DE973466C - Photocell switching with an amplifier tube connected to the photocell - Google Patents

Description

It is known to monitor a light source (for example a flame) by having it emitted light beams are thrown onto a photocell to which an amplifier tube is connected in the anode circuit of which there is a relay. If the light source goes out, it is affected the change in the current of the photocell the amplifier tube in such a way that its anode current changes, which actuates the relay and triggers an alarm signal or any causes or initiates another, appropriate process. Instead of monitoring the light source even such an arrangement is very often - ■ z. B. for measurement or control purposes - in addition used to determine whether a particular opaque object, for example a Measuring pointer, enters the beam path between an auxiliary light source and the photocell and thereby covers the light falling on the photocell.

With all of these monitoring devices, the circuit arrangement can always either be made in this way be that when the photocell is exposed to the

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The anode current of the amplifier tube is large and, if the photocell is not exposed, is small or completely to Disappearance comes (light switching), or vice versa (dark switching). Most of them practical. Applications of such monitoring devices is now the exposed state of the Photocell to be expected more frequently or for longer periods of time and thus represents the normal state, while the loss of exposure means an unusual condition or 'even on one Indicates disruption. In these cases, dark switching would be preferable to light switching for the reason that because with her the amplifier tube is loaded with the full anode current less often, with which ig itself - apart from the electricity savings - increases its service life and thus the probability failure of the monitoring device due to failure of the amplifier tube is reduced. The dark switching in the embodiments known up to now has the disadvantage that if the amplifier tube fails due to a broken filament or other damage, the undisturbed normal state of the object to be monitored is reported, since the absence ag of the anode current as a result of tube damage has the same effect on the relay in the anode circuit, like an exposure of the photocell. Such a failure of the monitoring device means but usually a great danger for the monitored system.

It is known to work an amplifier tube through a relay in the anode circuit too monitor, which drops in the absence of the anode current and thereby activates alarm signals 3g or other appropriate switching measures. It goes without saying that there was also the relay in the anode circuit of the amplifier tube another work resistance.

Using this idea, the described disadvantage of the dark switching becomes thereby remedied that according to the invention in addition to the relay monitoring the photocell in the anode circuit The amplifier tube has a second relay so sensitive that it is switched from the Residual anode current still flowing in the blocked area of the tube when the photocell is fully exposed is still tightened and only if the amplifier tube fails falls off.

In the case of photocell amplifier circuits operated in hot condition, it is known in the Anode circuit of the amplifier tube to switch two relays, which are set to a maximum or minimum of the anode current respond. However, neither of these two relays has the task of amplifying the g5 tube itself to monitor. If the amplifier tube fails, both relays would drop out anyway, so that a special monitoring circuit, as in the subject of the invention, which photocell and amplifier tube are operated in dark mode is not required at all and this is not even thought of here.

In simple applications of the invention, for example in monitoring devices, with which the burning or going out of a light 6g source (flame) is only to be displayed, the second relay closes or opens if the amplifier tube fails its own display or alarm circuit for the operating status of the amplifier tube.

In applications, however, where an electrically controllable system is to be monitored, one leaves for example, switch off the monitored system for safety reasons through the second relay.

A preferred system that can be controlled electrically for monitoring 7g, depending on its operating status influence the light from an auxiliary light source falling on the photocell, suitable further training of the invention. The circuit consists of the two relays in the anode circuit the amplifier tube together with a third relay in a manner known per se a relay combination is formed which works in such a way that the system to be monitored is only switched on is (or can be switched on) after to- 8g before (when switching on the monitoring device) both relays in the anode circuit have responded and switched on the auxiliary light source and then the first relay has dropped out again, and that the system to be monitored by dropping the second relay is switched off together with the auxiliary light source.

A particular advantage of this circuit arrangement is that it is caused by the switch-on process not only the amplifier tube, but also the gg photocell and its lead for any short circuit be checked, since such a short circuit affects the amplifier tube like an exposure the photocell. Both in the case of a short circuit mentioned and in the case of a defective amplifier tube both relays do not respond. The system to be monitored can therefore not at all be put into operation before the monitoring device itself has not been properly operated Work is checked. 10g

In the drawing, an application example for the invention is shown schematically.

L is a light source whose light is thrown through the converging lens 5 "onto the photocell F. M is an opaque object that is temporarily located in the beam path between the light source and the photocell, for example one connected to the float of the water level indicator of a heated boiler Body, or the swimmer himself, who in a known manner covers the exposure of the photocell in the event of an impermissible drop in the water level, in which case the heating medium supply to the electrically heated boiler, for example, must be switched off immediately. The amplifier tube V is connected to the photocell F; the The bias of their control grid G is suitably set by the tap on the resistor R. The relays R ₁ and R ₂ are located in the anode circuit of the amplifier tube V. The relay R ₂ is more sensitive than the relay R ₁ and also picks up 12g when the Anode current of the

tube has assumed a certain low value due to the exposure of the photocell. The relay R _1, on the other hand, only picks up when the full anode current corresponding to the unexposed state of the photocell F flows through the amplifier tube. The relay R ₂ operates the. Break contact r ₂ I and ₂ II working contact r, the relay R _1, the working contacts ₁ T 1 and T ₁ II, and the normally closed contact T ₁ III. In one at points i, 2

ίο the auxiliary circuit branched off from the supply network is the relay R ₃ with the _{normally open contacts T 3} I, r ₃ ll and T ₃ III. The contact r ₃ l is a self-holding contact for the relay R ₃ in the event of the opening of T ₁ I. The contact r ₃ ll is used for on and

! 5 Switching off the light source L. _{The contact T 3} III placed in a special circuit is used - in the example mentioned above - to switch the electric heating of the water boiler on and off. St is a fault indicator that appears in

so there is a circuit branched off from the feed network at points 3 and 4, which is opened or closed _{by contact T 2 1.} Ü is a monitoring indicator, which is located in a branched circuit at 5 and 6, which is switched by the contact V ₁ II of the relay R ₁ . In the same circuit there is a contactor Sch, which, for example, switches on a feed pump to supplement the boiler water when the current passes through.

This circuit arrangement works as follows: If the boiler water level is high enough, the body M is in the position shown in relation to the light source L and photocell F. If the photocell F and amplifier tube V are now ready for operation, when the power switch is turned on, N and after Completion of the heating time for the tube V, the relays R ₁ and R ₂ to pick up, since the light source L is not yet burning and the anode current flows in the anode circuit of the tube V so the full anode current. The relay R ₂ opens the contact r _% \ and closes the contact T ₂ II. The relay R ₁ closes the contacts T ₁ 1 and T ₁ II and opens the contact T ₁ III. By closing the contacts r ₂ II and T ₁ 1 that happens

Relay R ₃ energized, pulls its self-holding _{contact r 3} l, switches the light source on by closing contact T ₃ II and prepares the circuit for electrical heating of the water boiler by actuating contact r _{3 III.} As soon as the light source L is on, the anode current of the amplifier tube V drops to a value at which the relay R ₁ drops out. This does not change anything for relay R ₃ , since contact T ₁ 1 is bridged by contact T ₃ 1, but contact T ₁ III now closes and switches on the electric heating of the kettle , which is connected to its supply source at P. Furthermore, the circuit for the monitoring display element Ü is interrupted again by opening the contact T _{1 II.} The normal operating state of the entire system is thus achieved. If the boiler water level falls to an impermissibly low value in the further course, the body M covers the exposure of the photocell F ,! and the anode current of the amplifier tube increases \ to its full value. The relay R ₁ responds and switches on the monitoring device ü and the contactor Sch by means of contact r _x II, and the addition of the boiler water is initiated, the boiler heating is switched off via contact V _{1 III;} moving contact Y ₁ 1 does not result in any further changes. (The same switching state occurs when the mains switch N is inserted, as long as the body M is currently covering the light source, i.e. the boiler water level is impermissibly low).

If the boiler water level rises again, the body M moves away from the light path again and the normal operating state of the system described first is restored.

In the event of a short circuit in the photocell or its supply line or if the amplifier tube is defective from the start, the system cannot be put into operation because relay R ₁ and, as a result, relay R ₃ do not respond, contact T ₃ III therefore remains open ( in addition, the light source is not switched on because contact T ₃ II does not close).

If the amplifier tube V becomes incapable of working during operation, for example due to a broken filament or an interruption in the anode supply line, relays R ₁ , R ₂ and - as a result of the opening of contact T ₂ II - also relay R ₃ drop out, thereby heating the kettle and the light source L are switched off and also the fault display element St is switched on.

The opening contact T , which can be actuated by hand, serves to prevent the malfunction indicator element St from responding before the amplifier tube V has finished heating. Such a contact in the circuit of the monitoring display element Ü and the contactor Sch could prevent them from responding briefly when the system is switched on (before the lamp L is on and the photocell F is exposed).

Claims (2)

Patent claims: 1. Photocell circuit with one connected to the photocell no cell connected to the amplifier tube, in the anode circuit of which there is a relay that is included due to the exposure of the photocell, the reduced anode current (»dark switching«) falls, for Monitoring of processes that influence the damage to the photocell, characterized in that that in the anode circuit of the amplifier tube there is a second so sensitive one Relay is switched that it is in the blocked area of the tube at full exposure The residual anode current still flowing in the photocell is still attracted and only when the Amplifier tube falls off. 2. photocell circuit according to claim 1 for the purpose of monitoring an electrically controllable System, which according to its operational state influences the light from an auxiliary light source falling on the photocell, characterized in that that from the two relays in the anode circuit of the amplifier tube together with a third relay in itself known circuit a relay combination is formed such that the to be monitored System is switched on or can be switched on after both Relay in the anode circuits responded and switched on the auxiliary light source and then the first relay has dropped out again, and that they together with the drop-out of the second relay the auxiliary light source is switched off. Considered publications:
German Patent Nos. 591 891, 759955; • U.S. Patent No. 2,309,329. 1 sheet of drawings © 609 526/216 5.56 (909 721/17 2.60)