NO118231B - - Google Patents

Description

Electrical switching device for a growth circuit.

The present invention relates to a

electrical switch device for an alternating current circuit where a switch's contacts are shunted with a one-way rectifier which, when the switch contacts are open, conveys current between the contacts in one, e.g. positive, half period of the current and where said switch is connected in series with a further switch which is not shunted with a rectifier.

From German patent no. 638 981, a switch device is known where, to suppress the generation of sparks, at least two one-way rectifiers are used which shunt respective contacts, the rectifiers being arranged with mutually opposite directions of passage, i.e. opposite polarity, and the switches are connected to each other in such a way that they are opened and closed simultaneously and therefore two rectifiers are always necessary to suppress sparking.

The purpose of the invention is to provide a switching device of the type mentioned at the outset, where only a single rectifier is required.

This is achieved according to the invention by

that the device is arranged in such a way that the first shunted switch is opened before the second, non-shunted switch, so that the rectifier prevents, possibly suppresses spark formation in the first switch during e.g. the positive half-period because the rectifier forms little resistance in the shunt path and will prevent, possibly suppress, spark formation in the other switch in the event of a subsequent, e.g. negative half period, when the rectifier is non-conducting.

The invention shall be explained in more detail

with reference to the drawing.

Fig. 1 schematically shows a switch device according to the invention. Fig. 2 shows an alternating current curve which will be used to explain the operation of the switch device. Fig. 3 schematically shows an embodiment of the invention which includes synchronization of the contact operation. Fig. 4 shows a cross-section through one

other embodiment of the invention.

In fig. 1, two wires 1 and 2 are connected by means of a switch device comprising two switches with movable contacts 3 and 5 interacting with respective fixed contacts 4 and 6. A one-way rectifier 7 is connected as a shunt across contacts 3 and 4.

When operating the switch device according to the invention, the rectifier will short-circuit the first switch for a half period when the switch is open and the current in it will either already be zero or will become zero during the next half period in the direction in which the rectifier allows current to flow. The switch will therefore first break the circuit between the contacts during the half period that the rectifier does not pass through. The current flowing through the rectifier and the second switch will become zero due to the rectifier in the next half period that the rectifier does not pass through, so that the second switch is able to break the current circuit completely. You will see that if the first switch is opened during a half period that the rectifier does not pass through, current will only flow for half a period before the rectifier will again prevent the current from flowing. In the same way, when the other switch is opened for a half period when the rectifier lets current through, the current will only carry current during this half period. If the first mentioned switch is opened when the rectifier is conducting, this switch will not perform any current breaking, and likewise if the second switch is opened when the rectifier is not conducting current, the second switch will not perform any current breaking either. At any time during the current period in which the two switches are operated, the rectifier will therefore serve to reduce the breaking capacity required by the contacts, as the energy present in an arc formed in either switch is limited to a maximum which corresponds to the current for half a period if one of the switches is opened at times when these are carrying current.

It appears that the rectifier will normally carry zero or negligible current and be exposed to zero or negligible voltage when the switches are closed.

For carrying out the invention, the rectifier may be of any suitable type, but preferably comprise germanium or silicon rectifier elements. Rectifiers that include semiconducting elements of silicon have the advantage that they can work at higher temperatures and at a higher blocking voltage than germanium rectifier elements, so that silicon rectifiers can be made smaller in size than germanium rectifiers, and can therefore be more easily adapted in a switch or switch device. Silicone rectifiers have the disadvantage in general use that the voltage drop during current flow is greater than for any other type of rectifier. This high voltage drop will not do anything when using a silicone rectifier in a switch device according to the invention.

For use in carrying out the invention, the rectifier will generally comprise a number of germanium or silicon rectifier elements connected in series with each other to achieve the required blocking voltage. Similarly, a number of rectifier elements or a group of series-connected rectifier elements can be connected in parallel with each other to provide the desired current flow.

As stated above, a switch device according to the invention will provide effective current breaking even if one or both switches are operated while their contacts carry current. The most advantageous condition is achieved as indicated above, when the first switch is opened while the rectifier is carrying current and the second switch is opened when the rectifier is not carrying current. When implementing the invention, one must therefore provide a device that synchronizes the opening of the switches with the periods of the alternating current. One such device may be of any conventional construction. For example, the synchronizing device for opening the contacts in the switch device according to the invention can be of any commonly used or known type for synchronizing the closing of switches during testing. When a synchronizing device is used in carrying out the invention, this must preferably be set so that it operates the first switch, namely the one that is shunted with the rectifier, that this is opened at or shortly after the beginning of a half-period that the rectifier passes through, while the other switch is opened at or shortly after the beginning of a subsequent half-period when the rectifier is not carrying current. This timing of the contacts is desirable as a time corresponding to approximately half a period is available for movement of the contacts to achieve the necessary distance against kickback in the gap when the rectifier blocks or conducts as is the case for the first and second switches , when the voltage again occurs across the switches. It has been shown in practice that a considerable tolerance in the time setting for operating the switches in relation to the alternating current can be allowed.

It is not necessary for the second switch to be opened immediately after the first switch, but where such operation is not

is desired, the rectifier will have to carry the current to be broken in several half-cycles.

Opening another switch at the first half-period that the rectifier does not pass through therefore allows the use of the smallest possible rectifier for a given switch performance.

It is clear that the invention can be applied to electrical switching devices of all types and for all voltages and currents with or without other devices for arc suppression, as is well known, and can work in air, gas, oil or any other medium.

As mentioned above, it is not necessary for the switch which is shunted with the rectifier to be opened before the other switch. If the other switch opens before the one that is shunted with the rectifier, then the first opened switch will be exposed to an arc during one or more half-cycles, as the arc is extinguished when the rectifier does not carry current, and after the shunted switch is opened, one achieve the effect described above. If the unshunted switch is opened during half a period when the rectifier is not conducting, no current breaking of this switch is required. The shunted switch will then not carry out any current breaking but is necessary for the purpose of short-circuiting the rectifier in the normal closed state of the switch device.

In some cases, a resistor or other impedance can be connected in series with the rectifier, shown at R in fig. 1, in the shunt above the first mentioned switch. Such a resistance or impedance will reduce the current flowing in the rectifier so that its size can be reduced. The contacts for the first-mentioned switch will then conduct current when this is opened during a half-period when the rectifier conducts current, but the switch's performance will again be reduced by the rectifier. The performance of the second switch will be reduced both by said resistance or impedance and by the rectifier in the manner described above.

In the embodiment of the invention shown in fig. 3, the switch device comprises a movable contact arm 20 which cooperates with fixed contacts 21 and 22. The contacts 20 and 21 are connected to each of the wires 23 and 24 which are to be connected by means of the switch device. The contact 22 is connected to the line 24 by means of the rectifier 25 which preferably consists of a number of germanium or silicon rectifier elements 26 arranged in contact with each other in an insulating tube 27, a pressure being applied to the row of rectifier elements by means of the end connection pieces 28 and 29 which are connected with the contact 22 and the wire 24, respectively. The number of units 26 is chosen in accordance with the required blocking voltage. The size of the rectifier elements is chosen in accordance with the required current flow and, if desired, a number of rectifiers of a similar type to 25 can be arranged in parallel with the first rectifier, as shown by the line 25a.

The contact arm 20 is stored at 30 and the peripheral extent of the various contacts is such that the arm 20 touches the contact 22 before it leaves the contact 21. In the shown position of the contact arm, the wires 23 and 24 are connected to each other directly, but by movement of arm clockwise in fig. 3, the first breaking point will occur between the contact arm 20 and the contact 21 and a movement of the arm to the contact 22 will connect the rectifier 25 parallel to the gap between the fixed contacts 22 and 21, so that in the position shown by the dashed arm 20' while a further breaking point will be introduced into the circuit by continued movement of the arm 20 over the contact. 22 as shown in the position of the arm which is shown dashed with 22', the second breaking point being between the arm 20 and 22.

The rectifier's current-limiting effect is the same as described with reference to fig. 1.

Fig. 3 shows one example among many of how the introduction of two switches in a circuit is synchronized with the alternating current. In the example shown, the contact arm 20 is connected to an insulated arm 31 by means of which the contact arm is arranged to be moved to the position shown for closing the circuit. The arm is pulled to the open position 22' by means of a spring 32 which is connected between the arm 31 and a fixed anchoring point 33. The open position of the arm 31 and the contact arm 20 is determined by a fixed stop pin 34.

The switch arm is held in the closed position shown by means of a locking member 35 which is stored at 36 and which engages with a hook 37 on the arm 31. The member 35 is held in the position shown in the drawing by means of its own weight and is determined of a fixed stop pin 36a. The body 35 is made of magnetic material and forms a movable armature which is influenced in a clockwise direction about the bearing 36 by means of a magnet 37a as a winding 38.

A current transformer 39 in connection with the line 23 has a secondary winding connected to an ohmic load 40 whose ends are connected respectively to the grid and the cathode in a gas discharge tube such as e.g. a thyratron 41. The coil 38 is connected to the anode circuit in this thyratron and the anode current source is a battery 42. A variable inductance 43 is inserted in series with the winding 38 in the anode circuit for a reason to be explained later. The grid circuit contains a bias source, e.g. a battery 44 which usually biases the thyratron to a non-conductive state.

In use, the transformer 39, which is a saturation transformer, will during each half-cycle produce a current pulse of short duration with a higher current than the switch is designed to break. This current pulse will be in opposite phase to the current pulse of the current in the line 23 as shown by the dashed line at point A in fig. 2 for the first positive half-period. The ohmic load resistance 40 produces a corresponding voltage pulse which is supplied to the grid of the thyratron. When the voltage pulse due to the overcurrent is supplied to the grid during a positive half period, the thyratron is ignited and the coil 38 is energized, so that the armature 35 is attracted and removes it from the hook 37. The arm 31 is then released and the spring pulls the contact arm 20 over the contact 22 to the open end position 22'.

The tension in the spring 32 is in relation to the moment of inertia of the contact arm 20 and the arm 31 and the parts that are in connection with these and the periodic extent of the contact 21, made so that the arm 20 will leave the contact 21 for a time corresponding to three quarters of a period after the generation of the voltage pulse in the load 40. The first breaking point in the circuit between the wires 23 and 24 will therefore occur at a point B in fig. 2. The variable inductance 43 enables a variable time delay of the current in the coil 38 and thus of the ignition of the thyratron for an adjustment of the time point for the opening of the switch point between the contacts 20 and 21, so that this break occurs exactly at point B.

The continued opening movement between the contacts 20 and 21 occurs in the positive half-wave when the rectifier 25 lets the current through so that the contact is opened without current in them.

The position of the left end of the contact 22 is arranged so that the contact arm 20 will move from the left end of the contact 21 to the left end of the contact 22 in a period of half a period, so that the second interruption in the circuit namely between the contact arm 20 and the contact 22 will be made to open at or approximately at point C in fig. 2. This second interruption is therefore opened during the following half-period when the rectifier 25 does not release current again so that the second switch is also opened without there being current in the contacts.

If desired, a suitable phase shift network can be connected between the contacts of the load 40 and the thyratron grid circuit, to produce a voltage pulse which fires the thyratron at a selected time in the period different from point A in fig. 2.

As mentioned in connection with fig. 1, a resistance or impedance R can be connected in series with the rectifier as shown by the line in fig. 3.

Fig. 4 also shows as an example the use of the invention in connection with an air switch. The switch in fig. 4 is off

known type having movable nozzle contacts carried by tubular members 52 and 53 which slide in cylinders 54 and 55 which are

attached to conductive parts 56 and 57 which form the switch's connections. The movable contacts are in connection with respective stationary nozzle contacts 58 and 59 by means of compression springs 60 and 61 which act between the annular projections 62 and 63 in the cylinders 54 and 55 and the piston parts 64 and 65 which are prepared on the tubular

parts 52 and 53. The fixed contacts 58 and 59 are carried by a metal exhaust chamber 66 which has a number of exhaust openings

as 67. The chamber 66 is carried by a part 57 by means of a tubular insulating body 69 while the part 56 is carried by the exhaust part 67 by means of a tubular insulating part 70. The cylinder 55 is in connection with a

or several outflow openings such as the one shown at 71, the air from the tube part 53 being separated from the air intake opening 72 by means of an internal wall 73 arranged in the part 57.

According to the invention, a one-way rectifier 74 e.g. a germanium or silicon rectifier as shown in fig. 3, or two or more such rectifiers in parallel attached between the parts 75 and 76 which in turn are attached respectively to the parts 66 and 57, the parts 75 and 76 being conductive and thus serving to connect the rectifiers with the parts 57 and 67. The rectifier or rectifiers in this way shunts the contacts 51 and 59 while the contacts 50 and 58 are connected in series with the first mentioned contacts and the rectifier.

The part 66 separates the space in the parts 70 and 69 and in the embodiment according to the invention is

the rooms connected to each other by means of a wire connection 77.

To open the switch, the usual control valve (not shown) is opened to connect the source of compressed air with the opening 72 whereby the pressure increases inside the cylinder

69 and causes the piston 65 so that the contacts 51 and 59 separate. At the same time, compressed air will flow through the connection line 77 and increase the pressure in the part 70

and here too influence the piston 64 so that the contacts 50 and 58 are separated. The length of the connection line 77 is made so that a desired delay is introduced in the build-up of the pressure in the part 70 after the part 69, so that the contacts 50 and 58 will be opened half a period or about half a period later than the contacts 51 and 59 .

It is clear that, if desired, the valve that controls the air supply can be synchronized with the alternating current, e.g. the valve can be controlled in the same way as it

device described in fig. 3.

It is also clear that either the one or

both of the two switches described

above may be multiple switches instead of single switches as described here, and the claims must be understood accordingly.

In a modification of the device described above, the contacts can e.g.

contacts 5 and 6 in fig. 1 instead of being

connected to the main circuit by means of

contacts 3 and 4, be directly connected in

series with the rectifier, namely in the shunt

over contacts 3 and 4. Such a device

will produce the same effect as that achieved

in the device according to fig. 1 in that when contacts 4 and 5 are closed, the opening of contacts 3 and 4 will take place without current during the half period when the rectifier is conducting. Contacts 5 and 6 should also be here even if they are not

necessary, opens after contacts 3 and 4.

When the contacts 5 and 6 are open, the rectifier 7 will prevent the current from flowing in it

half period when the rectifier is not conducting

current so that contacts 5 and 6 again do not

need to break a current flowing in it

then the following half-term.

Claims (5)

1. Electrical switching device for a alternating current circuit where a switch's contacts are shunted with a one-way rectifier which, when the switch contacts are open, transmits current between the contacts in one, e.g. positive, half-period of the current and where the mentioned switch is connected in series with a further switch which is not shunted with a rectifier, characterized in that the device is arranged in such a way that the first shunted switch is opened before the second, non-shunted switch, so that the rectifier prevents, possibly suppresses spark formation in the first switch during e.g. the positive half-period because the rectifier forms little resistance in the shunt path and will prevent, possibly suppress, spark formation in the other switch in the event of a subsequent, e.g. negative half period, when the rectifier is non-conducting. 2. Device according to claim 1, characterized in that the second, non-shunted switch lies in the shunt path above the first switch and forms a conductive path together with the rectifier when the first switch is opened and then switches this path. 3. Device according to claim 1 or 2, characterized in that the opening of the switch is so synchronized with the current that the first switch is opened at or shortly after the beginning of a conducting half-period of the rectifier and that the second switch is opened at or shortly after the beginning of a non -leading half period of the rectifier. 4. Device according to any one of the preceding claims, characterized in that a resistance or other impedance is connected in series with the rectifier in the shunt path above the first, shunted switch. 5. Device according to any of the preceding claims, characterized in that the one-way rectifier consists of one or more per se known germanium or silicon rectifiers in parallel and/or in series for adaptation to the required current and/or voltage.