DE19510510A1 - Electronic high voltage switch esp. in vehicles - Google Patents

Abstract

The switch has a cathode (K), a control electrode (G) and an anode. The vacuum microelectronic potential follower is realised using field emission technology, with a field emission cathode (K) and a control electrode (G) to activate the potential follower function. The switch has one anode (A1) to generate secondary electrodes and also has an anode to intercept the secondary electrodes. Preferably, the potential of the first anode (A1) follows the potential of the second anode (A2) when a positive control voltage is applied to the control electrode (G). The control voltage is preferably between 0 and 400 volts. The switch may be closed when the potential of the first anode (A1) approximates that of the second anode (A2).

Description

Electronic components are used, for example, in motor vehicles, and especially in the engine compartment, special requirements. On the one hand, the semiconductor components must have high temperatures tolerated and on the other hand, the components are extremely high Demands are made if high voltages come directly to you Semiconductor switches are created. To the high tensions must record i. generally several semiconductor components in series be switched. This is complex and expensive. A destruction of Components caused by overvoltages are not yet certain to exclude.

Field emitters are u. a. from publications by C. Spindt, from the Standford Research Institute known. So far they are mostly for Displays used.

The field emitter, a component of vacuum microelectronics, uses the controlled emission of electrons from a metal tip or edge into the vacuum. In FIG. 2, the basic structure of a field emitter is illustrated with field emission cathode. The metal tip is in a high electrical field at room temperature.

Due to the shape of the metal tip, field strength increases are possible up to Range of some 10⁷ V / cm possible. These field strengths are sufficient for Electrons out to the potential mountain at the height of the work function tunnel through.

Because of the small distance between the cathode tip and the edge of the gate Hole and the much greater distance to the anode in case of voltages in the same size arrangement on both electrodes, determined in essentially the gate voltage for the field emission at the cathode prevailing field strength.  

The electrons are already in after exiting the tip Cathode proximity to a noticeable part of the final speed accelerates.

The invention has for its object an electronic switch specify, in which the output potential V1 an input potential V2 follows when the switch function "Switch closed" is enabled.

The object is achieved by the features specified in claim 1 solved. Further training is included in the subclaims.

The principle of the switch according to the invention is shown in FIG. 1. The input voltage V2 is always positive. The output voltage V1 is always positive when the switch is closed. When the switch is open, a voltage V1 can be present at the output, which can be a few 10 kV and is negative. When the switch is open, the leakage current may not exceed a few nA. The output voltage V1 can be higher or lower than the input voltage V2 (bipolar switching function). The control voltage for the open and closed states should be in the range between 0 V and a maximum of a few 100 V. The switch to be specified must fulfill its switch function under the conditions mentioned and it must be able to be represented in vacuum microelectronic technology.

The invention is explained below with reference to the drawing.

It shows:

Fig. 1 wiring of the bipolar switch;

FIG. 2 shows the realization of a bipolar switch with two Feldemittertrioden;

Fig. 3 principle of the potential follower with field emitter and

Fig. 4. Application example ignition system with potential follower with field emitters.

Field emitters in vacuum microelectronics have high insulation resistances between the electrodes. The insulation resistances are through determines the properties of the electrode carrier materials.  

With a suitable formation of the geometry of the field emitter and choice of The anode can have high voltages compared to the rest Pick up electrodes. Because of their properties are suitable Field emitter for displaying highly insulating switch functions with big potential changes.

The implementation of a bipolar switch with two field emitter triodes is shown in FIG. 2. A field emitter, consisting of field emission cathode, control electrode or gate and anode, has the disadvantages described below in the implementation of the switch floating in potential. Assuming the switching connection would be established between anode 2 , 3 and cathode 4 , 6 . The positive switch voltage between the anode and cathode could then not drop below the value of the control voltage between gate 5 and cathode without a gate current flowing. It must also be ensured that the switch remains open when the high negative voltage V1 is applied. The control voltage VG at the gate 5 would have to assume high negative values, which means a considerable additional effort.

The disadvantages mentioned are avoided if the anode A1 of the field emitter in FIG. 3 is designed as a secondary electron emitter and a further anode A2 is added. In the case of the potential follower with field emitter that is created, the potential at anode A1 follows the potential at anode A2 in the de-energized, non-loaded case (IA1 = 0, IK not = 0). At the anode A2 there is a positive direct voltage 7 , for example an alternating useful voltage 9 is superimposed.

The sum of both voltages forms the input voltage to be switched. If the potential at A2 is higher than at A1, more electrons are emitted by the secondary electron effect of A1 than are collected by the cathode K. The potential at A1 is becoming more positive. If the potential at A2 is lower than at A1, fewer electrons are emitted than those from the cathode K are collected. The potential at A1 becomes more negative. The stationary case, that the potential at A1 is equal to that at A2, arises when the same number of electrons are emitted from A1 as are collected. The switch is now closed. Strictly speaking, the description applies to the currentless case I _A1 = 0.

The principle of the potential A1 approaching A2 does not change in the current case I _A1 << 0. Due to the switching resistance, a current-dependent voltage drop occurs between A1 and A2.

The switch connection between A1 and A2 becomes electronic interrupted when the control voltage VG at gate G Field emission is ended.

Fig. 4 shows an example of application of a potential follower in an ignition system with a field emitter switch. The ignition voltage UZ supplies several spark plugs in succession via field emitter switches. If the ignition voltage UZ = 0 V, the storage capacitor 11 is charged via the potential follower 12 with a positive voltage for the field emitter switch 13 . The charging input voltage V2 is a few 100 V in size and the switch function of the potential follower is in the closed state by a positive control voltage VG. After the capacitor 11 has been charged, the potential follower is opened by the control voltage VG = 0. V2 can also become zero. The ignition voltage UZ changes its value to UZ = -30 kV. The voltage on the storage capacitor 11 closes the field emitter switch 13 , which builds up the ignition voltage at the spark plug 14 by means of a current flow, until ignition occurs. When the ignition voltage UZ has returned to the value OV, the storage capacitor is discharged via the potential follower 12 and the field emitter switch 13 is opened.

Claims (7)

1. Electronic switch for high voltages with a cathode, a control electrode and an anode, characterized in that the vacuum microelectronic potential follower is designed in field emitter technology, with a field emission cathode (K) and a control electrode (G) for activating the potential follower function, and in addition to an anode (A1) an anode (A2) for collecting the secondary electrons is provided for generating secondary electrons. 2. Electronic switch according to claim 1, characterized in that the potential V _{A1 of} the first anode (A1) follows the potential V _{A2 of} the second anode (A2) when the positive control voltage VG is applied to the control electrode (G). 3. Electronic switch according to claim 1 or 2, characterized, that it controls a field emitter as a potential follower. 4. Electronic switch according to one of claims 1 to 3, characterized, that he has a field emitter in an ignition system as a potential follower controls. 5. Electronic switch according to one of claims 1 to 3, characterized, that the voltage (VG) at the control electrode (G) between 0 and Is 400 V.   6. Electronic switch according to one of claims 1 to 3 or 5, characterized, that the switch is closed when the potential at the anode (A1) has approached the potential of the anode (A2). 7. Electronic switch according to one of claims 1 to 3 or 5 characterized, that the switch is interrupted when the control voltage (VG) on the control electrode in the range of VG from -100 V to +100 V the field emission ended.