DE1218589B - Thermoelectric switch, especially flasher - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

HOIh

German class: 21c -40/05

Number: 1218 589

File number: L 45360 VIII d / 21 c

Filing date: July 16, 1963

Opening day: June 8, 1966

The invention relates to a thermoelectric switch which is intended to serve in particular as a flasher unit. Such flasher units are generally used in motor vehicles to signal lights, e.g. B. the Lights indicating the direction of travel to flash. The thermoelectric flasher will be either connected in series with the lamps and thus controlled by the working current, or they are connected in parallel to the lamps and activated by the voltage applied to the lamps.

Although the thermoelectric flasher units for motor vehicles are simpler and cheaper than flasher units of a different type, e.g. B. a motor driven breaker, they have the disadvantage that they are very sensitive to changes in the operating voltage and the ambient temperature are. These changes affect the switching period of the flasher and in some cases also the Ratio of the times in which the flasher unit is closed or open.

It is known that the supply voltage of the electrical systems in motor vehicles changes quite considerably. These electrical systems essentially consist of the vehicle battery and one with your parallel-connected power generator, with the voltage fluctuating within considerable limits, yourself if voltage regulation is provided for the power generator. So z. B. a tension that is rated at 12 volts, will vary from 11 to 15 volts. This relatively large percentage Change in voltage compared to the nominal voltage has the consequence that a correspondingly strong Change in the operating characteristics of the thermoelectric flasher occurs.

The change in the mode of operation of a thermoelectric flasher unit depending on the operating voltage and the ambient temperature is a consequence of the fact that the actuator of the flasher unit is an electrically conductive component with a resistor, the temperature of which is determined by the Working current is increased and which expands according to its temperature coefficient. That's why its heating and thus its expansion is dependent on the applied voltage. Changes this then also changes the time it takes the actuating element to carry out the switching process needed.

In addition, however, the time required for the actuator to expand and contract changes with ambient temperature. Since between the thermal energy W required for a certain expansion of the actuator, thermoelectric switch, in particular
Flasher

Applicant:

Lehigh Valley Industries, Inc.,

New York, N.Y. (V. St. A.)

Representative:

Dr. G. W. Lotterhos

and Dr.-Ing. H. W. Lotterhos, patent attorneys,

Frankfurt / M., Annastr. 19th

Named as inventor:
Arthur F. Bleiweiss, Great Neck, NY;
George Colombo, Far Rockaway, NY;
John B. Dickson, Kew Gardens, NY;
Boris Orlov, Richmond Hill, NY (V. St. A.)

^a 5 the voltage drop in the actuating element E, the current flowing through it / and the time T required to carry out the switching process the relationship W = E · I · T , for a given constant value W the time changes inversely proportionally with every change in E or /.

The signal lights used are incandescent lamps. The filaments of these lamps have a very high temperature coefficient of resistance. As a result, even if the resistance of the signal lamps changes considerably with the current flowing through them, the resistance in the flasher unit is practically constant. However, both the voltage drop in the flasher unit and the current intensity change with the applied voltage, and if the value W remains constant, the actuation time T changes inversely proportional to the applied voltage. This means that the period of the flasher increases with the operating voltage and decreases with its decrease.

If, however, the voltage remains constant but the ambient temperature rises, the work required to expand the actuator by a certain amount is reduced by the proportion which results from the heating due to the increased ambient temperature. As a result, the heating time T, and the number are shortened

609 578/409

the number of switching operations per unit of time is increased. In other words, the required electrical work W changes in inverse proportion to the ambient temperature, so that with constant voltage E and constant current / the heating time decreases and the switching frequency increases.

Attempts have already been made to reduce the flashing frequency of a buckling voltage flasher unit, even if it changes To keep the voltage constant to a certain extent by the hot wire serving as an actuator into an electrically separated current-influenced and voltage-influenced conductor part is divided. The effective length of the sub-conductors is determined in such a ratio, and the necessary balancing resistances are dimensioned in such a way that the time span of the change in length compensates for the differences in current strength within certain specified limits. the The current dependence of the hot wire is thus reduced to a certain extent by such a vote suppressed so far that the flashing frequency changes only insignificantly.

This known device has the disadvantage that changes in the ambient temperature not be taken into account. The use of temperature-dependent resistors should because of them Cost, inertia and voltage drop are avoided. The present invention avoids these Disadvantages and creates a device that is simple and cheap to manufacture and that works reliably, whose coordination can be carried out without difficulty. It is also based on a thermoelectric Switch off with a switching element current-dependent controlling resistor, z. B. an elastic band, whose load contacts also switch the heating current for the controlling resistor on and off, as well as with a voltage-dependent controlling resistor, which has a thermal. Additional element fluctuations in the voltage drop in the Switch can compensate within certain limits. According to the invention, the switch has an additional member on, one end of which is permanently attached and conductive to the input of the controlling resistor is connected and the other end is thermally bendable, as well as an approximately strip-shaped elastic compensation resistor, one end of which is conductive with the output of the controlling one Resistance is connected and the one free end with a contact in the path of movement of the free End of the additional element and also has a heating winding that influences the additional element as a voltage-dependent one controlling resistor, which is the controlling resistor when the load contacts are closed is connected in parallel and is always exposed to the voltage drop in the switch, so that the Additional element when a first predetermined voltage value is exceeded with its free End by making contact with the balancing resistance and the additional link resistance in the shunt to the controlling resistor switches on.

The additional link according to the invention is caused by the applied voltage and the ambient temperature influenced so that both factors contribute to the equalization of the switching frequency. Appropriate the switch is designed so that the additional member with a further increase in voltage to one second predetermined value so far bends the free end of the balancing resistor that there is a Mating contact touches the switching element and thereby short-circuits the additional element resistance, i.e. only the Compensating resistor in the shunt to the controlling resistor switches on.

So there is a relatively large resistance of a certain value in the first switching step Shunt to the controlling resistor (stretch band) of the switching element switched on, namely at a first, slightly higher value of the operating voltage. At an even higher value of the operating voltage If a smaller resistor is switched on in the shunt, the resistance of the switching element relieved even more of the load current and its voltage drop.

Since the controlling, high resistance of the switching element so more or less depending on the increase in the operating voltage is short-circuited, the link works as if a corresponding lower voltage would be applied to it.

With a suitable choice of the electrical constants, the number of circuits per unit of time, so the frequency, and the ratio between the time in which the normally open contacts are closed and the Time in which they are open can be kept essentially constant. If z. B. the operating voltage Is 12 volts, the first bypass switching can take place at a voltage of 12 to 13 volts. If the voltage applied to the flasher unit has increased to a much higher value, e.g. B. between 14 and 15 V increases, another shunt circuit takes place instead, so that an even larger proportion of the current that would otherwise go through the controlling Resistance (actuator) would flow, is guided parallel to this. On the actuator

(e.g. elastic band) there is again a lower voltage, e.g. of only 12V, that of the nominal voltage is equivalent to.

As can easily be seen, this arrangement also shows that the thermoelectric compensating element responds to the ambient temperature and its changes, so that the bypass circuit is controlled by changes in the operating voltage and the ambient temperature.
The invention is applicable to all types of thermoelectric flasher units which contain an actuator which expands through electrical heating and causes the contacts to open and close. In particular, however, the invention is applicable to thermoelectric flasher units which have a snap-on plate and a pulling element or a pulling strap. Such flasher are z. In U.S. Patent 2,756,304.

If the invention is used with these thermoelectric flasher units, those described are used Shunt elements to produce a shunt to the drawstring, which the under the influence represents heat expanding actuator of this flasher type. That in context The embodiment explained with the drawings is an application to the above-mentioned special thermoelectric flasher unit; however, it should be emphasized that the invention does not address these Flasher design is limited.

An exemplary embodiment of the subject matter of the invention is shown in the drawing. It shows

F i g. 1 a thermoelectric flasher unit according to the invention, without a housing,
Fig. 2 is a side view of the flasher,

F i g. 3 the flasher from one narrow side,

4 shows a view of the flasher from the right side,

F i g. 5 is a plan view of the snap plate and individual parts connected to it,

F i g. 6 and 7 the flasher unit in one of FIGS. 2 corresponding way, but in different positions the compensating contact element,

F i g. 2 to 4 as well as 6 and 7 are sections through the housing and

F i g. 8 is a circuit diagram to illustrate the principle of the invention.

The essential effective parts of the flasher are a snap plate 10, which is preferably made of electrically conductive material, e.g. B. metal, and to which a drawstring 20 is attached. This consists of a metal that is electrically conductive and expands when heated. The resistance of the drawstring is chosen so that the working current can raise its temperature considerably. The snap plate 10 has deformations or depressions 15 in the diagonal direction, which are mutually exclusive Distance and represent a bending line around which the snap-on plate in its "relaxed" Position is bent. At the ends of these diagonals, the corners 11 of the snap-on plate 10 are made their plane bent out. The ends of the drawstring 20 are fixed to these corners, e.g. Welding connected. This connection happens when the drawstring is cold and when the snap plate is bent around another bending line which runs at an angle to the depressions 15. If that Drawstring 20 is attached, the snap plate is in the other direction with the application of force deformed. The bending of the snap plate 10 in this position stores energy in it, so that the Snap plate has the tendency to snap back into the relaxed position as soon as the tension, which keeps them in the deformed position decreases.

As soon as the temperature of the tension band rises as a result of the passage of current, it expands, and after a certain expansion, the force stored in the snap-on plate 10 outweighs the force of the drawstring, and the plate 10 snaps back into its relaxed position in which it is around the indentations 15, 15 is bent. When the drawstring 20 cools and contracts, it moves the Plate 10 back into the deformed position in which it is bent around a straight line that is at an angle to the Depressions 15, 15 runs.

When the plate 10 is firmly clamped in a zone or point, the lateral distance from the bending line 15, 15, a movable part of the plate has a relatively large amplitude of movement, as soon as the plate performs alternating snap movements between the relaxed and the tensioned position.

The moving parts of the switch are arranged on an insulating plate 12, which is rectangular and has rounded corners. The circumferential flange 13 serves as a seat for the housing 14. On top of the Insulating plate 12 is the metal plate 30, which is connected to the insulating plate by rivets 16 and 17. By means of the rivet 16, the clamp 18 is also electrically conductive with the base plate 12 and with the plate 30 connected. A first arm 31 is up from one edge of panel 30 and then out bent.

The arm 31 is connected by riveting or welding to the plate 10 at one point, the one a certain distance from the depressions 15, 15 has. The point of attachment of the arm 31 to the plate 10 represents the fixed point about which this plate pivots during the snap movements. A second arm 32, serving for a purpose to be discussed later, extends from one end of FIG Plate 30 to the outside and is then upwards

ίο bow. A third arm 33 is from an outer one Edge of the plate 30 bent upwards and then inwards parallel to the plate.

A second clamp 21 extends from the base plate 12 and is connected to it by means of the part 22, the lower end of which is riveted to a bent part of the clamp 21. The top The end of the part 22 is widened at 23. This end has a certain distance from the surface of the Metal plate 30. The clamp 21 is out of contact with the plate 30 and is consequently of it electrically isolated. The upper surface of the widening 23 is close to the drawstring 20, which one centrally located contact 25 which cooperates with the fixed contact 35 on the head 23.

Contacts 25 and 35 touch when no voltage is applied to terminals 18 and 21. The flasher is, when it is used, in the usual way by means of a plug connection or a connected to a signal circuit in series with another connection. The connection of the flasher can e.g. B. in series with the switch of a direction indicator and the direction lights lie. If in such an application the switch of the direction indicator is in one or is closed in the other direction, the current flows from terminal 21, part 22, contacts 35 and 25 to drawstring 20. The stream branches into drawstring 20, so that each half to one end of the tension band and thus to the plate 10 flows. The current runs from the plate 10 to the support arm 31 and to the plate 30, which is conductively connected to the terminal 18.

The current flowing through the drawstring 20 heats it so that it expands. After a predetermined expansion of the tension band 20, the plate 10 snaps into its relaxed position, pivoting about its connection with arm 31. Those parts of the plate on which the drawstring 20 is attached, have a relatively large amplitude of movement, namely in Direction away from part 22 so that contacts 25 and 35 snap apart and the working circuit is opened. As soon as the passage of current through the tension band 20 ceases, it cools down and contracts. After a predetermined contraction, the drawstring causes the Snap movement of the plate from its relaxed position into the deformed position, so that by the Snap movement the contacts 25 and 35 are closed again. This creates the working circuit restored by the flasher via the contacts 25 and 35, so that the tension band 20 is again heated as a result of the passage of current. This periodic process takes place as long as as voltage at terminals 18 and 21.

The flasher unit and its mode of operation are known as far as the snap-on plate is concerned.

The switching frequency of the flasher changes with it the voltage applied to terminals 18 and 21 (e.g. 0.4 V) and changes in the ambient temperature. If z. B. the voltage at terminals 18 and 21 drops, the heating takes and the extension of the drawstring 20 sufficient to cause the plate 10 to snap into place To allow opening of contacts 25 and 35 longer. This time is shortened when the voltage is applied to the Terminals 18 and 21 becomes larger. This also increases the time in which through the flasher the circuit is switched on, become longer and shortened in the other case. If the The ambient temperature is relatively high, the cooling of the drawstring 20 takes longer, and the heating time is shortened. This is another cause of a change in the switching frequency of the flasher and for a change in the ratio of the time in which the circuit is switched on and in which it is switched off. But if the ambient temperature is relatively low is, the cooling time decreases and the heating time increases. As in the following will be described in more detail, the flasher device according to the invention has a device for automatic Shunting the current flowing through the drawstring 20; the resistance of this Shunt is changed depending on the applied operating voltage. To this Way, the switching frequency and the ratio of the time in which the flasher is switched on to Switching period kept essentially constant regardless of changes in voltage and the ambient temperature.

A thermoelectric switch 40, which is preferably is designed as a bimetal strip, has a relatively narrow inner portion 41, the is attached at its end to the arm 32 that extends upwards. The outer free portion 42 of the Arm 40 is slightly longer than the narrow inner section and has a channel cross-section or the like Design with which an increased rigidity of the outer section 42 is obtained. Of the Arm 40 extends approximately all the way over plate 10 so that its outer end is near the outer edge of the plate 10 is. A heating coil 45 is as close as possible around the bimetal arm 40 arranged at its end attached to the arm 32, so that one as large a bend as possible of the outer end of the arm 40 is achieved at a given heating power. One end of the Heating winding 45 is made on the electrically conductive and preferably flexible strip 26 Attached to metal, the opposite end of which is in electrical and mechanical contact with the Part 22 is. The other end of the heating coil 45 is electrically and mechanically connected to the bimetal arm 40 connected, which is also electrically conductive. The heating coil 45 is therefore in the shunt to the Working current contacts 25 and 35, as can be seen from FIG. The extreme end of the arm 40 is turned around at 43 for a purpose yet to be described.

As best seen in 2, 4 and 5 can be seen, a strip 50 is provided, which consists of a material of relatively high resistance, e.g. »Chrome nickel«. One end of this strip is attached to the drawstring 20 near the contact 25 welded, preferably on the side of the drawstring facing away from the contact. The strip 50 runs outwards below the snap-on plate 10, but without contact with this, is then upwards bent and twisted (see. At 51) and then runs inwardly bent over the plate 10 at a distance of this (see at 52). This strip is flexible and elastic. The free end 52 of the strip 50 is encompassed by the contact strips 55. The end 52 and the contact strip 55 are approximately perpendicularly under the bent end 43 of the bimetallic strip 40, that is to say in its = B & wegungsweg. Furthermore, the snap plate 10 has a contact 60 which is perpendicular to the end 52 and the contact strip 55 is welded and also in the path of movement of the bendable end 43 of the bimetal strip 40 lies.

The function of the flasher device according to the invention is best with reference to FIG. 2, 6, 7 and 8 to explain. In the schematic circuit diagram F i g. 8, the power source B is grounded with one terminal and connected to the flasher unit with the other terminal. This battery is z. B. a common for motor vehicles 12 V battery to which a power generator belongs. The contact 35 is connected to one terminal of the lamp SL via the switch SW , while the other terminal is grounded. For a better understanding of the underlying electrical theory, the bimetal strip 40 is shown so that it includes the resistor 40 ^ 4, and in a corresponding manner the strip 50 with the resistor 50 ^ 4. The two halves of the tension band 20 are also illustrated with the resistors 20.4 and 205.

At or below the nominal operating voltage of about 12 V, the parts of the flasher unit, the position shown in Figs. 2 and 8 take as soon as the switch SW is closed, a current flows through the flasher unit, and this leads snap movements between the open and the closed position in the manner described above, so that the contacts 25 and 35 periodically separate and close again. When the operating voltage increases above the nominal value, the bimetallic strip 40, which is normally in contact with the arm 33 and in this way is kept a predetermined distance from the contact 55, begins to bend as a result of the heating by the heating coil 45. This heating coil is practically due to the full operating voltage when the operating current contacts 25 and 35 are separated. Between 12 and 13 V, the bend in the bimetal strip 40 is so great that its end 43 reaches the contact 55, which sits on the resistance strip 50 (see. Fig. 6). This closes a circuit in which the resistors 40A and 50 ^ 4 are connected in series, in parallel with the parallel resistors 20.4 and 202? of the drawstring 20. There is thus a shunt path for the current which normally flows through the two skins of the drawstring, and the fact that a lower current is now flowing there causes a reduction in the switching frequency compared to that which leads to the 13V -The operating voltage should be at a value that almost corresponds to the 12 V operating voltage.

Should the operating voltage rise further, the bimetal strip 40 will also bend further and

touches the contact 55 with greater pressure, the resistor 50 in relation to the plate 10 after is pressed down. The increased contact pressure has increased current flow through the shunt as a result, which further delays the heating of the tension band and the switching frequency and the Ratio of the time in which the flasher unit is switched on to the time in which a switching period expires, is reduced. At a voltage between 14 and 15 V, which is selected here as an example, be ίο the contact 55 stirs the contact 60 on the snap-on plate 10 (cf. FIG. 7). Now is the resistance 40 ^ t shorted out, and it's just that Resistance 50 ^ 4 in the shunt to the parallel ones Resistors 20 ^ 4 and 2OB of the drawstring 20. As the voltage continues to increase, the contact pressure increases with those described above Follow. In addition, the direct pressure on the snap plate acts mechanically via contact 60, such that the switching frequency of the flasher is reduced. As a result, a a larger part of the current is passed through the shunt, and a corresponding reduction occurs of the currents flowing through the two halves of the drawstring 20. This will increase the amperage held in the drawstring to a value that corresponds approximately to the current strength in the drawstring that is obtained when operating with the nominal voltage, so z. B. 12 V. The switching frequency becomes so practical held constant over the range of 12 to 15 V, regardless of the fact that the operating voltage is increased.

It can be seen that the arrangement or circuit described also changes in the ambient temperature compensates. When the ambient temperature increases, the bimetal strip becomes 40 bent toward contact 50, so that the voltage increase that would be required is around the strip 40 to bring the contact 55 into contact is reduced. The opposite effect occurs a decrease in the ambient temperature.

In practice it has been shown that the flasher according to the invention at relatively strong Fluctuations in the operating voltage and significant changes in the ambient temperature the switching frequency and the ratio of the time the flasher is switched on to the time a period can be kept within relatively narrow limits.

The subject matter of the invention can also be implemented differently from the above exemplary embodiment will.

Claims (5)

Patent claims: 1. Thermoelectric switch, in particular flasher unit, with a resistor controlling a switching element as a function of current, e.g. B. an elastic band, the load contacts of which also switch the heating current for the controlling resistor on and off, as well as with a voltage-dependent controlling resistor, which can compensate for fluctuations in the voltage drop in the switch within certain limits via an additional thermal element, characterized by an additional element (40), one end of which is fixedly attached and conductively connected to the input of the controlling resistor (20 Λ, 20, 20 B) and the other end (43) is thermally bendable, and by an approximately strip-shaped, elastic compensation resistor (50, 50 ^ 4) , one end of which is conductively connected to the output of the controlling resistor (20) and has a free end (52) with a contact (55) in the path of movement of the free end (43) of the additional member (40), and by one influencing the additional member Heating winding (45) as a voltage-dependent controlling resistor, which is connected in parallel to the controlling resistor (20) when the load contacts (25, 35) are closed t is and is always exposed to the voltage drop in the switch, so that when a first predetermined voltage value is exceeded, the free end (43) of the additional element (43) establishes contact at (52) the compensation resistor (50, 50 ^ 4) and the additional element resistance ( 40, 40 ^ 4) turns on in the shunt to the controlling resistor (20, 2OA, 205). 2. Thermoelectric switch according to claim 1, characterized in that the additional member (40) upon a further increase in voltage to a second predetermined value the free end (52) of the compensating resistor (50, 50.4) bends so far that there is a mating contact (60) touches the switching element (10) and thereby the additional element resistance (40, 40 ^ 4) short-circuits, i.e. only the balancing resistor (50, 50 ^ 4) in the shunt to the controlling one Resistance turns on. 3. Thermoelectric switch according to claim 1 and 2, characterized in that the high-resistance heating winding (45) of the additional element in a manner known per se around the additional element (40) is wound and conductively connected to it at its input. 4. Thermoelectric switch according to claim 1 and 2, characterized in that the Switching element in a manner known per se from a snap plate (10) and a tension band (20) as there is a controlling resistor connected to the snap-on plate (10) at both ends is and this, when it is cold, forces it into a deformed position so that the snap-on plate snaps into its original position at a predetermined expansion of the drawstring, so that the load contacts (25, 35) open in one position of the snap-on plate and in the other Location are closed. , 5. Thermoelectric switch according to claim 1 to 4, characterized in that the Equalizing resistor (50 ^ 4) consists of an elastic strip (50), which from the movable Contact (25) of the tension band (20) goes out, protrudes over the edge of the plate and with an approximately U-shaped end (51, 52) which can be moved by the additional member (40), the plate (10) comprises, its contact (55) with the mating contact (60) at a corner of the plate in operative connection can kick. 6. Thermoelectric switch according to claim 1 to 5, characterized in that a Stop (33) to limit the leading away from the free end of the compensation resistor (50) Movement of the additional member (40) is provided. 7. Theromelectric switch according to claim 1 to 6, characterized in that the "' ^{: Λ} 609 578/409 Additional member (40) is designed as a bimetal strip with stiffeners at its free end (42) and a bent pressure surface (43) is provided. 8. Thermoelectric switch according to claim 2, characterized in that by the Enlargement of the contact pressure between the free end of the additional member (40) and the Equalization resistor (50) the current strength in the first shunt is increased and that by xo the increase in the contact pressure between the free contact end (55) of the equalizing resistor and the mating contact (60) of the switching element in the event of a further increase in voltage the amperage in the second shunt is increased. Considered publications:
German Patent No. 888 818;
German Auslegeschrift No. 1150 001;
U.S. Patent Nos. 2756304, 2978 665. 1 sheet of drawings 609 578/409 5.66 © Bundesdruckerei Berlin