DE188236C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

-Yes 188236-CLASS 21c . GROUP

Patented in the German Empire on November 27, 1904.

The present invention relates to a combined switch control and switch actuation device, by means of which a switch mechanism, its actuation for the purpose of switching electrical switching devices on and off requires significant force in an AC distribution system, automatically in an or the other direction is adjusted as soon as the load in the distribution system changes

ίο a little a predetermined, far below exceeds or falls below the maximum load, whereby the construction of the switch control apparatus is such that the same is not only one to the desired Actuation of the switch device at the required or required times has sufficient sensitivity, but also meets the following practical requirements:

a) The apparatus should, although it is constantly switched on in the circuit, very little consume electrical energy;

b) it should not cause harmful sparking when moving slowly;

c) it should not have any impact or other harmful effects on the circuit containing the switch when fully loaded and at maximum current strength,
d) If the load falls below the previously determined amount, the actuation by the apparatus should not be sudden but rather slow, ie there should be a certain time limit after which the actuation takes place, for the purpose of actuating the switch device to avoid when the drop in the load below the predetermined level has only been caused by a temporary cause, thereby avoiding unnecessary movements and consequently unnecessary wear and tear of the switch device.

e) Finally, the construction of the apparatus should be such that its operation is only a transitory one, so that it may be a strong one even if the continuous current should use very little energy and no damage from electricity is exposed.

The present invention also relates to the use and device such an apparatus as a transformer, to an auxiliary transformer (or auxiliary transformers) with a main transformer (or with several main transformers) in two-wire, three-wire and multi-phase AC distribution systems on and off, depending on whether the load falls below or exceeds a predetermined level. ■

Fig. Ι the accompanying drawing illustrates the circuit diagram for a customary set up according to the present invention Single-phase or Two-wire distribution system.

a, b are the high voltage primary conductors and c, d are the low voltage secondary conductors.

e and f are the related primary and secondary coils of the main transformer and g and h are the related primary and secondary coils of the auxiliary transformer. k is a moving contact and m, η are fixed contacts. These three contacts form part of a high-voltage switch which, in the open position, connects the primary coils e and g in series with one another to the conductors α and b

ίο switches on at low loads and which in the closed position shorts the primary coil g and leaves the primary coil e switched on alone, ο is the movable and ρ the fixed contact of a low-voltage

switch, which in the open position the coils / and h in series with one another to the conductors c, d switches on at low loads and which in the closed position short-circuits the coil h and leaves the coil f switched on alone. One end of the coil e is connected to the line b and the other end is applied at r to the contact η and to one end of the coil g , the other end of which is connected to the line α .

One end of the coil f is applied to the line d and the other end at s to the contact o and to one end of the coil h , the other end of which is connected to the line c .

According to the present invention, the actual switching device, which consists of the switching contacts k, m, η and ο, ρ (Fig. 1), respectively, for commissioning. Short-circuiting the coils g, h is used and is referred to below as a short-circuit device, actuated by an electromagnet device i , which has two windings u and t . The circuits of the same are controlled independently by two independent automatic switching devices, one of which (v), hereinafter referred to as an electrically operated switch, is dependent on the circumstances with regard to its operation, whether the load is above or below a predetermined level falls below, while the other switching device TP, hereinafter referred to as mechanically operated switch, is dependent on the circumstances with regard to its operation, whether the electromagnet and short-circuit device is effective in one direction or the other. The arrangement is such that when the load falls below the predetermined level, one of the windings, for example u, of the electromagnetic device, which has been closed at I by the movement of the switch w , is completely closed at a second point 2 and is applied to a source of electrical energy by the switch ν. This ensures that the armature of the solenoid device i is adjusted in one direction, the short-circuit device opens the high and low-voltage switch (contacts), accordingly the two coils g and h turns on while removing the short circuit and at the same time the switch at w The circuit of the winding u interrupts at ι, whereas the circuit of the winding t closes at the corresponding point i ^a; here this circuit of the winding t is opened by the movement of the switch ν at a second point 2 ^a . The various parts of the device are then in the position illustrated by FIG.

If the load exceeds the predetermined limit, the switch ν connects the winding t at point 2 ^a to the source of electrical energy, whereby the electromagnet device is moved in the opposite direction and thereby causes the short-circuit device to short-circuit the coils g and h and that at the same time the switch w interrupts the line of the winding t at i ^a , whereas that of the winding u closes at 1.

As a result of the device described, the electrically operated switch, which operates slowly, only acts to close a circuit, but not to open a closed circuit, while the effectiveness of the mechanically operated switch is to completely open a circuit through the electrically operated switch has been closed, to open quickly and to close an open circuit at one point of the same preparatory, so that the same can be completely closed at a second point by the electrically operated switch. This avoids the creation of harmful sparks between the fixed and movable contacts of the electrically operated switch, which sparks could be formed if the load on the system were to change slowly and the said contacts would therefore slowly be separated from one another to form an existing complete circuit interrupt. Likewise, if the circuit is interrupted by the mechanically operated switch, sparking is avoided for the reason that this switch is always operated quickly and almost instantly, respectively. is adjusted. This arrangement offers the security that the current BEZW only temporarily. flows through the windings t and u for only a moment.

The electromagnet device, the short-circuit device and the electrical and mechanically operated switches can be used to

Achieving the above effects built in different embodiments will.

The combined electromagnet and short-circuit device, as shown in Fig. 1 and on a larger scale in Fig. 2, consists of an iron housing 3 which is attached to a support plate 4 and is provided with a horizontal iron plate 5 inside. The latter carries hollow iron cores 6 and 7, around which two coils t and u are wound. In front of the two ends of the housing and opposite the core ends, two iron disks or anchors 8 and 9 that are rigidly connected to one another are arranged, the mutual distance between them being greater than the length of the housing. Each of the two ends of the housing is closed by an insert plug 3 * made of non-magnetic material.

The arrangement is now such that when the circuit of the winding t is completely closed, a magnetic circuit through the core 6, plate 5, housing 3 and plate 8 is completed, whereupon the coupled plates 8 and 9 are moved downwards. An upward movement of these plates takes place when the circuit of the winding u is completely closed. The short arms 10 of two angle levers 10, 11, which are pivotably attached at 12, are articulated on the disk 9. The longer arms 11 of the angle levers are connected to the lower ends of associated links 13, the upper ends of which are articulated to a vertically guided head 14. The latter carries the two movable contacts k and 0, which are electrically isolated from one another. The long lever arms 11 and the link 13 together form a toggle lever. The contact k, which advantageously consists of a bundle of curved copper strips, is used to short-circuit the two fixed contacts m and η of the high-voltage switch. The advantageously wedge-shaped contact 0 is carried by a transverse rod 15 which is fastened to the head 14 by means of guide rods 16. This contact places in lifting the rod 15 to the advantageous j \ - or angled cut, fixed contact ρ of the low-voltage switch.

The electrically operated switch (Fig. 1) consists of a solenoid 17 which is connected in series with one of the primary or secondary main conductors, advantageously with the primary conductor a , and is provided with an iron core 18 which is attached to one arm of a lever which can be rotated by 20 19 is articulated, the other arm of which is provided with an optionally adjustable weight 21. The two ends of the switch lever 19 are provided with contacts 22 and 23, which two associated isolated, fixed contacts 24 and 25 are opposite. The contact 24 is connected to one end of the winding t and the contact 25 to one end of the winding u of the electromagnet device i (FIG. 1), while the switching lever 19 is connected by conductor 26 to the main line c . The contacts 22, 23, 24 and 25 are advantageously made of carbon. The other ends of the windings t and u are placed on two associated fixed, insulated contacts 27 and 28, which are components of the mechanically operated switch n> (FIG. 1). The movable contact 29 of this switch is connected to the main line d by conductors 30 and consists of a lever, the ends of which slide over the contacts 27 and 28. One of the arms of this lever is connected to the movable disc 9 by a link 31, for example. The arrangement of the contacts 27, 28 and 29 is such that when the contact 29 is pivoted through the disk 9 in the direction of the arrow χ one of the arms of the contact lever slides over the contact 27 and remains in contact with the latter, while the other lever arm of the Contact 28 slides off, whereby the circuit of the winding t is closed at i ^a and that of the winding u is opened at ι. The opposite effect occurs when the contact lever 29 is rotated by the disks 8, 9 in the opposite direction. The switch lever 19 is moved by the core 18 of the solenoid 17 in one direction when the load and accordingly also the current flowing through the solenoid rises above the predetermined level and moved in the opposite direction by the weight 21 when the load and the current falls below this predetermined level, with a pair of contacts 22, 24 or 23, 25 always in contact when the movement is over. A damper 32 can be connected to the lever 19 in order to keep the speed of the lever movements within limits after the load has exceeded or fallen below the predetermined level. This damper is advantageously designed with a piston which is arranged in such a way that it can rise quickly so that the switch lever 19 brings about the short-circuiting of the auxiliary transformer safely and quickly, but can only slowly sink in order to put this transformer into operation while removing the short-circuit , whereby it is prevented that this switching on of the auxiliary transformer takes place if the reduction of the load below the predetermined level only for a short time

Period occurs. For this purpose, the damper piston 32 ^s , as shown in FIG. 3, can be enclosed with clearance in the cylinder 32 * and provided with holes 32 ^ which are controlled by a valve 32 ^. The latter consists of a thin sheet of light material, for example made of mica or silk, which is enclosed in a frame 32 ^ carried by the piston. The arrangement is such that the plunger can be drawn rapidly upwards through the core 18, the liquid above the plunger being able to pass rapidly downwards through the holes in the plunger and via the valve 32 ^, while that by the weight 21 caused the piston to move downwards, the valve closes the holes 32 °, so that the liquid only passes through the annular gap between the piston

and housing wall can flow over the piston.

Fig. 4 shows the arrangement of an auxiliary transformer with a single-phase three-wire distribution system.

In this embodiment, the primary coils e and g of the main and auxiliary transformer are connected to each other and to the primary main conductors b and α at the point marked r and are controlled by a high-voltage switch k, m, η , which is part of the combined short-circuit, electromagnet - and forms mechanically operated switch device, as has been described with reference to FIGS. 1 and 2. The auxiliary transformer has two secondary coils h, h ¹ , one end of the coil h through line 34 with the outer main conductor c of the three secondary lines c, d, d ^l and through line 35 with one contact, namely o ¹ , one of one fixed and a movable contact o ¹ respectively. p ¹ existing pair is connected. The contacts ο ^ι , ρ ^λ belong to a second system of combined short-circuit, electromagnet and mechanically operated switch device i ^{1 of} the type specified above. The contact p ^l is connected by line 36 to the other end of the coil h , which is also connected at 37 to one end of the coil f . One end of the coil h ¹ is through line 38 to the second outer main line d and through line 39 to the one contact, namely p, the respectively from a fixed and a movable contact ρ. 0 existing pair, the latter belonging to the first system of combined short-circuit, electromagnet and mechanically operated switch device. The other contact 0 of the pair is connected by line 40 to the second end of coil f , which is also connected by line 41 to the second end of coil h ¹ . The coil / is connected at the center point 42 by line 43 to the central or main earth line d ^v . A single electrically operated switch is associated with the two electromagnet devices i and i ^l , the contact 24 of which is common to the two windings t and i ¹ , while the contact 25 is common to the two windings u, u ^{1 of} these electromagnet devices. Otherwise, the arrangement is similar to that in the two-wire distribution system (Fig. 1), and the single auxiliary primary coil g and the two auxiliary secondary coils h, h ^l are put into operation and short-circuited as soon as the load falls below or exceeds the predetermined level. The contacts o ^l , p ^{l of} the low-voltage switch can, as shown in FIG. 5, be arranged as components of the system denoted by i of combined short-circuit, electromagnet and mechanically operated switch device, while the second system is omitted.

6 shows the circuit arrangement for a multiphase working system set up according to the present invention. In this embodiment of the three-phase system, a small three-phase auxiliary transformer is used together with a three-phase main transformer. The primary coils of the two transformers are arranged in a star connection, the secondary coils in a chain connection. Each of these primary coils g, g ^l , g ' ^{2 of} the auxiliary transformer is connected in series with one of the primary coils e, e ¹ , e ^{2 of} the main transformer between one of the primary conductors a, a ¹ , a ² and the middle grounding point E , and each of the Secondary windings h, h ¹ , h ^{2 of} the auxiliary transformer is connected in series with one of the secondary coils /, f ¹ , / ^{2 of} the main transformer between this coil and one of the secondary conductors c, c ¹ , c ² . To start up or short-circuit the auxiliary primary and secondary coils, depending on whether the load falls below or exceeds the predetermined level, short-circuit devices of the type described above are available, which consist of three high- ^{voltage switches 45, 45 a} and 45 ^b and three low-voltage switches 46, 46 * and 46 * exist and are operated by an electromagnet device i ² under the action of electrically and mechanically operated switches ν and w of the type described above.

In this case, the electrically operated switch is provided with different solenoids, for example three solenoids 17, ij ^a and ij ^b in a three-phase system, each of these solenoids in series with one of the primary lines a, a ¹ , d ^l and with one of the

Primary coils e, e ¹ , e ^{2 of} the main polyphase transformer is placed. The cores of the solenoids are attached to a common rod or to a frame 47 which is hinged to an arm of the switch lever 19.

Furthermore, in this embodiment, the coils g, g ^l and g ^{2 are arranged} between the coils e, e ¹ , e ² and the grounding point E , but can also be between the coils e, e ¹ , e ² and the primary conductors α, α ¹ , σ? be switched. Likewise, the primary and secondary coils of the main transformer instead of the star or shown.

Daisy chain can also be connected in other ways, with the coils of the auxiliary transformer can be connected in series or short-circuited with the related first-mentioned coils as required, as indicated above.

Instead of a single polyphase auxiliary transformer three single-phase auxiliary transformers can also be used, which are connected to one another in such a way that they together form a single polyphase auxiliary transformer.

The described device and arrangement of the various fixed and movable Switch contacts can be modified as required without affecting the effectiveness of the system.

Claims (3)

Godfather sayings: i. Automatic on and off switch for the auxiliary transformer to be switched on or off a main transformer by means of a relay through which the current flows and a short-circuit device which is influenced by an electromagnetic device provided with two windings, characterized in that the relay (v) is a double-acting one with damping Contact carrier (19) which, depending on the deviation from a certain load, connects one or the other of the two coils (t, u) to a current source only until the part of the electromagnet ( i) the switch (n>) quickly interrupts this circuit again and thereby closes the interruption point of the other coil on this switch. 2. An embodiment according to claim ι for a single-phase - three-wire distribution system, characterized in that the auxiliary transformer for use with the main transformer with a single primary winding (g) and two secondary winding (h, h ¹ ) is provided, the latter with the secondary winding ff) of the main transformer connected to the central conductor of the three-wire system can be connected in series in such a way that they come to lie on opposite sides of the central conductor (d ^l ) , the short-circuit device (k, m, n, o, p, o ^l , p ^l ) is arranged in such a way that it simultaneously switches on or short-circuits the primary winding (g) and the two secondary windings (h, h ^l ) of the auxiliary transformer (FIGS. 4 and 5). 3. An embodiment according to claim ι for a multi-phase system, characterized in that the contact carrier (19) of the electrically operated switch or relay (v) is subjected to the combined effect of one of the number of phases equal number of solenoids (17, iy ^a , 17 *) which are arranged in the primary or secondary main line and act on the contact carrier (19) by means of a part (47) common to all solenoids, the movable part (8, 9) of the electromagnet device (i) having one of the number of phases Number of short-circuiting contacts for the primary and secondary windings of the auxiliary transformer is connected. 1 sheet of drawings.