DE1566902B2 - THERMALLY ACTIVATED FLASHING SIGNAL GENERATOR WORKING WITH CONSTANT LOAD - Google Patents

Description

The invention relates to a thermally actuatable one which operates with constant load Flasher device, including a fixed bracket, one of each by the load flowing load current through which snap plate flows and a snap plate connected to it, from the same, each load current flowing through the load throughflosser.es tendon carries, the heats itself up to such a current flow solely because of its own resistance, and so far extends that a moving contact, which is normally on one in the load circuit fixed contact is applied and the respective load current through the snap plate and passes through the tendon, lifts from the fixed contact until the tendon is has cooled down again and contracted sufficiently.

There is already a flasher device known (US Pat. No. 2,706,227), which has a rectangular Contains snap plate with a tensioning band stretched over this. The snap plate carries one Contact that lies opposite a further contact that is isolated in one that carries the snap-on plate Bracket is arranged. The two contacts mentioned are except in the normal state of the arrangement Intervention. With the tension band, which is a resistance band that expands when exposed to heat, is a resistor connected to its one end. The other end of the resistor is with the said connected to a contact. When using this known flasher device in a flasher circuit First, a current flows through the bracket that carries the snap plate and that through the snap plate tensioned tension band and the resistance mentioned. As a result of this current flow, the heats up Clamping tape in such a way that the snap plate in its other possible position after a certain period of time turns. In this position, the additional contact connected to the snap plate touches it opposite contact. So then there is the resistance and that which is in series with it Tension band bridged so that now over the bracket, the snap plate and the closed Contacts a current flows. This current then causes the flashing circuit in question to light up lying light bulbs. After the tension band has cooled down and tightened the snap plate then jumps back into its starting position, in which the said further contact is lifted from said one contact. The explained process then begins anew.

The disadvantage of the known flasher device considered above is that only after it has expired A corresponding lamp current will flow over a certain heating-up time of the associated tensioning strap can. In addition, in this known flasher device, the size of each in the load circuit load does not affect the duration during which the load current flows. In the difference this is in the flasher device according to the invention, the duration during which a load current flows, depending on the size of the load in the load circuit. Only with constant The flasher device according to the invention works with a constant load in the load circuit Working frequency.

There is also a flasher system known (US Pat. No. 3 196 311), which is an actual Includes flasher and two switching arrangements. The flasher contains a Rectangular snap plate with a tensioning strap stretched over it, which is attached to a corresponding Heating leads to a snapping of the associated snap plate. With the strap is a contact connected, the one connected to a bracket contact in the idle state of the blinking signal generator touched. One of the two switching arrangements provided comprises a snap-on plate with a tightening strap stretched over it. The snap plate is connected to a contact which is arranged opposite a fixed contact. The strap in question is thereby indirectly heated by means of a heating coil wound around the tensioning band in question. the The tightening strap is only heated when the entire blink signaling system is operated in a certain manner. For the duration of such an operating mode, the aforementioned contacts are mutually exclusive lifted off so that no current can flow through them. The other switching arrangement that is still planned serves as overvoltage protection. It consists of a snap plate with a mounted on it Contact and a tensioning strap stretched over the relevant snap-on plate, which is operated by a heating coil is surrounded. The heats up when this heating coil is heated accordingly Tension band. At the same time, the tension band expands until the snap plate finally snaps over and with its aforementioned contact a contact arranged opposite it touched. This creates a parallel circuit to the one containing the snap plate mentioned above . Flasher activated. In this way, the the same voltage as with normal operating voltage. Only when the normal operating voltage occurs the parallel circuit is disconnected again.

There is also an electromagnetic flasher known (German Auslegeschrift 1 197 787), the an electromagnet lying in a blinking circuit with an associated switch armature and contains a hot wire that also actuates this switch armature. This well-known electromagnetic flasher works in such a way that a heating current flowing through the hot wire and the electromagnet causes the hot wire to heat up and expand. However, the current flowing is sufficient does not go off to illuminate any lamps in the blinker circuit. Beyond that is enough this current is also not used to excite the electromagnet and attract the switch armature. The linear expansion of the hot wire, however, has the effect that the one connected to this hot wire is insulated Switch armature is moved out of its rest position and after sufficient movement two normally, d. H. When the flasher unit is in the rest position, open flasher contacts closes. The closure of these flashing contacts has the consequence, on the one hand, that the lamps cause such a high Electricity flows so that these lamps light up. On the other hand, this current flow has the consequence that the Electromagnet is so strongly excited that it attracts its associated switch armature, which thus the flashing contacts remains closed. When closed

These flashing contacts are the hot wire through a relatively low-resistance, electrically conductive connection bridged. This has the consequence that the hot wire cools down and contracts again. Has If the hot wire has cooled down sufficiently, it again exerts such a force on the switch armature that this is moved out of its just assumed position. This will make the two Flashing contacts open again. A heating current now flows through the hot wire again and warmed up with it. In the case of the electromagnetic flasher unit just considered, the flashing function is carried out by means of both electromagnetically and thermally actuated elements. In contrast to this, the flasher device according to the invention is purely thermally actuable Flasher transmitter.

Finally, an electrical snap-action switch with an expandable clamping member is known (German Auslegeschrift 1 195 394), which is stretched diagonally over a rectangular snap plate and which in the Cold state biases this snap plate in a certain position. The tendon carries in its center a contact that rests against a stationary contact when the tendon is cold. the Both contacts, which are in contact with one another when the tendon is cold, are in a load circuit. If this load circuit is closed, then flows through the two adjacent ones Contacts and thus the load current via the tension member carrying one contact. On the If this load current flows, the tendon is heated and expanded until the snap plate snaps over and leads to the lifting of one contact from the fixed contact.

The load circuit is then interrupted. Only after the tendon has cooled down sufficiently This pulls itself back so far that the snap plate returns to its original position and so that said one contact comes to rest against the fixed contact again. The process just explained is then repeated anew. A disadvantage with this known thermoelectric snap switch is mainly that the clamping member carries a contact. This arrangement results in a substantial in this known snap switch shorter service life than flashers, where the respective tendon does not have any Contact carries.

The invention is now based on the object of showing a way, such as one with constant load to train working, thermally actuated flasher device of the type mentioned is, therefore, the stresses caused by the intended moving contact the envisaged tendon are kept away and otherwise with relatively little constructive Effort can be managed.

The above-mentioned object is achieved with a flasher device of the type mentioned at the beginning Kind in that, according to the invention, the tensioning member has a directly permanently connected to it, the respective Load current carrying flexible connecting member carries that the movable contact on the Snap plate is attached directly so that one takes place with expansion of the tendon Change of shape of the snap plate to lift this contact from the fixed contact and thus leads to an interruption of the load circuit and that a contraction of the tendon again to apply this contact to the fixed contact and thus to close the Load circuit leads.

The invention has the advantage over the known arrangements considered above that with relatively simple constructive means

ίο one that works with constant load, purely thermal actuatable flashing signal generator is created in which by moving the provided movable Any stresses occurring during contact are kept away from the envisaged tendon. Through this is achieved above all that the operating characteristics of the flasher device according to the invention and thus its service life compared to the corresponding values of known flashing signal generators, in which an envisaged tensioning element is movable and is located in the respective load circuit Contact carries, are improved.

Further expedient embodiments of the invention are given below with reference to drawings explained in more detail. It shows

Fig. 1 schematically shows a flasher device constructed according to the invention in a typical Signaling system,

F i g. 2 schematically shows another embodiment of a flasher device according to the invention and

F i g. 3 schematically shows yet another embodiment of a flasher device according to the invention.

The following is the one shown in FIG. 1 illustrated embodiment of the flasher device according to the invention explained in more detail. With this flasher unit, the associated contacts are normally closed. The intended signal lamps are switched on at the moment in which the Circuit by pressing a direction signal switch, such. B. a toggle switch, is closed. By periodically opening and closing the mentioned contacts, the Signal lamps switched on or off.

The one shown in Fig. 1 and designated 13 Flasher transmitter contains a snap plate 14 which is arranged on a stationary holder 15. The snap plate 14 carries a clamping member 16 with which a flexible connecting member 21 in Is firmly connected in the form of a connecting line.

As a connecting member or flexible connecting line 21, any flexible electrically conductive Structures are used, such as a wire mesh or a metal band, one end of which is in a suitable manner Manner is attached to the tendon 16, such. B.

by welding. The flexible connecting member or the flexible connecting line 21 is on the through a tensioning band formed tensioning member 16 preferably fastened in the middle between its ends, so that a corresponding division of the load current flowing through the tensioning strap 16 takes place.

A movable contact 17 is electrically connected to the snap plate 14. Compared to the movable Contact 17 is a fixed contact 18 is arranged. Usually, i. H. when the Tension band 16, the movable contact 17 rests against the stationary contact 18.

The end of the flexible connecting member or end facing away from the tensioning band or tensioning member 16.

the flexible connecting line 21 is connected via a supply terminal X to one pole of a battery 11, which is grounded at its other pole. Four signal lamps 12 can be connected to said stationary contact 18, which is connected to a load terminal L via a line 19, via a travel direction signal switch TS. Of these signal lamps 12, the left and rear signal light each contain three incandescent lamps, while the respective front signal light contains only one signal lamp. As a result of the respective connection of the signal lamps 12 to the load terminal L , the load on the flasher remains constant regardless of the respective direction of travel display (left or right) as long as all the incandescent lamps are in operation. The properties of the flasher transmitter are selected so that a desired flashing sequence results for the number of incandescent lamps given for the respective side of the vehicle and the load current flowing with it.

With regard to the load circuit in which the flashing signal generator shown in Fig.l is located, it should be noted that this flashing signal generator works in the same way when the battery 11 and the signal lamps 12 are connected to the terminal L and X , respectively, in deviation from the relationships shown. Furthermore, one of the two terminals could be grounded through a resistor circuit.

In the following, the mode of operation of the in FIG. 1 illustrated flasher device 13 explained in more detail. When the direction of travel signal switch TS formed by a toggle switch is actuated in order to display a direction of travel, a circuit running from the battery il via the four signal lamps 12 located on the relevant side of the vehicle is closed. The relevant signal lamps 12 light up in this circuit. The mentioned circuit runs in detail via the flasher device 13, namely via the supply terminal X, the flexible connecting line or the flexible connecting member 21, the tensioning strap 16, the snap plate 14, the adjacent contacts 17 and 18, the line 19 and the load terminal 11. Since the tensioning band 16 is subject to resistance, this tensioning band 16 is heated when a current flows. As a result of this heating, the tensioning band 16 in question expands, as a result of which the snap plate 14 is enabled to jump over from its forced position into its return position. The movable contact 17 lifts from the stationary contact 18, whereby the circuit is interrupted. When the circuit is interrupted, the signal lamps 12 go out and the tensioning strap 16 cools down again. When the tension band 16 has cooled down sufficiently, the snap plate 14 returns to its forced position in which the movable contact 17 and the fixed contact 18 touch each other again and the signal lamps 12 light up again. The tensioning strap 16 heats up again and, as a result of its expansion, causes the snap plate 14 to snap over. The cycle explained continues as long as the travel direction signal switch TS is in the working position.

As with known flasher devices, the snap plate 14 here contains the fixed holder 15. The jumping of the snap plate 14 between the return position and the constrained position has a movement of that snap plate part which carries the movable contact 17, opposite to which the fixed contact 18 is arranged. The movement of the snap plate 14 also causes a Movement of the tension band 16. The flexible connecting member 21 used prevents any Hindrance in the movement of the tension band 16. Regarding the connection of the flexible connecting member 21 with the tightening strap 16 it should be noted that the flexible connecting member in question is around the tightening strap 16 may be wrapped or crimped around or welded to it, such as by spot welding. By welding on one end of the flexible connection line or the flexible Connection member 21 on the tensioning strap 16 is its molecular structure and the otherwise uniform Although the stress concentrations have been modified, the operating properties are still relatively good during the life of the flasher device concerned. Can be used in the manufacture of the avoiding the weld in question, even greater advantages are achieved. By Wrapping or crimping the flexible connection line or flexible connection member in question 21 around the tensioning strap 16 connections with such good results can be achieved, as they occur per se in arrangements in which over the entire length of the respective Tension band no tensile stress occurs. Such an arrangement is shown in more detail in FIG.

The in F i g. The arrangement shown in FIG. 2 and showing a further embodiment of the flasher device according to the invention differs from the arrangement shown in FIG. 1 essentially by a different shape of the tensioning strap. The snap plate, the stationary holder and the contacts are arranged here in the same way as in FIG. 1. The tensioning band 31 provided according to FIG. 2 consists of an electrically conductive resistance strip. If desired, the tensioning strap 31 in question can have a largely uniform width, apart from an area which is preferably located in its center. The tensioning band 31 is provided with a shoulder 32 running transversely to its longitudinal axis. A flexible connecting line 33 is welded to one end of the extension 32, the other end of which is connected to the supply terminal X in a suitable manner. From Fig. 2 it should be apparent that the longitudinal axis of the tensioning band 31 is free from all external tension loads, which normally result from the connection of a flexible connecting line to the tensioning band. While a feed on the longitudinal axis of the tensioning band normally represents the strongest form of tension stress, the aforementioned wrapping or folding can also have a corresponding effect on the tensioning band. External factors influence the uniformity of the heating and cooling speeds, the expansion and contraction of the tensioning band during its service life; by reducing the influence of such external factors, as already stated above, the desired operating characteristics of the flasher device can be maintained for a long period of time.

By using a tightening strap 31 with an attachment 32 as shown in FIG. 2 will be the impact external factors considerably reduced. As with the

Arrangement according to FIG. 1, the electrical connection to the tensioning strap 31 must also be flexible here, to allow free movement of the snap plate 14 and the tensioning strap 31 during switching guarantee. According to FIG. 2 is a flexible connecting line or a flexible connecting member electrically conductive tape 33 has been used. It is just as possible, however, any other use flexible connector here.

As in Fig. 1 and 2, the electrical connection to the tensioning strap 16 or 31 preferably in the middle between its ends. In this way, the through the strap and the snap plate 14 to the contacts 17, 18 flowing current evenly divided, whereby a largely uniform heating of the tension band is effected. Although the flasher too would work satisfactorily with connections other than a middle connection, this would result in ^ however, an uneven heating of the tensioning band, namely as a result of an uneven Current distribution in the relevant tension band.

According to the arrangement shown in FIG. 3, which shows a further embodiment of the flasher signal generator according to the invention, an elongated extension 42 projects away from a tensioning strap 41. The tensioning strap 41 and the extension 42 are punched out as a coherent part, the extension 42 being slightly bent at the point 43. In this way, the structure in question is given the necessary flexibility to be able to be used as a coherent flexible connecting member. The approach 42 is directly connected to the supply terminal X. In this way, an actually “tension-free” tensioning band 41 is available.

Claims (10)

Patent claims: 1. Thermally actuated flasher generator operating with constant load, containing a fixed bracket that has a snap plate through which a load current flowing through the load flows and a snap-on plate connected to this, through which the same load current flows through the load Tendon carries that is based solely on its own resistance on such Current flow is heated and so far expands that a movable contact, which is normally connected to a stationary contact in the load circuit is applied and the respective Load current passes through the snap plate and through the tendon, of which fixed contact lifts off until the tendon has cooled down again and contracted sufficiently has, characterized that the tensioning member (16) has a directly fixed connection to it, the respective load current leading flexible connecting member (21; 33; 42) carries that the movable contact (17) on the snap plate (14) so directly is attached that a change in shape with expansion of the tendon (16) Snap plate (14) for lifting this contact (17) from the fixed contact (18) and thus leads to an interruption of the load circuit and that a contraction of the Tensioning member (16) again to apply this contact (17) to the fixed contact (18) and thus leads to the closing of the load circuit. 2. Flasher transmitter according to claim 1, characterized in that the clamping member by a Tension band (16) is formed which is attached to the snap plate (14), and that the snap plate (14) is pretensioned in such a way that it is pretensioned from its preloaded on heating of the tensioning band (16) Position pops out and only after the tensioning band (16) has cooled down in this prestressed Position jumps back. 3. Flashing signal generator according to claim 2, characterized in that the tension band (16) is connected to a first connection terminal (X ) via a flexible connecting line (21) directly connected to it, that the snap plate (14) is connected to a second connection terminal (L) is connected and that the load circuit runs through these terminals (X, L) . 4. Flashing signal generator according to claim 3, characterized in that the tensioning strap (16) with its Ends on the snap plate (14) is attached and that the flexible connecting line (21) in the middle of the tensioning strap (16) is attached to this. 5. flasher transmitter according to claim 3 or 4, characterized in that the flexible connecting line (21) is welded at one end to the tensioning strap (16). 6. flasher transmitter according to claim 2, characterized in that the one with the snap plate (14) directly connected contact (17) on this snap-on plate (14) at one of its fastening points is arranged with the holder (15) remote location. 7. flasher unit according to claim 2, characterized in that the tensioning strap (16) in its Longitudinal direction has a largely uniform width and that at least at one point of the tensioning strap (16) is provided with an attachment (32, 42) serving to conduct current. 8. flasher device according to claim 7, characterized in that the projection (32, 42) in the Center of the tension band (31, 42) is provided between its ends. 9. flasher transmitter according to claim 7 or 8, characterized in that a flexible connecting line (33) is welded to the end of the extension (32). 10. flasher transmitter according to claim 7 or 8, characterized in that the tensioning strap (41) associated approach (42) itself serves as a flexible connecting line (FIG. 3). 1 sheet of drawings 109 526/41