be a self-regulating system. Alternatively or in addition, one of the operating parameters could be designed as the amount of hot air from the heat dissipation unit. Alternatively or additionally, one of the operating parameters could be designed as a heating period.

It is also proposed that the function include at least one control of an operator interface. In particular, a high level of security can be achieved in this way. An “operator interface” is to be understood in particular as a man-machine interface which provides an operator with information, in particular with regard to at least one of the operating parameters. For example, the information could be provided as an acoustic and / or haptic and / or visual signal. For example, the operator interface could also include an operator control unit. An “operating unit” is to be understood here in particular as a unit that has at least one component that can be directly operated by an operator and that is intended to influence and / or influence the heating by actuation and / or by entering operating parameters to change. In particular, the operating unit is designed as a touch display. Alternatively or additionally, the operating unit could be designed as a voice control unit. Alternatively or additionally, the control unit could be designed as a control panel.

It is also proposed that the control unit is provided to take into account at least one material parameter in order to trigger the function. In this way, a high level of effectiveness can be achieved in each case, especially with different materials. In particular, the triggering of the function can be adapted to different materials by means of the material parameter. Furthermore, increased safety can be achieved in this way, in particular in that overheating of the surface can be avoided by taking into account a material parameter. In this context, a “material parameter” is to be understood in particular as a measurable material property of the material which forms the surface to be heated, which is particularly relevant with regard to the heating of the surface. In particular, at least one of the material parameters could be an optimal distance between the heat dissipation unit and the surface, alternatively between the sensor unit and the surface, in order to achieve a certain surface temperature. For example, it would be conceivable that the optimal distance is a critical distance which should not be undershot, in particular in order to avoid damage to the surface. In particular, as an alternative or in addition to this, a specific heat capacity and / or a thermal conductivity of the material which forms the surface to be heated could be taken into account. As an alternative or in addition, at least one of the material parameters could be an optimal heating time to achieve the specific surface temperature. For example, it is conceivable that the optimal distance is dependent on the optimal heating duration, this dependence being the material parameters taken into account. In particular, the dependency could be implemented in the control unit, for example by means of a control characteristic, in particular taking into account values determined by means of the sensor unit. For example, it would be conceivable that the optimal heating period is a critical heating period which should not be exceeded, in particular in order to avoid damage to the surface. In particular, the specific heat capacity and / or the thermal conductivity of the material could be taken into account as an alternative or in addition to this. Alternatively or additionally, at least one of the material parameters could be a surface color and / or an opacity and / or a transparency.

It is also proposed that the control unit is provided to compare the material parameter with the information in order to trigger the function. In this way, in particular, a particularly high level of efficiency with regard to the heating of the surface can be achieved. In addition, damage to the surface in particular can be avoided, as a result of which, in particular, a high level of user friendliness can be achieved. For example, the distance between the heat release unit and the surface could be compared with the optimal distance between the heat release unit and the surface. The control unit is advantageously provided to trigger the function when the distance between the heat release unit and the surface falls below the optimal distance between the heat release unit and the surface. For example, a user could be informed, in particular by means of the operator interface, that the surface could be damaged at this distance can occur. Alternatively or additionally, the heating duration could be compared with the optimal heating duration, the control unit being provided to trigger the function when the optimal heating duration is exceeded. For example, the control unit could be provided to end the heating when the critical heating period is exceeded. Alternatively or additionally, the material parameter could be embodied as the surface color, the control unit being provided to trigger the function if the information ascertained, ie a measured surface color, deviates from the surface color. As an alternative or in addition, any other material parameter could be compared with the information, the control unit being provided to trigger the function when the value is exceeded and / or not reached. The material parameter is advantageously compared with the component of the information which is different from a surface temperature of the surface. In this context, “deviate” is to be understood as meaning, in particular, a deviation of a value of in particular less than 25%, preferably less than 10% and particularly preferably less than 5% of the value. In this context, “exceeding” and “falling below” are to be understood as meaning, in particular, exceeding or falling below a value of in particular less than 25%, preferably less than 10% and particularly preferably less than 5% of the value.

It is also proposed that the material parameter is part of a material parameter set which can be selected via the control unit. In this context, a “set of material parameters” is to be understood as meaning, in particular, a data record which in particular includes associated material parameters and is in particular in the form of a database. In this context, the fact that the set of material parameters is “in the form of a database” should be understood in particular to mean that the set of material parameters is stored in the control unit and / or can be called up by means of a communication unit of the distance heating device. In particular, the material parameter, in particular from the material parameter set, can be selected automatically and / or by a user. For example, the material parameter could be selectable by a user, for example by means of the operator interface. For example, the sensor unit could be provided to identify the material of the surface to be heated, for example by means of a measurement of a conductivity or an electrical capacitance or, alternatively, by means of determined image information. A set of material parameters corresponding to the material could in particular be selected automatically by the control unit.

It is also proposed that the distance heating device have at least one communication interface for providing the set of material parameters. In particular, it is possible here to ensure that the material parameters of the material parameters set are up to date. In particular, improved security and / or increased user-friendliness can thereby be achieved. In particular, it would be conceivable that the communication interface can call up the set of material parameters from the Internet or a public telecommunications network. For example, the set of material parameters could be subject to a constant updating process. As a result, the communication interface could advantageously be provided to provide a constantly updated set of material parameters. The set of material parameters could preferably be subject to a machine learning process. For example, the set of material parameters could, however, also be permanently stored in the control unit.

Furthermore, the invention is based on a method for controlling a distance heating device, in particular a hot air gun device, with a heat output unit for heating a surface with a sensor unit which determines at least one piece of information in relation to the surface in at least one operating state.

It is proposed that the information is different from a surface temperature of the surface and that at least one function is automatically triggered in at least one operating state based on the information. A particularly high level of effectiveness can in particular be achieved in this way. In particular, damage to the surface can be avoided and / or particularly rapid heating of the surface can be achieved.

The distance heating device according to the invention, the distance heating according to the invention and the method according to the invention are not intended to be restricted to the application and embodiment described above. In particular, the distance heating device according to the invention, the distance heating system according to the invention and the method according to the invention can have a number that differs from a number of individual elements, components and units as well as method steps mentioned herein for fulfilling a mode of operation described herein. In addition, in the case of the value ranges specified in this disclosure, values lying within the stated limits should also be deemed disclosed and can be used in any way.

drawing

Further advantages emerge from the following description of the drawings. Three exemplary embodiments of the invention are shown in the drawings. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

• 1 eine erfindungsgemäße Distanzheizungsvorrichtung mit einer Sensoreinheit in einer vereinfachten Darstellung,
• 2 eine schaubildliche Darstellung eines Betriebsparameters einer Wärmeabgabeeinheit der Distanzheizungsvorrichtung,
• 3 ein Flussdiagramm eines Verfahrens zur Steuerung der Distanzheizungsvorrichtung,
• 4 ein weiteres Ausführungsbeispiel einer Distanzheizungsvorrichtung mit einer Sensoreinheit in einer vereinfachten Darstellung,
• 5 ein Flussdiagramm eines Verfahrens zur Steuerung der Distanzheizungsvorrichtung aus 4,
• 6 eine nicht erfindungsgemäße Distanzheizungsvorrichtung in einer vereinfachten Darstellung und
• 7 ein Verfahren zur Steuerung der Distanzheizungsvorrichtung aus 6.

Show it:

• 1 a distance heating device according to the invention with a sensor unit in a simplified representation,
• 2 a diagrammatic representation of an operating parameter of a heat dissipation unit of the distance heating device,
• 3 a flowchart of a method for controlling the distance heating device,
• 4th a further embodiment of a distance heating device with a sensor unit in a simplified representation,
• 5 a flowchart of a method for controlling the distance heating device 4th ,
• 6th a distance heating device not according to the invention in a simplified representation and
• 7th a method for controlling the distance heating device 6th .

Description of the exemplary embodiments

1 shows a simplified representation of a distance heating 40a , which is designed as a hot air gun in the example shown and is in an exemplary operating state. The distance heating 40a has a distance heating device 10a on, which is designed as a hot air gun device.

The distance heating device 10a has a heat dissipation unit 12a on. The heat emitting unit 12a is used to heat a surface 14a intended. The distance heating device 10a also has a sensor unit 16a on. The sensor unit 16a is to identify information 18a in terms of the surface 14a intended. The information 18a has one of a surface temperature of the surface 14a different component on. The from the surface temperature of the surface 14a different component is in the example shown as a distance 24a between the heat emitting unit 12a and the surface 14a educated.

The distance heating device 10a has a control unit 20a on which in 1 is shown schematically and in a control unit of the distance heating device 10a is integrated. The control unit 20a is at least to control the heat dissipation unit 12a intended.

The control unit 20a triggers in the operating state based on the information 18a a function. In the example shown, the function includes a control of an operator interface 32a the distance heating device 10a . The user interface 32a is designed as a warning light. In this way, in particular, a visual signal is provided for an operator, which instructs the operator to adapt an operating parameter 30a the heat dissipation unit 12a prompts. The operating parameter 30a is in the embodiment shown as the distance 24a between the heat emitting unit 12a and the surface 14a educated.

The control unit 20a is provided to trigger the function at least one material parameter 34a to consider. The material parameter 34a is about the control unit 20a selectable by means of a control panel (not shown). The material parameter 34a corresponds to the material of the surface.

The material parameter 34a is part of a set of material parameters 36a . The set of material parameters 36a is available in the form of a database from a network. The distance heating device 10a has a communication interface 38a which is designed as a WLAN module (not shown) in the example shown. The communication interface 38a is to provide the set of material parameters 36a intended. Using the communication interface 38a can be a continuously updated set of material parameters 36a to be provided.

The material parameter 34a is in the example shown as an optimal distance 42a between the heat emitting unit 12a and the surface 14a trained, which in 2 is shown graphically as an exemplary characteristic.

On the abscissa of the graph 2 is that as a distance 24a between the heat emitting unit 12a and the surface 14a trained operating parameters 30a applied. On the ordinate of the graph 2 is a temperature to be reached 44a applied. The material parameter 34a is designed as an exemplary characteristic curve and describes the optimal distance 42a between the heat emitting unit 12a and the surface 14a , namely with regard to the temperature to be reached 44a .

The control unit 20a is provided to trigger the function the material parameter 34a with the information 18a to compare. In the example shown is the control unit 20a provided by the sensor unit 16a determined distance 24a between the heat emitting unit 12a and the surface 14a with the optimal distance 42a between the heat emitting unit 12a and the surface 14a to be compared, namely at a certain temperature to be achieved 44a .

3 shows a flow diagram of a method 100a to control the distance heating device 10a . The procedure 100a has a plurality of process steps 110a-210a on.

In the process step 110a an operator switches the distance heating device 10a and selects the material of the surface that corresponds to the material parameter 34a corresponds to which part of the set of material parameters 36a is, by means of a control panel (not shown). For this purpose, the operator can access the set of material parameters using the control panel 36a access. The material parameter 34a is as an optimal distance between the heat emitting unit for heating the surface 12a and the surface 14a formed, namely with regard to the temperature to be reached 44a .

In the process step 120a the control unit automatically selects an optimal heating output for heating the surface. In the process step 130a is heating the surface 14a started. In the process step 140a determines the sensor unit 16a the distance 24a between the heat emitting unit 12a and the surface 14a . In the process step 140a compares the control unit 20a the material parameter 34a , ie the optimal distance 42a between the heat emitting unit 12a and the surface 14a with that of the sensor unit 16a determined distance 24a between the heat emitting unit 12a and the surface 14a .

In the process step 150a the result of this comparison is that the determined distance is less than the optimal distance 42a is. In the process step 160a the heating power is consequently reduced.

In the process step 170a is the result of this comparison that the determined distance 24a the optimal distance 42a is equivalent to. In the process step 180a consequently the heating power is maintained.

In the process step 190a is the result of this comparison that the determined distance 24a greater than the optimal distance 42a is. In the process step 160a the heating output is increased accordingly.

The procedural steps 140a until 200a are run through continuously for as long as the distance heating device is 10a is in an operating state.

In the process step 210a the operator switches the distance heating device 10a the end.

In the 4th and 5 a further embodiment of the invention is shown. The following descriptions are essentially limited to the differences between the exemplary embodiments, with the same components, features and functions being restricted to the description of the other exemplary embodiments, in particular the 1 until 3 , can be referenced. To distinguish the exemplary embodiments, the letter a in the reference numerals of the exemplary embodiment is 1 until 3 by the letter b in the reference numerals of the embodiment of 4th and 5 replaced. With regard to components with the same designation, in particular with regard to components with the same reference symbols, the drawings and / or the description of the other exemplary embodiments, in particular the 1 until 3 , to get expelled.

4th shows a further embodiment of a distance heater 40b , which is designed as a hot air gun in the example shown and is in an exemplary operating state. The distance heating 40b has a distance heating device 10b on, which is designed as a hot air gun device. The distance heating device 10b also has a sensor unit 16b on. The sensor unit 16b is designed as a camera in the embodiment shown.

The sensor unit designed as a camera 16b is to identify information 18b in terms of the surface 14b intended. The information 18b includes image information 26b the surface 14b . The sensor unit designed as a camera 16b is intended to take a picture of the surface, from which the information 18b can be derived. The information 18b includes a surface condition in the example shown 28b the surface 14b .

The control unit 20b is intended to be in the operating condition based on the surface condition 28b trigger a function. The function includes an adjustment of an operating parameter 30b the heat dissipation unit 12b . With the operating parameter 30b In the example shown, it is a heating output of the heat dissipation unit 12b . If there is a change in the surface condition 28b , for example a change in the surface color due to excessive heating power, triggers the control unit 20b the function off.

5 shows a flow diagram of a method 100b to control the distance heating device 10b the 4th . The procedure 100b has a plurality of process steps 300b-350ba on.

In the process step 300b an operator selects a temperature, for example by means of a control panel (not shown), to which the surface is to be heated. In the process step 310b becomes the distance heating device 10b brought into an operating state in which the user the distance heating device 10b turns on.

In the procedural steps 320b and 330b determines the sensor unit designed as a camera 16b continuously the image information 26b which as surface condition 28b is trained.

Detects the sensor unit 16b a change in the surface condition 28b , in particular damage to the surface, is in process step 340b the heating power of the heat dissipation unit 12b accordingly automatically reduced and / or the heat dissipation unit 12b is switched off.

Detects the sensor unit 16b no change in surface condition 28b , becomes the surface 14b heated to the temperature selected by the user and, for example, kept at this temperature until the distance heating device 10b switched off automatically or by the user.

In the 6th and 7th an embodiment not according to the invention is shown. The following descriptions are essentially limited to the differences between the exemplary embodiments, with the same components, features and functions being restricted to the description of the other exemplary embodiments, in particular the 1 until 3 , can be referenced. To distinguish the exemplary embodiments, the letter a in the reference numerals of the exemplary embodiment is 1 until 3 by the letter c in the reference numerals of the embodiment of 6th and 7th replaced. With regard to components with the same designation, in particular with regard to components with the same reference symbols, the drawings and / or the description of the other exemplary embodiments, in particular the 1 until 3 , to get expelled.

6th shows a distance heater not according to the invention 40c with a distance heating device 10c . The distance heating device 10c has a sensor unit 16c which is designed as a temperature sensor unit, in particular as an infrared temperature sensor. The temperature sensor unit is provided to measure the surface temperature of a surface to be heated 14c to eat.

The distance heating device 10c has a control unit 20c on, which is provided, a heating power of a heat output unit 12c the distance heating device 10c to be controlled as a function of the measured temperature, in particular to achieve an optimal temperature. The optimal temperature is part of a set of material parameters 36c which is on the control unit 20c is stored.

7th shows a procedure 100c for controlling the exemplary embodiment not according to the invention of the distance heating 40c .

In one process step 140c determines the sensor unit 16c the temperature of the surface 14c . In the process step 140c compares the control unit 20c the material parameter 34c , ie the optimal temperature with the measured temperature.

In one process step 150c the result of this comparison is that the measured temperature is lower than the optimal temperature. In one process step 160c the heating output is increased accordingly.

In one process step 170c the result of this comparison is that the measured temperature corresponds to the optimal temperature. In one process step 180c consequently the heating power is maintained.

In one process step 190c the result of this comparison is that the measured temperature is higher than the optimal temperature. In the process step 160c the heating power is consequently reduced.

Claims (12)

Distance heating device (10a; 10b), in particular hot air gun device, with a heat output unit (12a; 12b) for heating a surface (14a; 14b), with a sensor unit (16a; 16b) for determining at least one item of information (18a; 18b) in relation on the surface (14a; 14b) and with a control unit (20a; 20b) at least for controlling the heat output unit (12a; 12b), characterized in that the Information (18a; 18b) has at least one component different from a surface temperature of the surface (14a; 14b) and the control unit (20a; 20b) triggers at least one function in at least one operating state based on the information (18a; 18b). Distance heating device (10a) according to Claim 1 , characterized in that the information (18a) comprises at least one distance (24a) between the heat emission unit (12a) and the surface (14a). Distance heating device (10b) according to Claim 1 or 2 , characterized in that the information (18b) comprises at least one piece of image information (26b) of the surface (14b). Distance heating device (10b) according to one of the preceding claims, characterized in that the information (18b) comprises at least one surface condition (28b) of the surface (14b). Distance heating device (10a; 10b) at least according to one of the preceding claims, characterized in that the function comprises at least one adaptation of at least one operating parameter (30a; 30b) of the heat output unit (12a; 12b). Distance heating device (10a; 10b) at least according to one of the preceding claims, characterized in that the function comprises at least one control of an operator interface (32a; 32b). Distance heating device (10a; 10b) according to one of the preceding claims, characterized in that the control unit (20a; 20b) is provided to take into account at least one material parameter (34a; 34b) for triggering the function. Distance heating device (10a; 10b) according to Claim 7 , characterized in that the control unit (20a; 20b) is provided to compare the material parameter (34a; 34b) with the information (18a; 18b) in order to trigger the function. Distance heating device (10a; 10b) according to Claim 7 or 8th , characterized in that the material parameter (34a; 34b) is part of a material parameter set (36a; 36b) which can be selected via the control unit (20a; 20b). Distance heating device (10a; 10b) according to Claim 9 , characterized by at least one communication interface (38a; 38b) for providing the set of material parameters (36a; 36b). Distance heating (40a; 40b), in particular hot air gun, with at least one distance heating device (10a; 10b) according to one of the preceding claims. Method (100a; 100b) for controlling a distance heating device (10a; 10b), in particular a hot air gun device, with a heat output unit (12a; 12b) for heating a surface (14a; 14b), with a sensor unit (16a; 16b), which in at least one operating state at least one piece of information (18a; 18b) in relation to the surface (14a; 14b) is determined, characterized in that the information (18a; 18b) is different from a surface temperature of the surface (14a; 14b) and in at least one Operating state based on the information (18a; 18b) is automatically triggered at least one function.

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