DE973889C - Contact converter - Google Patents

Description

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Contact converters with lifting contacts that are actuated by eccentrics are known. The eccentric shaft is driven by a synchronous motor in these contact converters, so that the opening and Closing of the contacts takes place in a certain rhythm. To make contact practically at zero current to open, so-called opening choke coils are provided, which have an iron core, the one has almost rectangular magnetization characteristic, and the dimensioning is made so that the core is saturated even at low currents. The iron core of the reactor becomes during the commutation time magnetized, and the choke coil creates a low-current stage within which the contact is opened. It is desirable that the step current still slightly with a positive load current is positive, and various circuits are known for this purpose. The commutation time depends on the degree of modulation of the contact converter and the level of the output from the contact converter Current. In order to achieve that at different levels and also at different current loads the contact is opened in the low-current break (stage) is a proportionate great effort is required for the choke coil. To reduce this, it is known to adjust the opening time of the contacts or, in other words, adapt the overlap time of the contacts to the modulation or the level of the load current. One achieves that the switching inductor

009 552/12

can be chosen relatively small and still the opening time always falls within the level.

To set or automatically regulate the overlap time, devices have been implemented so far, which in principle act as if the length of the plunger acting on the moving contact, will be changed. For this purpose, for example, the eccentric has a cylindrical shape given a different shape and to set the ίο overlap time the eccentric shaft perpendicular to the Movement direction of the ram shifted. Another known design has one Rocker arm that actuates the plunger, raised or lowered in its storage. All of these facilities has, as already mentioned, in common that they act as if the plunger length is shortened or lengthened. As a result, if the overlap time is influenced, i. H. the switch-off time of the Contact, and the switch-on time is also changed at the same time. It therefore occur in the control or regulation of the overlap time difficulties, since z. B. for mechanical partial control Reducing the voltage postponed the closing time of the contacts by a certain amount is, but the overlap control also has an additional influence on the switch-on time. In addition, the overlap control causes a change in the current-voltage characteristic of the contact converter, in such a way that the characteristic curve is flatter in a regulated converter than with an unregulated one.

The invention relates to a contact converter in which these difficulties are avoided. According to the invention, there are two contacts per switching point (Switch-on and switch-off contact) is provided, and it is used to control or regulate the overlap time only the switch-on and switch-off time of one of these contacts (switch-off contacts) relative to The switch-on and switch-off times of the other contact (switch-on contact) are influenced. This will result in Change of the overlap time of the switch-on time for the switching point, i.e. the moment in which this switching point is energized, not changed. One can adjust or regulate the overlap time according to the invention both when a mechanical partial level control, d. H. a change in voltage takes place by shifting the switch-on time of the switching point, as even with partial modulation by influencing the magnetization state of the switching inductor in the Power-on instant. It can also be used when there is no partial modulation and only the Load current changes. You can connect the two contacts in series or in parallel. The one of the two contacts has the task of a switch-on contact. Its contact time is kept constant and its switch-on time is fixed or changed to change the voltage or current. Of the the other contact serves as a switch-off contact. To control or regulate the contact time of the Switching point, the relative position of the eccentric for the switch-on and switch-off contact can be kept constant and change the contact time of the switch-off contact.

Another possibility is to keep the contact time of the switch-off contact constant and to change the position of the eccentric of the switch-off contact in relation to the eccentric of the switch-on contact. However, it is also possible to determine both the contact duration of the switch-off contact and the position of the eccentric to change for this contact compared to the eccentric of the switch-on contact.

Various exemplary embodiments of the invention are shown in the drawing.

In Fig. Ι the three phase voltages u, v, w of a three-phase network are shown.

Fig. 2 shows the relationships for the series connection of two contacts per contact point. In Fig. 2 and in the following figures, which show the contact duration of the on and off switch, the upper line indicates the time in which the switch contact is closed, while the two lines below indicate the time in which the switch off contact closed is. In Fig. 2, the contact time of the switch-on contact is i8o ^c . The phase shift of the eccentric of the switch-off contact compared to the eccentric of the switch-on contact is -30 °, whereby the minus sign means that the eccentric of the switch-off contact is advanced, i.e. with the same contact time the switch-off contact ^{closes or opens 30 0} earlier than the switch-on contact. The overlap time can be set by influencing the contact duration of the switch-off contact. If the switch-on time of the switch-off contact is 120 ⁰ , the overlap time is 0 °. If the switch-on time of the switch-off ^{contact 240 is 0} , the gs overlap time is 60 °. So you can set the overlap time between 0 and 60 °.

If you want to use the setting of the overlap time also for the purpose of starting the contact converter, you have to set the closing times of two switching points so that they do not overlap, i.e. no flashback is possible. You can then connect the full AC voltage to the device without a special starting device. For this purpose, in the arrangement according to the invention, it is necessary to provide the possibility of regulating the overlap below 0 ° for a short time. For this purpose, for example, the phase shift between the eccentrics of the switch-on and switch-off contact could be somewhat larger, e.g. B. to -35 ⁰ , select the largest contact time of the switch-off contact would then be 250 ⁰ and the smallest iio °, so that the overlap time would be set from -10 to + 60 °.

In Fig. 3, the conditions in the parallel connection of two contacts are shown for a specific case. The contact time of the switch-on contact is 120 ⁰ , the phase shift + 30 °, the contact time of the switch-off contact is regulated between 60 and 180 °, so that the overlap time can be set from 0 to 60 °. Here you could, if it is necessary for starting, the phase shift angle of the two eccentrics a little smaller, z. B. to + 25 °, and select the contact time of the switch-on contact to iio °. If the longest switch-on time of the switch-off contact is then 170 ⁰ , the smallest 50 ⁰ , then it can

the overlap time is set between -io and + 50 ° will.

This regulation of the overlap time is sufficient for contact converters in a three-throttle circuit. A larger change in the overlap time is required for contact converters in a six-throttle circuit. It is generally sufficient to change the overlap time by 10 °.

In order to achieve an overlap time greater than 60 °, the contact times can, for example, be selected as shown in FIG. 4 for the series connection of two contacts. The switch-on contact has a duty cycle of 240 ⁰ . The contact duration of the switch-off contact can be changed from 120 to 360 ⁰ . The phase shift of the two eccentrics is - 60 °. As you can see, the overlap time can be set from 0 to 120 °. If you want to start a change from - 10 °, as is necessary for starting, for example, you could select the phase shift to -65 ⁰ and change the switch-on duration of the switch-off contact between 110 and 350 ⁰ , so that an overlap time of - 10 to -f-iio ° results.

Fig. 5 shows the relationships in the parallel connection. The switch-on duration of the switch-on contact is 120 ⁰ . The contact time of the switch-off contact can be changed from ο to 240 ⁰ , and the phase shift of the eccentrics of the switch-on and switch-off contact is + 60 °. The overlap time can thus be set between 0 and 120 ⁰ . If you want to change the overlap time between -10 and +110 ⁰ , you can, for example, set the contact time of the switch-on contact to 110 °, the phase shift to + 55 ° and change the switch-on time of the switch-off contact between 0 and 220 °.

In the previous embodiment it is assumed that the relative position of the eccentrics of the and switch-off contact remains constant and that the duration of the contact time of the switch-off contact changes will. This can happen because the eccentric of the switch-off contact is not cylindrical, but is designed conical or in another shape and that the shaft for the eccentric is shifted perpendicular to the direction of movement of the ram. This will be the switch-on time and the switch-off time of the switch-off contact and thus the switch-on duration of the switch-off contact changed.

In all these and the following exemplary embodiments, it should also be noted that the converter operation gives rise to certain conditions with regard to the switching speed for opening and closing the contact and that the spring stroke is limited in a certain structural design of the device. It will therefore not always be possible to utilize the full range for the overlap control. The exemplary embodiments represent the theoretical borderline cases. For example, a contact time of 0 and 360 ⁰ cannot be used.

But it can be seen from the exemplary embodiments that by suitable choice of the contact duration for the switch-on and switch-off contact and, by suitable choice, the phase shift between the two Eccentric can adapt to a wide variety of conditions. It should be mentioned that FIG to 5 only represent exemplary embodiments, namely borderline cases, and that one also depends on the given Ratios other contact times and phase shift angle can choose.

As already mentioned, there is another possibility to change the contact duration of the switch-off contact to leave constant, but the phase position of the eccentric of the switch-off contact compared to the To change the eccentric of the switch-on contact.

The relationships that occur are shown for the parallel connection of the contacts in FIGS. 6 and 7 for two cases. In FIG. 6, the switch-on duration of the switch-on contact is i8o °, and the switch-on duration of the switch-off contact is likewise i8o °. The relative phase position of the eccentric of the Ausschaltkontaktes opposite the permanent make is changed from 0 to i8o °, so that a change in the overlapping period of 60 to 240 results in ^{the 0th} In the arrangement according to FIG. 6, the closing time of the switch-on contact is just as long as the opening time, and the same applies to the switch-off contact. Here, as a simple consideration shows, conditions that are particularly favorable for switching speed and spring stroke are achieved.

In the arrangement of Fig. 7 is a contact time is accepted by 120 ° and the eccentricity of Ausschaltkontaktes opposite the permanent make can be changed from ⁰ to 120 ο in its position. It can be seen from this that the overlap time can be regulated from 0 to 120 °. To z. B. to regulate the overlap time from -10 to + 100 °, one could make the contact duration of both contacts iio ^c and the maximum phase shift of the eccentrics also no ⁰ .

For the series connection, two exemplary embodiments are also shown in FIGS. 8 and 9, and 8 shows an arrangement in which the opening and closing times of the switch-on contact and also those of the switch-off contact are of the same size. The duty cycle for each of the contacts is therefore 180 °. If you turn the eccentric of the switch-off contact in relation to that of the switch-on contact from -180 to 0 °, the overlap time changes from -120 to + 60 °.

Such an arrangement, the favorable conditions for the switching speed of the contacts and gives the spring stroke, is therefore z. B. suitable for a contact converter in three-throttle circuit, in which the overlap duration should be regulated from -10 to + 60 °.

In FIG. Q the contact time is not 180, but 240 ⁰ , and the phase position of the eccentric of the switch-off contact is shifted from −120 to 0 ° with respect to the eccentric of the switch-on contact. The overlap time can therefore be regulated ^{from 0 to 120 0.} If you choose the ratios a little different, for example. B. the contact times of both contacts 220 °, and the phase position of the eccentric of the switch-off contact is shifted from ο to 110 °

compared to the eccentric of the switch-on contact, you get a regulation of the overlap time from -io to 100 °. This arrangement or the after 9 can therefore be used, for example, for the overlap control in the case of contact converters in a six-throttle circuit be applied.

It can be seen from the figures that by changing the contact time and the phase shift angle the eccentric can adapt to the most varied of conditions.

Another possibility is to have the contact duration of the switch-on and switch-off contact different to make great.

The following figures show how the invention can be carried out in detail.

In Fig. Io and ii an arrangement is shown, in which the relative position of the two eccentrics is constant and the switch-on duration of the switch-off contact is changed, so an embodiment so for the arrangements according to FIGS. 2 to 5. With 1 is the switch-on contact, denoted by 2, the switch-off contact, which are connected in parallel in the exemplary embodiment are. But you could also connect them in series. Each of these contacts is through a Plunger 3 or 4 actuated, which is driven by eccentric 5 or 6. The two eccentrics 5 and 6 sit firmly on the eccentric shaft 7. The eccentric 5 is cylindrical, while the other Eccentric 6 has a shape deviating from the cylindrical shape. The coupling of the shaft 7 with the Synchronous motor 8 takes place via a coupling sleeve 9, which is firmly connected to the shaft of the motor 8, and a pin 10 of the eccentric shaft 7, which engages in grooves of the coupling sleeve. On and off contact are only shown schematically in the exemplary embodiment. By raising and lowering the eccentric shaft the contact time of the switch-off contact can be changed. For setting the overlap time is accordingly raised and lowered the eccentric shaft, for example by an eccentric 12, the is set manually or by an overlap regulator.

As already mentioned, the eccentric shaft is driven by a synchronous motor 8 The stand opposite can adjust or regulate voltage or current or power the frame, not shown, which contains the bearing for the eccentric shaft and the plunger, rotated will. But it is not necessary that the stand is rotated; you can also use the stand store firmly and feed the drive motor via a rotary transformer. As already mentioned, the contacts are connected in parallel in the exemplary embodiment. The AC busbars are denoted by 13 and the direct current busbars by 14. In the exemplary embodiment there are three Eccentric pairs provided on the eccentric shaft 7, and each eccentric actuates two contacts that are arranged opposite one another. Do you want the contact time of the switch-off contact leave constant and the position of the eccentric of the switch-off contact in relation to the eccentric of the switch-on contact change, as it is assumed in FIGS. 6 to 9, so you can an arrangement as shown schematically in FIG. Here are the two eccentrics 15 and 16, from one of which acts on the switch-on contact, the other on the switch-off contact, loosely on the eccentric shaft 7 arranged. The eccentrics are cylindrical. The eccentric shaft 7 has for each eccentric a driver pin 17 or 18. The eccentric 15 for the switch-on contact has a straight groove 19, which runs in the direction of the axis of the eccentric shaft, the eccentric 16 for the switch-off contact a groove 20 which deviates from the straight line and z. B. forms a helix. Will to set the overlap time manually or automatically, the eccentric shaft opposite the direction of movement of the plunger moved, so in the embodiment raised or lowered, so twisted the eccentric 16 is relative to the eccentric 15.

You can also change the phase position of the two eccentrics for the switch-on and switch-off contact for each switching point adjust by providing two eccentric shafts. This is shown in FIGS. 13, 14, 15 and 16. In this arrangement, two eccentric shafts 21 and 22 are provided for a contact converter. The eccentric 23 of the shaft 21 acts on the switch-on contact 1, the eccentric 24 of the eccentric shaft 22 to the switch-off contact 2. The two contacts are in series in the exemplary embodiment connected, as can be seen from Fig. 15, in which the alternating current rail with 25 and the direct current rail is denoted by 26. FIG. 13 shows the front view, FIG. 16 shows the top view, and FIGS. 14 and 15 represent the side view, once only the waves with the eccentrics, the other time only the busbars with the contacts are shown.

The eccentric shaft 21 is driven by a synchronous motor 27, the other, 22, by a synchronous motor 28 driven, the stands are rotatably mounted. The overlap time is set by that the stator of the motor 28 is rotated by hand or by an overlap regulator. The setting the voltage or the current or the power can take place in that the Stator of the motor 27 is rotated, or a rotary transformer is also provided, which is preferably feeds both motors, which reduces the working range of the overlap control device will.

The angle of rotation of the motor 28 must be equal to the sum of that without a rotary transformer feed be the control angle used for the partial control and the angle by which the overlap time will be changed. With rotary transformer supply, the angle of rotation can be related to the control angle, necessary for setting the overlap time.

In the exemplary embodiment, 29 and 30 are the drive points of the voltage regulator or the overlap regulator on the housing of the motor 27 and 28 respectively.

Another possibility is that, as shown 'n Fig. 17, the eccentric shaft 21 for the

Switch-on contact directly from the motor, the eccentric shaft 22 for the switch-off contact via a Differential gear (differential gear) 31 is driven by the same engine. To set the Overlap time, the differential is adjusted so that the relative phase position of the two Eccentric shaft is changed.

The setting of the overlap time can be done manually when the voltage of the contact converter or the current is set by hand by partial control. One can also use the overlap time regulate automatically with contact converters, their control manually or automatically is set. The overlap controller can, for example, as is known per se, from the time integral the voltage across the inductor that generates the stage.

In the arrangements in which two eccentric shafts are used, one of which is the Switch-on and the other controls the switch-off contact, you can set up the contact converter make in a simple manner that the contact device consists of two identical basic elements a unit is assembled, each basic element from an eccentric shaft, at least a contact, a plunger and a frame, which is the bearing for the eccentric shaft, contains the plunger and the contact.

Such a basic element is shown schematically in FIGS. It consists of one Eccentric shaft 40, the eccentrics 41, the movable contacts 42, the plungers 43 and a frame 44, in which the eccentric shaft and the plunger are mounted and which also has the fixed mating contacts carries, which in the exemplary embodiment through the AC busbars 45 and the DC busbar 46 are formed. In the exemplary embodiment, a coupling flange 47 is connected to the frame 44, which forms a unit with the frame 44. But you could also z. B. the coupling flange on the Fasten the frame with screws or the like. The eccentric shaft 40 protrudes in the exemplary embodiment their storage addition and carries a coupling part 48 on which the drive motor or a further eccentric shaft can be coupled. In Fig. 20 is a plan view of such a base element shown.

Fig. 21 shows schematically that with the coupling part 48 a synchronous motor 50 via a Coupling part 49 can be coupled, and the arrangement can be made so that the stand of the Motor, which is attached to the coupling flange 47, opposite this and thus opposite the frame is rotatable.

For example, one can combine two such basic elements into one unit in such a way that that the axes of the eccentric shafts are parallel. An exemplary embodiment for this is shown in FIG. 22 and 23. The two basic elements are labeled 60 and 60 '. So much for the parts with those of the previous ones Figure match, the same reference numerals are chosen; only the parts of the second Units are marked with a line. The coupling flanges 47 and 47 'are, as shown schematically, connected by screws. The contacts 42 of the base elements 60 and the contacts 42 ' the basic elements 60 'are connected in series so that each switching point has one contact of the basic element 60 the function of the switch-on contact and a contact of the base element 60 'the function of the switch-off contact, as described earlier, takes over. The AC power rails are 45 or 45 'and the DC bus is denoted by 46'. With every basic element is a synchronous motor 50 or 50 'connected, the stand is rotatably mounted with respect to the associated frame. By rotating the stator of the synchronous motor 50, the voltage, the current or the power controlled or regulated by partial control. By rotating the stator of the synchronous motor 50 ' the overlap time is controlled or regulated. In the exemplary embodiment, switch-on contact 42 and Switch-off contact 42 'connected in series. The contacts can also be used in parallel for each switching point switch. You can z. B. a three-phase bridge circuit with three inductors or a three-phase Use a bridge circuit with six inductors as a basis.

As mentioned earlier, you could also regulate the voltage by using a rotary transformer undertake, which feeds the motor 50 and possibly also the motor 50 '.

The construction of the contact converter from basic elements is not only applicable if it the overlap control is concerned, in which the contacts of one basic element act as switch-on contacts, those of the other serve as switch-off contacts for each switching point, but wherever it is are contact converters with lifting contacts and eccentric shafts. For example, you can as shown in FIGS. 24, 25 and 26, connect two basic elements 60 and 60 'to one another so that their axes fall in the same direction. It is then connected to the coupling 48 'of the basic element 60' the coupling 48 of the base element 60 connected so that the two axes of the eccentric shafts coincide. With the coupling 48 at the other end of the base element, the rotor of the synchronous motor becomes 50, whose stand is rotatably connected to the coupling flange 47, for example. the facing coupling flanges 47 and 47 'are connected to one another by unspecified screws tied together.

If, as assumed in the exemplary embodiment, there are six contacts for each basic element, then so one can get the contacts of each basic element in three-phase bridge circuit with three or six Operate chokes. You can connect the two bridge circuits in series or in parallel. In the exemplary embodiment, they are connected in series so that only a single direct current rail 46 and there are three pairs of alternating current rails 45 and 45 'for each basic element.

The phase position of the eccentrics of the two basic elements can be 0 or 180 °. But you can also offset the eccentric shafts by ± 30 ° and through

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Claims (18)

Parallel or series connection of the two bridge circuits each formed by a contact converter element achieve a circuit with twelve-phase ripple. When connected in series, the voltage is if the two basic elements are connected in parallel, the current is doubled. You can also use other phase shifts Adjust the eccentric of the two basic elements to become different electrical To be able to adapt conditions, ίο You can also use an arrangement as shown in Fig. 24 is shown, combine with an arrangement according to FIG. 22. You then have two each Basic elements with equiaxed eccentric shafts, the eccentric shafts each having two such units lie parallel. The contacts of the two basic elements, the axes of which are parallel, are used as switch-on and switch-off contact for one switching point each. The systems so formed for one Contact converters can be operated in a three-phase bridge circuit with three or six reactors and be connected in series or in parallel with the corresponding other system, with through Adjustment of the phase position of the coaxial eccentric shafts compared to the other coaxial eccentric shafts Eccentric shafts the overlap control can be carried out. You can choose the phase position of the equiaxed eccentric shafts to be o, 180 or ± 30 ° or choose other angles. With in-phase eccentric shafts, a six-phase bridge circuit can also be used and regulate the overlap time at the same time. So far it is only the union of two basic elements with parallel eccentric shafts or has been described with eccentric shafts lying in the same axis or the connection of one of two coaxial basic elements existing unit with a corresponding unit, the eccentric shafts these two units are parallel. It follows without further ado that one contact converter any design can also be composed of basic elements in other ways, for example one could arrange three or more basic elements on the same axis, or one can arrange 2 M basic elements assemble in any way so that some are equiaxed, and the units so formed assemble with corresponding other units so that the axes of their eccentric shafts lie parallel. You can set the size of the current and the voltage as desired and also, as soon as one uses basic elements with parallel axes, the overlap control, as before described, perform. In the previous exemplary embodiments, the basic element consisted of one eccentric shaft, three Contact pairs, six plungers and a frame. But you can also have more or fewer contact pairs provide for a basic element. _c PATENT CLAIMS: i. Contact converters with lifting contacts, which are driven by eccentrics and in which the overlap time is set or automatically regulated, characterized in that two contacts (switch-on and switch-off contact) are provided for each switching point and only the switch-on and switch-off time of one of these are provided for setting the overlap time Contacts (switch-off contact) is influenced relative to the switch-on and switch-off time of the other (switch-on contact). 2. Contact converter according to claim 1, characterized in that the two contacts are in series are switched. 3. Contact converter according to claim 1, characterized in that the contacts are connected in parallel are. 4. Contact converter according to claim 1, characterized in that the relative position of the eccentric for the switch-on and switch-off contact is constant and the contact time of the switch-off contact will be changed. 5. Contact converter according to claim 1, characterized in that the contact time of the switch-off contact is constant and the position of the eccentric of the switch-off contact is changed compared to that of the eccentric of the switch-on contact will. 6. Contact converter according to claim 4 and 5, characterized in that both the contact duration as well as the position of the eccentric of the switch-off contact in relation to the eccentric of the Switch-on contact is changed. 7. Contact converter according to claim 5, characterized in that the contact duration of the switch-on contact as long as its opening time and that also the contact duration of the switch-off contact as long as its opening hours. 8. Contact converter according to claim 4, characterized in that the eccentric shaft is perpendicular is shifted to the direction of movement of the plunger and that the eccentric for the switch-on contact cylindrical, designed differently from the cylindrical shape for the switch-off contact. 9. Contact converter according to claim 5, characterized in that the two eccentrics for the The switch-on and switch-off contacts sit loosely on the shaft and that the switch-on contact has a parallel to the shaft axis, the switch-off contact has an inclined groove and that in each Groove a pin engages the eccentric shaft, which is perpendicular for the purpose of setting the overlap time to the direction of movement of the ram is changed in their position. 10. Contact converter, in particular according to claim i, characterized in that it consists of two or more identical basic elements are assembled to form a unit, each Basic element consisting of an eccentric shaft, at least one contact and plunger and a frame consists, which contains the storage for the eccentric, the plunger and the contact. 11. Contact converter according to claim 11, characterized characterized in that two or more basic elements in the direction of the axis of the eccentric shaft are assembled into a unit. 12. Contact converter according to claim io, characterized characterized in that two or more basic elements are assembled side by side are that the axes of the eccentric shafts are parallel. 13. Contact converter according to claim 10, characterized characterized in that two or more basic elements in the direction of the eccentric shaft and are assembled side by side with parallel axes. 14. Contact converter according to claim 10, characterized characterized in that a coupling flange is connected to the frame. 15. Contact converter according to claim 10, characterized characterized in that the eccentric shaft protrudes beyond its storage in the frame. 16. Contact converter according to claim 10, characterized characterized in that the basic element consists of an eccentric shaft, three pairs of contacts, the associated plungers and a frame. 17. Contact converter according to claim 12, characterized characterized in that each eccentric shaft is driven by a synchronous motor and the stand of one of the two is rotated to regulate the overlap time. 18. Contact converter, in particular according to claim 12, characterized in that the one The shaft is driven directly by a synchronous motor, the other via a differential gear, attacked to set the overlap time. For this purpose 2 sheets of drawings © 009 552/12 7.