奥地利专利AT514454A1 heater

专利PDF首页>>奥地利专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
Heating device with at least one radiant heater (2), at least one receiving area (3), in which at least one semi-finished product (4) in the heating region (5) of the at least one radiant heater (2) can be arranged and at least one temperature sensor (6) which is arranged in that a temperature of at least one semifinished product (4) arranged in the at least one receiving region (3) can be measured, wherein a control device (7) is provided, to which the measuring signals of the at least one temperature sensor (6) can be supplied, wherein the blasting power of the at least one radiant heater (2) in dependence of the measuring signals of the at least one temperature sensor (6) is controllable.
公开号:AT514454A1
申请号:T572/2013
申请日:2013-07-11
公开日:2015-01-15
发明作者:Alexander Dipl Ing Stock；Gregor Hartung；Michael Dipl Ing Dr Fischlschweiger；Peter Dipl Ing Egger；Georg Dipl Ing Dr Steinbichler
申请人:Engel Austria Gmbh；
IPC主号:

专利说明:

The present invention relates to a heating device having the features of the preamble of claim 1, a shaping machine with such a heating device and a method for heating at least one semifinished product having the features of the preamble of claim 25.
Under a molding machine is an injection molding machine, a press, an extrusion press or the like to understand.
The use of electromagnetic radiation, in particular infrared radiation for heating thermoplastic semi-finished products and films to enable the thermoforming process for the molding of complex geometries is state of the art. For radiation emission a wide variety of systems are used. Examples are metal strip emitters, carbon emitters, ceramic emitters and quartz emitters. The differences of the radiation sources are, as the examples mentioned, in the use of different materials as emitters. By emitting different materials, a range of radiation wavelength and temperature-dependent emission spectra can be generated. Depending on the absorption and transmission spectrum of the semifinished product to be heated, this leads to different heat input response times, radiation penetration depths and finally to necessary residence times of the semifinished product in the radiator field.
In the standard film processing heaters are used to ensure the heat input and allow subsequent forming, which built the radiant heater in one or in special cases, two-sided design wear. The film, fixed by a holder, which in turn is attached to an external manipulation unit (for example robot), is introduced into the radiator field. During operation, the radiant heaters are in continuous power and the control of the amount of heat to be introduced into the film is effected by the residence time of the manipulation unit in the heating area of the radiant heaters. For the mass production of fiber-reinforced plastic composites based on thermoplastic matrix systems, heat input into semi-finished products is a prerequisite for component production until the formability is reached. As a result, the heating station becomes an essential element of the system. The prior art is to use the method described above for films also in the production of fiber composite components.
The thicknesses of thermoplastic semi-finished products are between 0.1 and 10 mm and cover different color spectra with any fillers. Accordingly, the heating of semi-finished products results in much higher heating times than in conventional film processing. Due to the low thermal conductivity of the polymers and by the filler content, color, fiber content and matrix dependent penetration depth of the radiation, the dominant heat transport effect in the semi-finished product is the heat conduction. As a result, it comes with heating methods that correspond to the prior art, to overheat and damage the surface and edge zone of the matrix material of the semifinished product.
In other words, the continuous operation of the radiant heaters and the control of the residence time in the heating station must be compromised: If the residence time is too short, the surface temperature of the semi-finished product may be in order, but the semi-finished product is not homogeneously heated. If the residence time is too long, the semi-finished product is indeed warmed, but the surface of the semifinished product is damaged by overheating.
In order to ensure the homogeneity of the temperature across the area, the radiant heaters are divided into zones in the area of film production and controlled individually. This method of temperature control means that time-consuming and costly calibration work has to be carried out with each change of the process in order to adapt the temperature distribution in the semifinished product.
The holding of the semifinished products is carried out by external manipulation units which move them either crosswise using the force acting on the semi-finished gravity or by fixing the semifinished product to the semi-finished products (for example, by needles) in the heating of the radiant heater. However, when one-sided holding of the semifinished product, the force of gravity is insufficient to compensate for temperature-induced residual stresses (single-roll effect of the semifinished product), which leads to changes in shape, fiber distortion and delaminations of the semifinished product.
If the semifinished product is fixed at the corners by needling and tensioned, the resulting uneven clamping force distribution results in a further increased tendency to delaminate.
Furthermore, the external manipulation unit must remain in this position during the entire warm-up cycle, whereby an additional manipulation unit must be used to prepare the semi-finished products for the warm-up and to remove the end components from the forming machine.
The object of the invention is to provide a heating device, a shaping machine with such a heating device and a method for heating semi-finished products, wherein a gentle soaking of the surface of the semi-finished product is made possible.
This object is achieved by a heating device having the features of claim 1, a shaping machine having the features of claim 24 and a method having the features of claim 25.
This is done by measuring a temperature of the at least one semi-finished product and controlling a heating power of the at least one radiant heater as a function of the measured temperature. The heating device has at least one radiant heater, at least one receiving area, in which at least one semifinished product can be arranged in the heating area of the at least one radiant heater, and at least one temperature sensor, which is arranged such that a temperature of at least one semi-finished product arranged in the at least one receiving area can be measured. , wherein a control device is provided, to which the measuring signals of the at least one temperature sensor can be supplied and which regulates the beam power of the at least one radiant heater as a function of the measuring signals of the at least one temperature sensor.
The regulation thus keeps the surface temperature at an acceptable level. The heating time can then be selected so that there is a desired temperature in the center of the semifinished product.
Further advantageous embodiments of the invention are defined in the dependent claims.
Preferably, at least one tube is provided, wherein a first opening of the at least one tube points in the direction of the receiving region and at a second opening of the at least one tube, the at least one temperature sensor is arranged. In contactless measurement of the temperature of the at least one semifinished product can be prevented that the measurement result is distorted by scattered radiation, in particular from the radiant heaters. It is particularly preferably provided that the at least one tube is arranged in at least one recess in at least one radiant heater. This makes it possible to measure the temperature at a generic point, in particular not at the edge of the semifinished product.
A further problem may arise in that air in the heating device in the vicinity of the semifinished product to be heated absorbs heat from the semifinished product and reaches the surroundings of the temperature sensor. This can also lead to a falsification of the measurement results. This can be counteracted with a blowing device through which the at least one pipe can be supplied with purging air through an inlet opening. It can also be provided that in at least one tube outlet openings are provided for exiting the scavenging air, wherein the outlet openings preferably each have in a direction transverse to a longitudinal axis of the at least one tube.
It may be advantageous to provide a movement device, by means of which the at least one temperature sensor is movable in such a way that temperatures of different points of at least one semi-finished product arranged in the receiving region can be detected. Since high-quality temperature sensors can be expensive, this can contribute to the reduction of production costs of the heating device.
However, this effect can also be achieved by providing a mirror system by means of which thermal radiation, in particular infrared radiation, emitted from different points of at least one semi-finished product arranged in the receiving region can be reflected to the at least one temperature sensor.
It is also possible to provide a raster device by means of which raster cells on at least one semi-finished product arranged in the receiving region can be irradiated sequentially by the at least one radiant heater. A first embodiment of such a raster device comprises the possibility to move the at least one radiant heater itself and to focus its heating radiation on the raster cells on the semifinished product. However, it is also possible, in a second embodiment, not to move the at least one radiant heater, but to act with a variable optics, the raster cells sequentially with radiation. The grid cells will usually be of an imaginary nature. Their size depends on the radiant heater, in particular its performance.
Particularly preferably, for the heating on both sides of at least one semi-finished product arranged in the receiving region, at least two radiant heaters spaced apart from one another are provided, between which the receiving region is arranged.
Systematically occurring deviations from a desired temperature profile can be remedied by a filter and / or a shield and / or a radiation converter is arranged in the beam path between the at least one radiant heater and the receiving area.
Since semi-finished products, for the heating of which the present invention is to be used, are generally flat, this may also preferably be provided for the radiant heaters themselves. A homogeneous temperature distribution in the semifinished product can be achieved in this way most easily.
In a particularly preferred embodiment, the at least one radiant heater radiates electromagnetic radiation essentially from the infrared spectrum. Infrared radiation is particularly well-suited for non-contact heating of objects, since it is comparatively well converted into heat.
It can preferably be provided that the at least one radiant heater is divided into zones, wherein the radiant power of each zone can be regulated separately.
It is particularly preferred to divide the zones according to their location with respect to adjacent zones in categories and to provide for each category of zones exactly one temperature sensor. For example, for square zones, categories may be created by the number of adjacent zones (eg, a category with zones having two closest neighbors, one with three nearest neighbors and one with four nearest neighbors). Since temperature evolution in zones of similar categories can be expected to be similar, the use of only one temperature sensor per zone category can provide a good compromise between striving for as many temperature measurement points as possible and cost-effectiveness.
In a preferred embodiment, a wire support can be provided for the arrangement of the at least one semifinished product in the receiving area. It is particularly preferably provided that wires of the wire support to compensate for thermal deformations are spring-loaded.
The wires of the wire support may have an elliptical - in particular circular - or a polygonal cross-section, wherein a cross-sectional main dimension is preferably between 0.05 mm and 5 mm, particularly preferably between 0.5 mm and 1 mm.
In addition, for the arrangement of a semifinished product in the receiving area a clamping frame may be provided which has at least one - preferably spring-loaded - holding device for the positive or non-positive holding of the semi-finished products. Again, the spring loading of the holding device can be used to compensate for thermal deformation.
The wire support and / or the clamping frame can be mounted linearly movable. This makes it possible to fasten the semi-finished products outside of the at least one receiving area and then - fixed on the clamping frame and / or placed on the wire support - to bring in the at least one receiving area. This may, inter alia, offer the advantage that, for example, a handling device is not hampered by the tight space conditions in the heating station itself or that it must be constructed less expensive, as more space is available.
Furthermore, a preheating station may preferably be provided for preheating the at least one semifinished product, wherein a temperature-controlled magazine for semifinished products is preferably provided. The preheating station may include an infrared heater and / or a circulating air heater and / or a contact heater. For example, in injection molding processes, the production of fiber composite part usually runs in timed cycles, for productivity reasons, the cycle time is to be minimized, which is why the heating time of the semi-finished products should be short. Particularly in this case, the embodiment with a preheating station is particularly advantageous because preheated semifinished products are available in a temperature range between room temperature and melting temperature and the heating time of the semifinished product in the heating station is thereby shortened.
It can be provided that the at least one semi-finished product in the preheating station with exclusion of atmosphere - preferably by means of a contact heater - is heatable. As a result, oxidation of the semifinished product to the ambient air can be prevented. This oxidation is disadvantageous because it makes the surface of the semifinished product "aged" or degraded.
Furthermore, a ventilation device for cooling a surface of the at least one semifinished product may be provided, wherein the ventilation device is preferably designed as convection cooling. Initially, the problem of too high a surface temperature paired with a too low temperature in the center of the semifinished product has already been described. Especially with thick semi-finished products, such a ventilation device can be used for the gentle introduction of heat.
For transporting the at least one semifinished product from and to the receiving region, a handling device can be provided. In a particularly preferred
Embodiment, the handling device on a gripping mechanism-preferably a suction cup-for the at least one semi-finished product and a support device for generating a counter-pressure in contacting the gripping mechanism with the at least one semi-finished product. This can improve the effectiveness of gripping mechanisms. Since the semi-finished products are easily deformable in the heated state, a retraction of the heated semifinished product from the gripping mechanism can be avoided by the described support device. In particular, in the case of spring-loaded wire supports or spring-loaded holding devices, this may be necessary.
Particularly preferably, the heating power of the at least one radiant heater is controlled by at least temporarily shutting off the at least one radiant heater during the heating of the at least one semi-finished product. In other words, an average heating power is regulated by temporarily completely switching off the power of the radiant heater. But also a continuous control of the heating power of the radiant heater can be provided.
Since in the production of fiber composite components in production cycles thermal changes may occur that extend over several cycles, it can be preferably provided that a start time of the temperature control is selected depending on a heating period in a previous heating of a semifinished product. This may not only be necessary at the start of production. Even smaller - for example, daytime - temperature changes, can decisively influence certain precision processes.
In a particularly preferred embodiment, the control device is integrated in a central machine control of the shaping machine. This can also be the case for a further control or regulating device for a handling device. This may result in the possibility of optimizing the overall process.
For example, due to a change in the ambient temperature to be heated semi-finished with different initial temperatures in the
Arrive heater, which changes the heating time. The time of insertion of the preheated semi-finished product, for example in a mold half is usually predetermined within a production cycle. This can therefore lead to an excessively long residence time of the semifinished product in the heating device. This can be remedied by starting the heating of the semifinished product by a time interval before inserting the semi-finished product into the mold half, which results from the heating-up time of the semifinished product from a previous cycle.
In other words, a start time of the temperature control can be selected as a function of a heating time in a previous heating of a semifinished product.
It can also be provided that a desired value for the regulation of the heating power of the at least one radiant heater is predetermined by a central machine control of a shaping machine.
In a further preferred embodiment, components which can be arranged or arranged in the heating region of the at least one radiant heater, in particular a shield and / or a handling device and / or a filter and / or a radiation converter are made of materials having a temperature resistance of at least 80 ° C. , preferably at least 100 ° C.
The handling device can consist of several elements. For example, an element may be provided which transports preheated semi-finished products into the heating device. It can also be provided an element that transport the semi-finished products from the heater into a mold. But it is also possible to have these different tasks done by a single integrated handling device.
Further advantages and details of the invention are apparent from the figures and the associated description of the figures. Showing:
Fig. 1 shows a heating device according to the invention in a perspective
View,
2 shows a heating device according to the invention in a side view,
Fig. 3 shows schematically the arrangement of different zones and
Temperature sensors in a heating device according to the invention,
4 a tenter frame,
5 shows a wire support,
6 shows a support device,
7 shows the arrangement of a temperature sensor at a recess of a radiant heater,
8 and 9 show two views of a mirror system,
10 shows schematically a raster device,
Fig. 11 is a ventilation device as well
12 shows a shaping machine with a heating device according to the invention.
The heating device 1 shown in Figure 1 has two radiant heaters 2, which are arranged spaced from each other. A wire support 18 is arranged linearly movable, so that stored semi-finished products in the receiving area 3, which is arranged in the heating area 5 between the radiant heaters 2, can be introduced. The radiant heaters 2 are connected to the control device 7, which is indicated only schematically in the figure. The arrangement and connection of the temperature sensors 6 are not yet visible in this illustration. Reference should be made in this regard to FIGS. 3 and 7.
Furthermore, a handling device 24 is shown. This semifinished products can be stored for example from a tempered magazine on the wire support 18. For this purpose, the handling device 24 has four gripping mechanisms 25, which are formed in this case as suction cups.
After heating of the semifinished product 4 in the heating device 1, the wire support 18 is removed again from the receiving region 3. This is again done by the linear movability of the wire support 18. The semifinished product is then located on the right side of the heater 1 in the figure above the four support means 26. These are shown in more detail in Figure 6. From this position, the heated semi-finished product 4 can be transported by another, not shown, handling device 24, for example, to a mold.
FIG. 2 shows a heating device 1 according to the invention together with a semi-finished product 4 located in the receiving region 3 in a side view. The radiant heaters 2 are divided into different zones 17, which are shown in more detail in FIG. By way of example, a shield 16 between the upper radiant heater 2 and the semifinished product 4 is shown. Infrared radiation from the upper radiant heater 2 can not penetrate these and thus produces a lower heating effect in the shade of the shield 16. By means of these and similar measures, temperature profiles of the semifinished product 4 can be produced in a targeted manner.
Some exemplary beam paths are indicated by an arrow.
The distance D of the radiant heaters is preferably between 10 mm and 600 mm. In this embodiment, it is about 200 mm.
A center distance d - defined as the distance of a semi-finished product 4 located in the receiving area to a center between the radiant heaters 2 - is preferably at most a quarter of the distance D. It is of course immaterial in which direction the deviation (ie up or down in the FIG. 2) from the middle between the radiant heaters 2.
Figure 3 shows schematically a view of a radiant heater 2 in a view of the receiving area 3. The radiant heater 2 is divided into different zones 17 (not all zones 17 were provided with reference numerals). In this case, the rectangular zones 17 are divided into three categories: a category of zones each having two closest neighbors, one having three nearest neighbors, and one having four nearest neighbors. For each category of zones 17, a temperature sensor 6 is provided, which is arranged in recesses 12 in the radiant heater 2.
It is schematically indicated how the temperature sensors 6 are connected to the control device 7. The arrangement of the temperature sensors 6 takes place in this embodiment according to FIG 7. It is at a
Temperature sensor, the circular catchment area, from which radiation can reach the temperature sensor, indicated.
FIG. 4 shows a clamping frame 20 with a plurality of holding devices 21. These are spring loaded to compensate for thermal deformation of the semifinished product 4. In this case, the holding devices 21 are designed as terminals. The clamping frame 20 can be used as an alternative to the wire support 18 of Figure 1.
FIG. 5 shows the wire support 18 from FIG. 1 in greater detail. It can be seen that the wires 19 of the wire support 18 are spring-loaded. A resting on the wire support 18 semi-finished product 4 is indicated.
A wire spacing s between the wires is preferably between 1 mm and 300 mm. In this embodiment, the wire spacing s is about 150 mm.
Figure 6 serves to illustrate the operation of the support means 26. Since both the heated semifinished product 4 and the wire support 18, in particular when it has spring-loaded wires 19 and holding devices 21, are relatively elastic, the semi-finished product 4 would be when placing a gripping mechanism 25 (suction cup) move away. The suction cup could therefore produce no negative pressure, since he sits with too little relative force on the semifinished product 4.
Therefore, the support means 26 is provided, which provides a support directly under the suction cup 25 by a movable mechanism. The back pressure thus generated allows the suction cup 25 to generate the required negative pressure and thus to receive the heated semifinished product 4.
In Figure 7, the arrangement of the temperature sensor 6 is shown in more detail. In a recess 12 in the radiant heater 2 sits a tube 9. Its first opening 10 faces in the direction of the semifinished product 4, at the second opening 11 of the temperature sensor 6 is arranged. The beam path to the temperature sensor 6 is indicated by dashed lines.
WWW
The temperature sensor 6 is also connected to the control device 7.
In order to prevent heated air from the semifinished product 4 rising through the tube 9 to the detection area, 13 purge air is supplied through an inlet opening 13 by means of a blowing device, not shown. Through outlet openings 14 in the pipe 9, this purge air can escape from the pipe 9 again. These are preferably designed so that the scavenging air does not pass through the first opening 10 in the vicinity of the semifinished product 4. Because this would lead to an inhomogenization of the heating process of the semifinished product 4 and falsify the measurement results of the temperature sensor 6.
FIGS. 8 and 9 schematically show a mirror system 8, as used in a further embodiment of the invention. It includes a mirror that is freely rotatable about two axes. This makes it possible to reflect heat radiation from different points of the semifinished product 4 to the temperature sensor 6. As a result, only one temperature sensor 6 is necessary, which can save costs.
In such an embodiment, it is also not necessary to guide thermal radiation from the semifinished product 4 through a recess 12 in the radiant heater 2 to the temperature sensor 6, that is, the temperature sensor 6 can be arranged in a simpler manner.
In the measurement result of the temperature sensor, the inherent temperature of the mirror system 8 must be computationally compensated in this way. This method is state of the art.
Figure 10 shows schematically a raster device 15, as it finds use in a further embodiment of the invention. By a movement of the radiant heater 2 in two axes, which lie in a plane parallel to the semifinished product 4, the grid cells 29 of the semifinished product 4 can be irradiated sequentially (not all raster cells 29 are provided with reference numerals). The trajectory of the radiant heater 2 to shut down all grid cells 29 was indicated by dashed lines.
It is not necessary that the radiant heater 2 dwells on the grid cells 29.
Figure 11 is a side view of a heating device according to the invention 1. It additionally has a ventilation device 23, which operates on the recirculation principle. An air flow that runs around the semifinished product 4 serves to cool the surface of the semifinished product 4. It should be noted how the planar design of the radiant heaters 2 automatically form boundaries for the air flow indicated by arrows.
FIG. 12 shows a shaping machine 26 (in this case an injection molding machine) together with a heating device 1 according to the invention. The control device 7 is integrated into a central machine control of the shaping machine 26. Set values for temperatures of the semifinished products 4 can thus be entered by the operator on the shaping machine 26.
The following reference numerals have been used in the figures, wherein like reference numerals have been used for analogous objects in the figures. 1 heating device 2 radiant heater 3 receiving area 4 semifinished product 5 heating area 6 temperature sensor 7 regulating device 8 mirror system 9 tube 10 first opening (of the tube) 11 second opening (of the tube) 12 recess 13 inlet opening 14 outlet opening 15 grid device 16 shielding 17 zones 18 wire support 19 wires 20 clamping frame 21 holding device 22 preheating station 23 ventilation device 24 handling device 25 gripping mechanism 26 supporting device 27 machine control 28 shaping machine 29 grid cells D distance of the radiant heaters d center distance (of the semifinished product) s wire spacing
Innsbruck, July 9, 2013

权利要求:
Claims (29)
[1]
1. Heater with at least one radiant heater (2), at least one receiving area (3), in which at least one semi-finished product (4) in the heating area (5) of the at least one radiant heater (2) can be arranged and at least one temperature sensor (6), which is arranged such that a temperature of at least one semifinished product (4) arranged in the at least one receiving region (3) can be measured, characterized in that a regulating device (7) is provided, to which the measuring signals of the at least one temperature sensor (6) can be fed, wherein the beam power of the at least one radiant heater (2) in dependence of the measuring signals of the at least one temperature sensor (6) is controllable.
[2]
2. Heating device according to claim 1, characterized in that the temperature sensor (6) comprises at least one pyrometer and / or at least one thermal imaging camera and / or at least one thermocouple.
[3]
3. A heating device according to claim 1 or 2, characterized in that at least one tube (9) is provided, wherein a first opening (10) of the at least one tube (9) points in the direction of the receiving area and at a second opening (11) of the at least one tube (9), the at least one temperature sensor (6) is arranged.
[4]
4. Heating device according to claim 3, characterized in that the at least one tube (9) is arranged in at least one recess in at least one radiant heater (2).
[5]
5. Heating device according to claim 3 or 4, characterized in that a blowing device is provided, through which the at least one tube (9) through an inlet opening (13) scavenging air can be fed, and that in at least one tube (9) outlet openings (14). are provided for the outlet of the scavenging air, wherein the outlet openings (14) preferably each have in a direction transverse to a longitudinal axis of the at least one tube (9).
[6]
6. Heating device according to one of claims 1 to 5, characterized in that a movement device is provided, by which the at least one temperature sensor (6) is movable such that temperatures of different points of at least one in the receiving area (3) arranged semifinished product (4 ) are detectable.
[7]
7. Heating device according to one of claims 1 to 6, characterized in that a mirror system (8) is provided, by which from different points of at least one arranged in the receiving area semi-finished product (4) emitted thermal radiation, in particular infrared radiation to at least one temperature sensor (6 ) is reflectable.
[8]
8. Heating device according to one of claims 1 to 7, characterized in that the at least one radiant heater (2) comprises a metal strip radiator and / or a carbon radiator and / or a ceramic radiator and / or a quartz radiator and / or a laser and / or an LED ,
[9]
9. Heating device according to one of claims 1 to 8, characterized in that a raster device (15) is provided, through which grid cells (29) on at least one in the receiving area (3) arranged semifinished product (4) sequentially from at least one radiant heater (2) are irradiated.
[10]
10. A heating device according to at least one of claims 1 to 9, characterized in that for the two-sided heating of at least one in the receiving area (3) arranged semifinished product (4) at least two, spaced-apart radiant heater (2) are provided, between which the receiving area (3) is arranged.
[11]
11. Heating device according to one of claims 1 to 10, characterized in that in the beam path between the at least one radiant heater (2) and the receiving area (3) a filter and / or a shield (16) and / or a radiation converter is arranged.
[12]
12. Heating device according to one of claims 1 to 11, characterized in that the at least one radiant heater (2) is formed flat.
[13]
13. Heating device according to one of claims 1 to 12, characterized in that the at least one radiant heater (2) is divided into zones (17), wherein the beam power of each zone (17) is separately controllable.
[14]
14. A heating device according to claim 13, characterized in that the zones (17) according to their position with respect to adjacent zones (17) are divided into categories and for each category of zones (17) exactly one temperature sensor (6) is provided.
[15]
15. Heating device according to one of claims 1 to 14, characterized in that for the arrangement of the at least one semifinished product (4) in the receiving area (3) a wire support (18) is provided.
[16]
16. Heating device according to claim 15, characterized in that wires (19) of the wire support (18) are spring-loaded to compensate for thermal deformations.
[17]
17. Heating device according to one of claims 1 to 16, characterized in that for arranging a semifinished product (4) in the receiving area (3) a clamping frame (20) is provided, which at least one - preferably spring-loaded - holding device (21) for form or having frictional holding the semi-finished products (4).
[18]
18. Heating device according to claim 17, characterized in that the at least one holding device (21) is designed as a clamp.
[19]
19. Heating device according to one of claims 1 to 18, characterized in that a preheating station (22) for preheating the at least one semifinished product (4) is provided, wherein preferably a tempered magazine for semi-finished products (4) is provided.
[20]
20. Heating device according to claim 19, characterized in that the at least one semifinished product (4) in the preheating station (22) with exclusion of atmosphere - preferably by means of a contact heater -erwärmbar.
[21]
21. Heating device according to one of claims 1 to 20, characterized in that a ventilation device (23) for cooling a surface of the at least one semifinished product (4) is provided, wherein the ventilation device (23) is preferably designed as convection cooling.
[22]
22. Heating device according to one of claims 1 to 21, characterized in that a handling device (24) for transporting the at least one semifinished product (4) from and to the receiving area (3) is provided.
[23]
23. A heating device according to claim 22, characterized in that the handling device (24) has a gripping mechanism (25) - preferably a suction cup - for the at least one semi-finished product (4) and a support device (26) for generating a counter-pressure when contacting the gripping mechanism ( 25) with the at least one semi-finished product (4).
[24]
24. Forming machine with a heating device (1) according to one of claims 1 to 23.
[25]
25. A method for heating at least one semifinished product with at least one radiant heater (2), characterized in that a temperature of the at least one semifinished product (4) is measured and a heating power of the at least one radiant heater (2) is controlled in dependence on the measured temperature.
[26]
26. The method according to claim 25, characterized in that the heating power of the at least one radiant heater (2) is controlled by the fact that the at least one radiant heater (2) is switched off at least temporarily during the heating of the at least one semifinished product (4).
[27]
27. The method according to claim 25 or 26, characterized in that the at least one semifinished product (4) is preheated prior to heating in the heating device (1) in a preheating station (22).
[28]
28. The method according to any one of claims 25 to 27, characterized in that a starting time of the temperature control as a function of a heating period in a previous heating of a semifinished product (4) is selected.
[29]
29. The method according to any one of claims 25 to 28, characterized in that a desired value for the regulation of the heating power of the at least one radiant heater (2) from a central machine control (27) of a shaping machine (28) is predetermined. Innsbruck, July 9, 2013

类似技术:

公开号 | 公开日 | 专利标题

AT514454B1|2015-03-15|heater

EP2340925B1|2013-04-03|Process for generative production of a three-dimensional object with continuous heat supply

DE102006053121B3|2007-12-27|Coating device for applying powdered layers to a device for producing a three-dimensional object comprises longitudinal walls joined together, a unit for fluidizing powdered material and a controlling and/or regulating unit

DE102005022308B4|2007-03-22|Apparatus and method for manufacturing a three-dimensional object with a heated powder coating material build-up material

DE102009047541A1|2011-06-09|Furnace for conditioning preforms

DE102014017085A1|2016-05-25|Device for producing a reinforcing structure on a shaped body surface

EP2298536A2|2011-03-23|Packaging machine with multiple heating elements and the method

EP2200797A1|2010-06-30|Method for producing a fibre-composite component

DE102006045027B4|2008-09-11|Apparatus and method for heating a thermoplastic film sheet or plastic sheet

WO2013156015A1|2013-10-24|Device and method for induction heating

DE102015010000B4|2018-01-04|Tool device for manufacturing components and method for manufacturing the tool device

DE102011052899A1|2013-02-28|Heating device and heating method for blow molding machine and blow molding machine

EP3527040B1|2020-12-02|Method and device for manufacturing molded parts from semi-finished parts

DE102009026259A1|2011-02-03|Device for warming pre-mold in stretch blow-molding device, has radiator emitting rays in wave-length range, which possesses maximum emission, where wave-length range and maximum emission differ from those of another radiator

EP3221123A1|2017-09-27|Device and method for producing a reinforcing structure on the surface of a moulding

DE102013107213A1|2015-01-15|Method and system for controlling the temperature of an autoclave production process

EP3369554A1|2018-09-05|Method of forming blisters in a heated film web

AT520316B1|2019-03-15|Method and device for foaming an expandable particle foam material

DE202017101484U1|2018-06-15|Plant for consolidating fiber composite structures

DE102014017088A1|2016-05-25|Apparatus and method for producing a reinforcing structure on a shaped body surface

DE102011116849B4|2019-07-25|Method for calibrating a heater of thermoforming machines

DE102017009700A1|2019-04-18|Method and system for producing thermoformed components by means of active, local cooling of the semifinished product

DE102019111631A1|2020-06-18|Method for producing an inner container for a refrigerator and / or freezer

DE102019007982A1|2021-05-20|3D printing device with advantageous emitter unit and process

DE4223883B4|2008-07-03|Method and device for deep-drawing plastic parts

同族专利:

公开号 | 公开日

AT514454B1|2015-03-15|

DE102014010173C5|2022-03-03|

DE102014010173A1|2015-01-15|

CN104275782B|2017-05-31|

CN104275782A|2015-01-14|

DE102014010173B4|2017-11-23|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

JP2000015693A|1998-07-06|2000-01-18|Sumitomo Heavy Ind Ltd|Method and apparatus for molding plastic sheet|

WO2002045135A2|2000-12-01|2002-06-06|Steag Hamatech Ag|Method for thermally treating substrates|

US20020088137A1|2001-01-09|2002-07-11|Mark Savarese|Drying appartus and methods|

JP2009192141A|2008-02-14|2009-08-27|Hitachi Plant Technologies Ltd|Continuous heating device|

DE102011077005A1|2011-06-06|2012-12-06|Rehm Thermal Systems Gmbh|Plant for heat treatment of substrates and method for acquiring measurement data therein|DE102014016365A1|2013-12-27|2015-07-02|Engel Austria Gmbh|Apparatus and method for heating a semifinished product|DE2745422C3|1977-10-08|1982-08-26|Société d'Application Plastique, Mécanique et Electronique Plastimécanique S.A., 14700 Falaise|Method for operating a thermoforming machine and device for carrying out the method|

DE3620954C2|1986-06-23|1989-01-19|J.H. Benecke Gmbh, 3000 Hannover, De|

DE9101990U1|1991-02-20|1991-05-08|Fibron Gmbh, 7518 Bretten, De|

US5520328A|1994-11-03|1996-05-28|Carrier Corporation|System for providing integrated zone indoor air quality control|

DE19736276B4|1997-08-21|2006-07-27|Alstom Technology Ltd|Optical pyrometer for gas turbines|

US6204483B1|1998-07-01|2001-03-20|Intevac, Inc.|Heating assembly for rapid thermal processing system|

DE10259883B4|2002-11-14|2005-04-21|Daimlerchrysler Ag|Method for producing a composite material|

DE10325602B3|2003-06-05|2004-09-09|Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.|Temperature regulated processing system for substrates including thick film contacts for solar cells has quartz tube with gas inlet, inspection window and pyrometer, surrounded by heating coil|

CA2593519A1|2006-07-14|2009-01-12|Marquez Transtech Ltee|Novel thermoplastic part, tool and method for the manufacturing thereof|

DE102007020176B4|2007-04-25|2010-08-12|Heinz Meßtechnik GmbH|Measuring system for temperature profile measurement in continuous furnaces|

DE102007046472B4|2007-09-28|2013-12-24|Bayer Materialscience Aktiengesellschaft|Process for the preparation of a thermoformed sheet of polycarbonate or polymethylmethacrylate|

AT506097B1|2007-12-14|2010-03-15|Engel Austria Gmbh|HEATING DEVICE FOR A TOOLING TOOL|

DE202009012628U1|2009-09-17|2009-12-10|Eos Gmbh Electro Optical Systems|Device for the generative production of a three-dimensional object|

DE102012004505B3|2012-03-05|2013-04-11|Von Ardenne Anlagentechnik Gmbh|Pyrometer pipe for measuring temperatures at measurement point within chambers in vacuum treatment plant, comprises a pyrometer having a specific end which is set with a transparent partition wall as particle shield, in measuring range|AT517754B1|2015-09-17|2017-10-15|Engel Austria Gmbh|Arrangement for consolidating thermoplastic semi-finished products|

DE102016119703A1|2016-10-17|2018-04-19|Kraussmaffei Technologies Gmbh|Method and device for producing molded parts with a semi-finished product|

DE102017011312A1|2017-12-08|2019-06-13|Broetje-Automation Gmbh|Apparatus for producing preforms|

DE102018109945A1|2018-04-25|2019-10-31|Kraussmaffei Technologies Gmbh|heater|

CN110849701A|2019-11-04|2020-02-28|山东见微生物科技有限公司|Sample processing apparatus|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

ATA572/2013A|AT514454B1|2013-07-11|2013-07-11|heater|ATA572/2013A| AT514454B1|2013-07-11|2013-07-11|heater|

DE102014010173.8A| DE102014010173C5|2013-07-11|2014-07-09|heating device|

CN201410328586.4A| CN104275782B|2013-07-11|2014-07-11|Heater, forming machine and heating process of semi-finished|

[返回顶部]