DE580723C - Multi-phase automatic lever switch - Google Patents

Description

They are multi-phase automatic lever switches to protect objects against inadmissible contact voltages known at which when the trigger responds all phases are switched off. The switches have the disadvantage that, if only in In one phase there is a lack of isolation, even the healthy phases cannot be switched on earlier until the failure of the sick phases is resolved.

The invention relates to a multi-phase lever switch in which the aforementioned Disadvantage is avoided. According to the new Mehrptiasige lever switch in which the phases are switched off together by hand and with the aid of a residual current release are designed so that the phases are also switched on and off individually by hand can be. Does the switch have overcurrent

«O trigger in every phase, it becomes appropriate designed in a manner known per se so that when the overcurrent release responds of a phase, only the phase in question is automatically switched off. The new

The switch can also be used with a device with the help of which all phases of the switch simultaneously can be switched on manually. The new switch not only has the advantage that it allows more switching possibilities than the previous switches, but above all Things also have the advantage that despite the presence of an insulation fault in one Phase the healthy phases can be switched on manually.

An embodiment of the new switch is shown in Fig. 1 of the drawing in longitudinal section, in Fig. 2 in cross section along the line AA of Fig. 1 and in Fig. 3 in cross section along the line BB of Fig. Ι. Fig. 4 of the drawing shows a further embodiment of the new switch in cross section.

The switch shown in Figs. 1 to 3 is a four-pole switch Switch for a three-phase network with neutral. The switch has overcurrent and residual current tripping. The fixed contacts 2 and on are on the switch base plate ι the leaf springs 3 attached movable contacts 4 attached. The next to the moving ones Contacts 4 arranged switch locks are on the base plate 1 attached carriers 5 attached. The movable contacts 4 are with the help of Lasehen 6 connected to the levers 8 rotatable about the fixed axes 7, which in turn Via the toggle levers 9 and Io with the levers 12 rotatable about the fixed axes 11 stay in contact. The levers 12 can be operated individually with the aid of the switch handles 13 so that the associated phases are switched on and off individually by hand can. In each phase an energy store is arranged, which from around the fixed Axles 14 rotatable double-sided levers 15

and springs 16 arranged between these and the switch mechanism. The energy accumulators are locked by the toggle levers 17 and 18, of which the levers 18 are rotatable about the fixed axes 19. The bimetallic strips 20, which act on the locking of the energy storage devices with the aid of the adjustable pins 21, serve as overcurrent releases. Around the current-carrying springs 3, horseshoe-shaped magnetic cores 22 are arranged which, when a short circuit occurs, attract the armatures 24, which are rotatable about the fixed axes 23, and thereby unlatch the energy storage devices. As can be seen from Fig. 3, instead of an overcurrent and short-circuit release, a fault current coil 25 is provided in the neutral conductor, which attracts the double-sided armature izj rotatable about the fixed axis 26 when a contact voltage occurs, and with its help the energy store of the neutral conductor unlatched. The movable contact 4 of the neutral conductor is connected via the lever 8 and the tab 28 to the lever 29, which is firmly seated on a control shaft 30 arranged behind the switch plate 1. The control shaft 30 goes through all three phases and in each phase has a lever 31 (Fig. 2) and a tab 32 which acts on the latching of the individual energy storage devices. If a fault current flows through the coil 25, the energy storage devices of all phases are unlatched with the aid of the control shaft 30 and all phases are thereby switched off. The arrangement is made in this way. that the phases are switched off earlier than the neutral conductor and cannot be switched on again without first switching on the neutral conductor. All-pole disconnection of the switch by hand can be achieved in a simple manner by disconnecting the neutral conductor. Since the phases are also arranged independently of one another and each provided with a trip-free release, they can be switched off automatically by the releases 20 and 22 independently of one another. In addition, they can be switched on and off individually by hand with the aid of the switch handles 13. A complete separation of the spark spaces of different phases can be achieved in that the control shaft 30 is arranged in front of and the contacts 2 and 4 behind the switch plate 1 and that continuous partition walls are provided between the contacts 2 and 4 of different phases. The leaf springs 3 carrying the movable contacts 4 are then connected to the switch locks arranged on the switch base plate 1 via connecting straps. In the exemplary embodiment shown in FIG. 4, the contacts 2 and 4 are arranged behind the switch mechanisms and, in each phase, are accommodated in a single-pole spark chamber 33 that exists for itself. The switch mechanism of each phase is fastened with the releases and the other parts on the spark chamber 33, so that the switch consists of several independent elements. When assembling the switch, several spark chambers 33 are nested one inside the other, one spark chamber representing the closure of the next spark chamber. The spark chambers 33 are held together by the bolts 34.

Claims (6)

75 claims: ι. Multi-phase automatic lever switch in which the phases are manually and are switched off together with the aid of a fault current release, characterized in that the phases also can be switched on and off individually by hand. 2. Multi-phase automatic lever switch according to claim 1, characterized in that in each phase a switch lock provided with a trip-free trip (9, 10), one on the trip-free trip (9, 10) of the lock, acting energy storage device (15, 16) and a control handle (13) are provided, with the help of which each phase can be switched on and off individually by hand, and that a common control shaft (30) is arranged for all phases, which is connected to the movable contact (4) of the neutral conductor ¹ and When the neutral conductor is switched off by hand or by a fault current release (25), the energy storage devices (15, 16) too of all phases are unlatched, thereby causing all phases to be switched off. 3. Multi-phase automatic lever switch according to claim 1, characterized in that that in each phase on the latch (17, 18) of the energy store (15, 16) effective overcurrent and short-circuit release (20,22) is provided, which when an overcurrent occurs in a Phase the energy store (15, 16) this Phase unlatched and thereby the automatic shutdown of the relevant phase independently of the other phases. 4. Multi-phase automatic lever H5 Switch according to Claim 1, characterized in that it also has a Device is provided with the help of which; all phases by hand at the same time can be switched on. 5. Multi-phase ■ automatic lever switch according to claim i, characterized 58072a indicates that the contacts (2, 4) behind the switch base plate (1) and that between Continuous partition walls are arranged in the contact spaces of different phases. 6. Multi-phase automatic lever switch according to claim i, characterized in that that the carrier (5) of the switching mechanism of each phase with the associated releases (20, 22 or 25) on a single pole Spark chamber (33) is attached, in which the contacts (2, 4) of the relevant Phase by itself are included, and that several spark chambers (33) are assembled to form a multi-pole switch are, with one chamber representing the closure of the next following spark chamber. 1 sheet of drawings