DE4436013A1 - Heating system for heating of fluid or flowable media continuously or intermittently - Google Patents

Abstract

The ceramic carrying body (12) is connected using a thermally conducting adhesive material (20) with a heat distributor (4), and the heat distributor (4) is subjected to the flowing through of the medium to be heated. The resistance track (14) of a hybrid circuit is applied corresp. on the ceramic carrying body (12). The ceramic carrying body is designed plate shaped. A multiple of parallel connected resistance tracks (14) are provided on the carrying body (12).

Description

The invention relates to a device for Heating of flowable or flowable media in the continuous or at intervals Continuous process, with an adjustable, electric heater.

Known heating devices in particular so-called instantaneous water heaters include a Heating device in the form of a tubular heater or a heating cartridge. A tubular heater or one Cartridges contain an electrical one Resistance forming heating wire from one metallic material used for electrical Isolation of magnesium oxide and a die Outside metal sheath is surrounded. Such a heater is either directly from the medium to be heated or by one Heat transfer medium, such as water or a heat transfer oil flows around. However, there are also known devices in which the in the form a tubular heater or a heating cartridge formed heater in a metallic Heat transfer body is added, the in turn in thermal contact with the heating medium is brought.  

The known heating devices are due to their large mass difficult to control or regulate. The Response times for control or regulation processes are long, what the use of such heaters for many Applications that require the highest accuracy are strong limited. During the heating up times of these systems consumed electrical energy that was not used during this time Heating of the flowing medium can be used. Especially if within a time interval Varying temperatures generated in the flowing medium Known devices prove to be sluggish; specified temperatures cannot be set generate with sufficient accuracy, and great tolerance are the consequence. Even if the flowing medium temperature setpoint to be set is reached the actual temperature value due to the excess or After a long time delay the given value. Another disadvantage known Heating devices can be seen in the fact that these are very need a lot of space and accordingly only complex and are expensive to manufacture. To provide Heating output in the kilowatt range are known from Heaters need high voltages what again in many areas where only low voltage is used Is available, these devices do not can be used as desired.

Another disadvantage is that the surface resilience known systems due to the physical properties the materials used are very limited. Height Heating outputs, especially in connection with high Heating currents are therefore not in a small space reachable.  

Furthermore, the susceptibility to corrosion is to be mentioned, which the Lifespan from in direct contact with aggressive Media-standing tubular heaters also when used high-alloy steels limited.

The disadvantages mentioned above have the consequence that known heating devices in many areas of Medicine, laboratory technology, food processing, Calibration technology, aircraft industry etc. not, not are sensible or can only be used to a limited extent.

The invention is therefore based on the object Heating device of the type mentioned create, in which the disadvantages mentioned do not occur and which is particularly characterized by fast response times, very precise controllability and high efficiency in the Heat transfer distinguishes and yet on economic Way is producible.

This object is achieved in that the Heating device of the heating device a ceramic Carrier body with one attached to it Heating resistor for electrical current Resistance path from a resistance paste includes that the ceramic carrier body by means of a thermally conductive Adhesive material is connected to a heat spreader and that the heat spreader from the medium to be heated is flowable.

A heating device designed in this way can be opened realize the smallest installation space; the heat capacity of the Heater is compared to known devices considerably reduced what the response times in considerably shortened, so that a precise regulation of the Temperature is possible. The surface resilience of the  ceramic carrier body is many times higher than in known heating devices. It can vary depending on Substrate temperatures up to 1300 ° Celsius can be generated without that there is damage to the carrier body.

The ceramic carrier body with high thermal Conductivity is preferably plate-shaped, that is, its thickness is compared to its longitudinal and Transverse extent is low, which is a slight Thermal resistance between the resistance track and that of the heat distributor through which the medium can be heated affects. Due to the low mass and consequently low Heat capacity combined with high thermal Conductivity is the efficiency of the invention Heating device compared to known devices increased, and the response times are shortened. It can be higher in a smaller space Heating outputs are made available.

With a substantially flat carrier body, the Resistance path corresponding to a hybrid circuit, especially in the screen printing process, on the ceramic Apply the carrier body. It is particularly advantageous here that the resistance trajectory of one related Hybrid circuits known resistor paste can be manufactured.

In a particularly advantageous embodiment of the heating device according to the invention are on the Carrier body a variety of connected in parallel Resistance tracks provided. With the same resistance falls then the same specifiable on each resistance track Voltage and thus the same heating power. It can be but also through resistance tracks with different electrical resistance one over the extension of the  Heating device or the support body varying Achieve power delivery. This proves, for example then as advantageous if within the heat spreader several separate flowing media should be heated to different degrees or a Temperature drop in the edge area should be avoided.

With regard to a compact and integral design proves it turns out to be advantageous if one with the heater and temperature sensor interacting with a controller, in particular based on PTC or PT, on the ceramic Carrier body applied, in particular is printed. This is an accurate surface temperature tap and thus a safe limitation of the surface temperature possible what may be required with problematic media can and also allows exact temperature control. Of the However, temperature sensors can also be operated using a thermally conductive adhesive applied to the heater his. To the current actual temperature of the Heat distributor flowing medium precisely record and at the It is proposed to be able to take regulation into account within the heat spreader another of the medium to provide flow-around temperature sensors.

The heat spreader can be thermally good from any conductive material that are for use in the occurring temperatures is suitable. Preferentially if the heat spreader is made of aluminum, which is in terms of specific heat capacity, the Machinability and thermal conductivity as has proven particularly advantageous.

The invention further relates to a device of type mentioned above, in which the heating device of the medium to be heated can flow around within a  Heat exchanger unit serving flowable container is arranged. To overcome the aforementioned and problems occurring equally with this device, the device is designed so that the heating device a ceramic support body with one on it applied a heating resistor for electric current forming resistance path from a preferably curable Resistance paste includes and that the resistance track on the ceramic carrier body of an electrically insulating Layer is covered.

Through the insulating layer is the flow around Heater prevents an electrical short circuit and thus the functionality of the heating device guaranteed. The heating device can flow around Development of the invention as explained above advantageously trained and in particular in a suitable manner be fixed within the heat exchanger unit.

Further details, features and advantages of the invention result from the attached drawing and from the following description of three preferred Embodiments of the invention Heating device. Show it

Fig. 1 shows a preferred embodiment of the device according to the invention;

Fig. 2 shows another preferred embodiment of a modular form expandable heating device and

Fig. 3 shows an embodiment of the device according to the Invention, which is arranged to flow around within a heat exchanger unit.

Fig. 1 shows a heating device according to the invention in the form of a flow heater, generally designated by the reference numeral 2. The instantaneous water heater 2 comprises a heat distribution body 4 and an electrical heating device 6 mounted thereon. The heat distributor body 4 has an inlet connection 8 and an outlet connection 10 , to which lines (not shown) for supplying or discharging a medium to be heated can be connected. The inlet and outlet connections 8 , 10 are connected by means of heat exchanger tubes, also not shown, which run inside the distributor body 4 .

The heating device 6 comprises a plate-shaped ceramic carrier body 12 and resistor tracks 14 made of one or different resistor pastes, as are also used in hybrid electric circuits. The resistance tracks 14 are connected in parallel to each other in the illustrated embodiment and have the same electrical resistance, so that the heating power remains the same over the extent of the heating device 6 when a heating voltage is applied to the connections 16 by means of an indicated regulator device 18 . The choice of different resistance pastes and the different design of the resistance tracks make it possible to vary the electrical resistance of the resistance tracks 14 and thus achieve different heating powers at different points in the heating device.

A thermally conductive adhesive has been used for the mechanical fastening and for the thermal coupling of the heating device 6 or of the plate-shaped ceramic carrier body 12 to or on the heat distributor body 4 . The accuracy and inertia of the temperature control can be influenced by the choice of a suitable adhesive material. If an adhesive with a high thermal conductivity is used, which is also insensitive to temperature differences, in particular does not form cracks, does not come off or evaporate, etc., a temperature control that is accurate to 0.1 ° Celsius can be achieved with the instantaneous heater shown. While the heating power in known devices due to the limited surface load of the materials used is in the order of 10 W / cm² of the heating device, about ten times can be achieved with the instantaneous heater described above.

The resistance tracks 14 are applied to the ceramic carrier body 12 in accordance with a hybrid circuit using the screen printing method.

Furthermore, a temperature sensor 22 which interacts with the controller 18 is provided, which is designed as a PT sensor and is also printed on the carrier body 12 .

In order to prevent short circuits in the heating device 6 and to ensure thermal stability with regard to aging, the resistance tracks 14 or the ceramic carrier body 12 are covered by an electrically insulating protective layer made of a glass or a glass-containing material.

FIG. 2 shows a further embodiment of the heating device according to the invention, which, like the device described above, also comprises a heat distributor body 30 and a heating device 32 designed in accordance with the heating device 6 . A temperature sensor 34 is applied to a separate ceramic carrier plate 36 , which in turn is applied to the ceramic carrier body 40 of the heating device 32 by means of a thermally conductive adhesive 38 .

The heat distributor 30 is arranged between two deflection or distributor blocks 42 and 44 . The deflection or distribution blocks 42 and 44 are connected by brass rods 46 extending therethrough in the blocks 42, 44 through openings 48 by means of screw and held. Connections 50 and 52 of the heat distributor body 30 through which flow can extend through the deflection or distributor block 42 and 44 and form connecting flanges for piping, hose connections or the like.

The height of the deflection or distributor blocks 42 , 44 is selected so that the electrical connections of the heating device 32 and the temperature sensor 34 can be guided away to the side. The assembly of heat distributor body 30 with deflection or distributor blocks 42 , 44 and heating device 32 can thus be stacked, so that several such assemblies can be arranged one above the other or next to one another. The modules can be connected in series by connecting the connections 50 , 52, for example, which can be recommended if the highest heating output is required. Due to the design of the blocks, parallel as well as serial connections of the piping are possible. The assembly described above provides a flexible and versatile heating device which, according to current requirements, can only be combined temporarily or permanently using suitable piping to form a larger device.

In a side wall of the deflection or distributor block 42 , a closure 54 is shown, which closes an opening for a temperature sensor which can be inserted therein, by means of which the temperature of the medium flowing or flowing within the heat distributor body 30 can be detected. However, two appropriately designed assemblies can also be fluidly connected to one another via the opening 56 . The end connections 50 , 52 can then be dispensed with, which makes the assembly appear even more compact.

Fig. 3 shows a flow-around within a heat exchanger unit 58 of the medium to be heated heating means 60 which comprises a ceramic support body 62 having thereon a resistor track 64 which is covered by an electrically insulating layer 66. The heating device 60 is designed in accordance with the above statements and therefore need not be described in more detail.

Claims (11)

1. Apparatus for heating flowable or flowable media in a continuous or intermittent continuous process, with a controllable electrical heating device, characterized in that the heating device ( 6 , 32 ) has a ceramic carrier body ( 12 , 40 ) with a heating resistor applied thereon Electric current-forming resistance track ( 14 ) comprising a resistance paste, that the ceramic support body ( 12 , 40 ) by means of a thermally conductive adhesive material ( 20 ) is connected to a heat distributor ( 4 , 30 ) and that the heat distributor ( 4 , 30 ) can be flowed through by the medium to be heated. 2. Device according to claim 1, characterized in that the resistance track ( 14 ) of a hybrid circuit is correspondingly applied to the ceramic carrier body ( 12 , 40 ). 3. Device according to claim 1 or 2, characterized ge indicates that the ceramic carrier body plat is ten-shaped. 4 Device according to one or more of the preceding claims, characterized in that a plurality of resistance tracks ( 14 ) connected in parallel are provided on the carrier body ( 12 , 40 ). 5. The device according to one or more of the preceding claims, characterized in that the specific resistance of different sections of the resistance track for generating varying heating power is varied over the extent of the carrier body ( 12 , 40 ). 6. The device according to one or more of the preceding claims, characterized in that the resistance track ( 14 ) on the ceramic carrier body ( 12 , 40 ) is covered by an electrically insulating layer. 7. The device according to one or more of the preceding claims, characterized in that the heat distributor ( 4 , 30 ) is made of aluminum. 8. The device according to one or more of the preceding claims, characterized in that a with the heating device ( 6 , 32 ) and with a controller ( 18 ) cooperating temperature sensor ( 22 ) is printed on the ceramic carrier body ( 12 ). 9. The device according to one or more of the preceding claims, characterized in that a with the heating device ( 6 , 32 ) and with a controller ( 18 ) cooperating temperature sensor ( 36 ) by means of a thermally conductive adhesive ( 38 ) applied to the heating device ( 32 ) is. 10. The device according to one or more of the preceding claims, characterized in that within the heat distributor ( 4 , 30 ) with the heating device ( 6 , 32 ) and with a controller ( 18 ) cooperating, from the medium to be heated temperature sensor is provided . 11. Device for heating flowable or flowable media in a continuous or intermittent continuous process, with a flowable from the medium to be heated and arranged within a heat exchanger unit, adjustable electrical heating device, characterized in that the heating device ( 60 ) with a ceramic support body ( 62 ) an applied to it, forming a heating resistor for electrical current resistance track ( 64 ) from a resistance paste and that the resistance track ( 64 ) on the ceramic carrier body ( 62 ) is covered by an electrically insulating layer ( 66 ).