SE450028B - ELECTRICAL HEATER FOR SUCTION PIPE IN COMBUSTION ENGINES - Google Patents

Description

450 028 OJ elements which previously stood reliably in a well heat-transmitting connection, which at the same time is and remains electrically conductive. The spacer thus serves as a leveling part, which allows each element a certain independent deformation under the influence of heat. The same is achieved even when there are such spacers between the heating elements on the one hand and the underlying holding devices on the other hand, which is also possible. If an electrically conductive adhesive is used as a liner, in particular an incompletely curing silicone-based conductive adhesive, this also affects the fixing of the heating elements on the heating plate} The adhesive layer can then also meet the extreme requirements at extreme temperatures from + 180 ° C to -40 ° C without risk of the heating elements coming off the hotplate. In addition, the liner takes up certain tolerances at the fastening points of the heating elements. The holding devices described have the advantage that, at least within certain limits, they give a resilient elastic force on the back of the heating elements and press their fronts against the heating plate. Thanks to special constructive measures, this compressive force is reproducible during assembly without the need for special measurements and adjustment work. It amounts to, for example, 15N (approximately 1.5kp). If the holding means together with the heating elements attached thereto form a mounting unit, for example the support plate a mounting unit with the contact bridge, on whose spring arms the heating elements are located, the assembly of the device is particularly simple and reproducible. A seat in the housing for the support plate gives it an accurate insertion depth, as well as for the radial position, so that these predetermined conditions also apply to the parts sitting thereon. The insulating support plate also guarantees that the wholesale heat does not, for example, radiate away backwards as loss heat, but is transferred to the heating plate as directly as possible. The contact bridge is, as described, a mounting aid and is designed in such a way that it guarantees an electrically well-conducting connection to the heating elements, generates a certain contact pressure and, due to a small material cross-section, practically does not dissipate any heat energy as possible loss energy.

In the following, the invention will be described in more detail with reference to exemplary embodiments shown in the drawing. Fig. 1 shows a schematic section through an electric heating device according to a first embodiment; Fig. 2 is a sohematic section along the line II-II in Fig. 1; Fig. Ba is a schematic section approximately corresponding to that of Fig. 1 by a second embodiment; Figs. 5b and 30 are each schematic views of limited elastic spacers in the heating device according to FIG. Fig. 4 is a schematic section approximately corresponding to that of Fig. 1 through a heating device according to a third embodiment; Fig. 5 is a section through the heating device according to Fig. 4, but turned 450; and Fig. 6 is a schematic section approximately corresponding to that of Fig. 1 by a heating device according to a fourth embodiment.

The electric heating device shown in Figures 1 and 2 is intended for heating intake pipes (not shown) in internal combustion engines. It is inserted into an opening in the intake manifold. Heating device has a heating plate 10, for example of aluminum, which on the one hand has projections 11 for improving the heat transfer and on the other hand a flat abutment surface 12, on which several heating elements in the form of PTC elements (resistance elements with positive temperature coefficient) late) 13-16 is held in good heat-conducting contact. For this purpose, holding devices are used, which form an electrical connection in contact with the PTC elements 15-16. The heating plate 10 is a one-piece component of an approximately trough-shaped housing 17 with an inner annular shoulder 18 and grooves for receiving a clamping ring 19. By means of these two, a support plate 20 of synthetic material is held at a predetermined distance from the heating plate 10. In addition, there is a resilient contact bridge 21 of material with good electrical conductivity, eg bronze or brass. It has a flat middle part 22, which is supported by the middle of the support plate 20. From the middle part 22 emerge approximately star-shaped spring arms 23-26, which are approximately Z-shaped booked in cross section and each of which is assigned to a PTC element 13-16. While the upper horizontal Z-leg of each spring arm merges into the middle part 22, the lower, thus approximately parallel Z-leg of each spring arm 23-26 has an approximately semicircular contour and flat flat side, with which it with the entire surface and with a large electrical transition surface is in contact with the back of the respective assigned PTC element. The parts lying between the middle part 22 and the flat sides of the spring arms 23-26 each have openings 27-30, which improve the thermal conductivity conditions. Prior to final assembly, the lower Z-legs of the spring arms 23-26 are inclined by approximately 30 relative to the abutment surface 12 to provide a bias. The contact bridge 21 is designed to press together with the support plate 20 with the lower legs of the spring arms 23-26 with prestress against the back of the PTC elements and with as smooth a surface as possible press them against the abutment surface 12. Between the PTC elements 13-16 and the abutment surface 12 there is an electrically conductive adhesive, which is at least limited elastic, preferably permanently elastic. The adhesive 31 is a conductive silicone-based adhesive which contains conductive particles of copper and / or silver and which is not completely cured. This not only causes the PTC elements to adhere, but also forms a leveling layer between the heating plate 10 and the PTC elements 13-16 due to the elasticity. The adhesive 31 thus takes into account the different, material-dependent temperature expansion coefficients and ensures that the elements can function independently of each other. Furthermore, the adhesive 31 prevents the PTC elements from coming loose in temperature ranges between + 180 ° C and -4000. The adhesive 31 has a high electrical conductivity thanks to a quantity proportion of, for example, 60-70% conductive particles. The thermal conductivity is also very good.

From the central part 22 of the contact bridge 21 a connecting tab 32 is cut out and passed approximately stepped outwards through a slot 33 in the support plate for electrically conductive contact with a cable 34. In addition, two tongues are cut out at the two spring arms 24 and 26 and passed through invisible slots in the support plate 20 and then crossed and / or bent over. Fig. 1 shows only two ends 35, 36. In this way the support plate 20 and the contact bridge 21 form a building block for the assembly. Even before assembly, the PTC elements 13-16 are fixedly connected to the spring arms 23-26, more precisely by soldering or by means of an electrically conductive adhesive, which for example corresponds to the adhesive 31. At the right end, the housing 17 is closed by means of a riveted lid 37; Via the cable 34, current is supplied, which flows via the connection tab 32 and the contact bridge 21 with the spring arms 23-26 to the PTC elements 13-16 and from these via the heating plate 10 and eg ground back. Because such PTC resistors in the cold state conduct a corresponding current extremely well, they heat up quickly, so that already after about 10-12 seconds all the heat required for heating the intake air passing through the invisible intake pipe is available. With increasing natural temperature, the internal resistance increases, so that at a certain temperature value the internal resistance of the PTC elements becomes so high that almost no conduction takes place anymore. The PTC resistor can therefore not be heated further. As the temperature drops, the resistance decreases again, so that current can be conducted again. These thermostatic properties of PTC resistors are used here for temperature-dependent control. The contact bridge 21 presses with predetermined force of, for example, up to about 15N (1.5kp) resiliently elastically against the PTC elements 13-16. The spring arms 23-26 rest with a large surface against the PTC elements_13-16 with good electrical contact. In the second embodiment in Figs. 3a ~ 3c, the contact bridge 121 also consists of sheet metal. Its spring arms 123, 125 are bent inwards approximately as a horizontal U. The openings 127, 129 are located here in the base area between the U-legs. The heating plate 110 has for each PTC element a corresponding depression 140, 141. As at least a limiting elastic spacer between the PTC elements 115, 115 and the heating plate 110, there are electrically and thermally well conductive grids 142, 145. , for example of a net of silver wire. The grid 142, 145 is located in the associated recess 140 and 141, respectively. The PTC elements 115, 115 are slightly smaller in diameter and are pressed against the grids 142, 145. The grid material is a relatively soft, malleable material, whereby an at least limited elastic spacer between the heating plate 110 and the PTC elements 115, 115.

The gaps in the grille 142, 145 are filled with heat-conducting paste.

In Fig. 5c, the liner has approximately the shape of egg carton with, for example, uniformly successive elevations. Such a wave portion may be wavy in both axial directions in a plane coordinate system. It consists, for example, of relatively soft material with good thermal conductivity. Here, too, the spaces are filled with heat-conducting paste.

According to Figs. 4 and 5, a position-determining disc 251 of insulating material, for example artificial mass, is laid on the flat abutment surface 212 and has a suitably shaped recess 252, 255 for each PTC element 215, 215. In each recess 252, 255 is a suitable spacer in the form of a circular disc-shaped grid 242, 245. The holding means press the PTC elements 215, 215 against the grids 242, 245 and the heating plate 210. The contact bridge 221 also serves here to hold the position-determining disc 251. For this purpose holding arms 254, 255 with a Z-shaped cross-section are bent out of the contact bridge 221 between the spring arms 225, 225 at a height with a peripheral angle of 450, wherein flaps at the middle part 222 are also passed through slots in the support plate 220 and serve for fixing and support. In Fig. 6, the contact bridge has a composite sheet 561 of insulating material, the left surface of which is formed as a contact side 562 with good electrical conductivity by copper-plating and then silver-plating.

A connection tab 552 passes through a central opening 565 to the contact side 562, where it is soldered in the center area. The PTC elements 515, 515 are attached to the contact side 562 of the pulp board 561, more specifically either by soldering or by means of an adhesive, for example corresponding adhesive 51 in the first embodiment according to Fig. 1. The PTC elements are held on the contact surface 512 of the hot plate 510 by pasted 551. The support plate 520 has a central recess here. Between the support plate 520 and the composite disc 561 there is an adapted pressure ring 564 with at least spring-like characteristics, which for example consists of artificial mass and undergoes a certain elastic deformation when the support plate 520 is inserted.

Due to this elastic deformation, pressure is applied to the back of the synthetic pulp board 561.

Claims (10)

450 028 F a t e n t k r a v: Electric heater for intake pipes in internal combustion engines, with a heating plate (10,110,210,310), with which the engine's intake air comes into contact, with several heating elements (13-16; 113,115; 213,215; 313,315), preferably PTC elements, which are kept in heat-conducting contact with the heating plate, and with holding means (20,21; 120,121; 220,221; 320, 301, 364) for the heating elements, which holding means by making contact with the heating elements form an electrical connection to these and comprise a contact bridge (21,121,221,321) of electrically conductive plate and on the side of the contact bridge facing away from the heating elements has a connection emanating from the bridge and resiliently connected cross member with the connection, which is pressed by spring means against the back of the heating elements and presses them against the heating plate, and one at a distance from the heating plate fixed and sealed support plate. (20,120,220,320), characterized in that the spring means are formed by the contact bridge itself (21), which consists of spring material, for example bronze or brass, that the contact bridge has a central part (22) made with a flat surface, which supports in a flat surface against a centrally located support part of the support plate (20,220, 320), and that the contact bridge for each heating element as a transverse element has a spring arm (23-26; 123,125; 223,225) extending from the middle part, which is formed in one piece with the middle part and is approximately Z- bent out (fig. 1, 2) or U-shaped bent back (fig. 3a, 4) therefrom, the spring arms (23-26; 123,125) starting approximately star-shaped from the middle part (22) and pressing resiliently against the heating elements (13-16) , and for presetting the compressive force are preferably formed into an inclination of, for example, relative to the heating plate (10, 110), and wherein the parts of the contact bridge (21, 121) which are not in contact with the heating elements are provided with openings (27 ~ 30; 127, 129), eg holes. Electric heater according to Claim 1, characterized in that at least to a certain extent elastic, preferably permanently elastic, outer edges (31; 142, 143; 242, 243; 331) are inserted between the twisted elements (13-16; 113, 115; 213, 215; 313, 315) and the hotplate (10,110,210,310). 3. An electric heater according to claim 1, characterized in that the support plate (20,220,320) is fixed and secured by means of a shoulder (18) and a clamping ring (19). 450 028 P1 l Electric heater according to Claim 1, characterized in that the contact bridge (21; 121; 221) is fixedly connected to the support plate (20; 120; 220), in particular by clamping, sealing or folding, and in that the contact bridge has a screwed-out and bent-out connection. (32), which is passed through a 911m (33) in the support plate (20). Electric heater according to Claim 1, characterized in that the contact bridge has a flat sheet of plastic material (361), the side of which facing the heating elements (313, 315) is designed as an electrically well-conducting member. the contact side (362), with which the plastic disc (361) abuts the heating elements (315, 315), and that on the contact side (362) there is an electrical connection tab (332), which is passed through a slot (363) in the plastic disc (361). ) and through an opening in the cleaning plate (320), and that between the support plate (320) and the plastic disc (361) there is preferably a pressure ring of at least a spring-like type, for example of a plastic material. U Electric heater according to one of Claims 1 to 5, characterized in that the heating elements (13-16; 113, 115; 213, 215; 313, 315) are attached to the contact bridge (21; 121; 221; 321). , by gluing with an electrically conductive glue as a liner., Electric heater according to one of Claims 1 to 6, characterized in that the heating elements (13-16; 313, 315) abut with the entire surface against the heating plate (10; 310) on their holder (20, 21). 361, 364, 320) and are glued by means of an electrically conductive adhesive (31; 331) as a spacer (Figs. 1, 2 and 6), the adhesive preferably being an incomplete, electrically conductive silicone-based adhesive, containing conductive particles, in particular copper and / or silver. Electric heater according to one of Claims 2 to 6, characterized in that the spacer between the heating elements (113, 115; 2.13, 215) and the heating plate (110, 210) provided a soft, deformable, electric and thermal well. conductive grids (142, 143; 242, 243), wire mesh or wave profiled element (Fig. 3c), preferably path profiled in both axial directions in a flat coordinate system and that the gaps in the grid, wire mesh or wave profiled element are filled with heat-conducting material, such as a heat-conducting paste. _ Electric heater according to claim 8, characterized in that the heating plate (110) for each heating element (113, 115) has a recess (140, 141) in which a suitably shaped spacer (142, 143) ) is arranged between the heating plate and the associated heating element. Electric heater according to claim 9, characterized in that it has a positioning plate (251), preferably made of insulating material, for example plastic material, which has a suitably shaped recess for each heating element (213, 215). (252, 253), in which the heating element (213, 215) and between it and the heating plate (210) a suitably shaped spacer (242, 243) are placed, the holding devices, in particular the contact bridge (221), pushing in one direction against the heating elements (213, 215) and press them over the liner (242, 243) against the heating plate (210) and in the other direction with further holding arms (254, 265) the position-determining disc (251) holds against the heating plate (210). “