DE537148C - Circuit arrangement for displaying or recording changes in a set - Google Patents

Description

Circuit arrangement for displaying or recording changes in a quantity The invention relates to a circuit arrangement for display or recording changes in a quantity, e.g. B. the amount of in the atmosphere existing smoke, which regulates the conductivity of a photoelectric Acts on the cell, the current fluctuations of which are intensified, in particular by three-electrode tubes, and then act on a recording instrument or the like.

In such systems, where the photoelectric cell with its cooperating light source and the electrodes of the amplifying tube voltage refer to the same electrical network, there is a risk of disruptive Effect of fluctuations in the feeding network. Will by such a fluctuation z. B. the intensity of the light source is weakened, if not special precautions be taken, and associated with a decrease in the grid potential of the tube according to the sum of the active dips resulting from the decrease in the grid voltage, the anode voltage, the cell voltage and the illuminance.

The invention now has the task of such summation of disturbances to compensate for changes in the line voltage. This is done according to the invention because the photoelectric cell is in the grid circle of the three-electrode amplification tube in series with a grid bias impedance parallel to a potential and connected to a source of negative potential greater than that Grid bias potential so that a change in the output of the amplifier due to changes in the anode voltage and the normal grid bias der, fluctuations in the mains voltage of the same order of magnitude, but opposite Polarity is how the changes in the output of the amplifier as a result of changes in the regulating grid voltage, which results from changes in the electrical conductivity of the photoelectric cell resulting from changes in the brightness of the Light source arise as a result of the mains voltage fluctuations.

The invention is shown in the drawing, for example, and although Fig. i is a circuit diagram according to the invention for a smoke indicator, Fig. Z a circuit diagram of a known system without actual voltage compensation.

According to Fig. I, a source includes electrical. he power conductors II and 12 to which the Primae nvichlung, 13 of a transformer 14 and the primary winding 1 5 .One second transformer are connected sixteenth In addition to the primary winding 13, the transformer 14 has: a core 17, a two-part main secondary winding 18 and: an auxiliary secondary winding 19, the purpose and effect of which will be described in more detail below.

The transformer 16 has in addition to the primary winding 1, a secondary winding 5 and a core 2 2o i. The secondary winding 2o expediently has several taps, the purpose of which will also be explained below.

A rectifier 22 is: electrically connected to the two terminals of the two-part Secondary winding 18 connected. The rectifier shown schematically has here two anodes and a single cathode to achieve full-wave rectification of the imposed To be able to achieve alternating current energy, which to the outer circuit between the rectifier cathode and Connection point of the two-part secondary winding is placed.

The photoelectric cell 23 is of the usual type, and it belongs to it a light permeable housing with an anode enclosed therein and Cathode. Since the particular design of the photoelectric cell does not form part of the invention an individual description does not appear to be necessary.

A three electrode booster tube 24 is also more conventional Type as developed for radio frequency messaging. The tube 24 has a thread 26, an anode 27 and a grid 28. The thread 26 is: electrical connected to and is fed by the auxiliary secondary winding i 9 of the transformer 14, via the connecting lines 29 and 3 i.

At 32 is a multi-section potentiometer resistor which is made up of three sections 33, 34 and 36. All these Sections are cascaded, and the outer terminal of the section 33 is connected to the cathode of rectifier 22 by a conductor 37. the outer terminal of section 36 is through: a conductor 38 to the connection point of the two parts of the secondary winding 18 connected-. A capacitor 39 is in parallel between the outer end of the resistor 33 and the connection point of the windings 18 placed in order to smooth the peaks in the rectified voltage waves of the rectifier occurs.

At 41 a grid impedance is shown; this has preferably a resistance of about 100 megohms. One terminal of the impedance is to the anode of the cell 23 and the other end connected by a conductor 42 to a desired one Point of resistance 34. The connection point between grid impedance 4i and anode the cell 23 is connected to the control grid 28.

The anode 27 is connected to the terminal 44 of the terminal pair by a conductor 43 44, 46 connected. If you want to have a circuit in addition to the facilities shown If you are using a recording device, you can connect it to terminals 44 and 46. If the device is not used, the terminals 44, -46 are connected by a Head connected.

The clamp 46 is through a conductor 47 with: a clamp. an electrical indicating instrument 48, the other terminal of which is connected to the outer terminal of the section 33 of the resistor 32. The cathode of the photoelectric cell 23 is connected by the conductor 49 to the outer terminal of the section 36 and thus also to the center point of the two parts of the secondary winding 18 by a conductor 38.

All the elements described so far, with the exception of the transformer 1 6 are expedient on a base plate 5 is fixed i, which may be made of electrically conductive material. The outer terminal of the section 36 of the resistor 32 is connected by a conductor 52 to the plate 5 i and by a conductor 53 to earth. With a housing 54 is referred to, in which not only the transformer 16, but also the light source 56 is housed, expediently a small incandescent lamp in a socket 57, the terminals by .ein pair of conductors with the terminals of the secondary winding 20 or better with his Terminal and are connected to a selected tap point. An opening 58 in the housing 54 allows the light from the filament of the lamp 56 to emerge from the housing and to hit the photoelectric cell 23.

Naturally, the base plate 5 i can form part of a housing, in which the elements cooperating with the photoelectric cell are housed are, while the housing 54 at a certain distance from the base plate or the housing 5 i is arranged.

A lens 61 associated with the lamp 56 and: a similar one Lens 62, which is assigned to the photoelectric cell 23, are used for collection and direction of the rays of radiant energy emitted by lamp 56 and which to fall on the photoelectric cell 23.

A conductor 63 is connected to a tap which is at the center point the auxiliary secondary winding i 9 is connected, and a ladder 64 connects the conductor 63 to the connection point of the resistor sections 33 and 34, 66 is a heating resistor for the filament 26 of the tube 24.

With circuits of this type it is possible that voltage fluctuations enter the feed circuit represented by conductors i i and 12, and the invention relates in particular to certain specified working conditions of different elements and parts of the system as well as their cooperation with the result, that smaller voltage fluctuations in the supply circuit relatively little or for at least a reduced effect on the readings of the indicating instrument 48 exercise or equivalent on the records in the event that a recording device is used.

In order to clearly distinguish the described system from such, in which there is no compensation for the voltage fluctuations, one is uncompensated System shown in Fig. 2. Essentially the same devices are provided, but the connections between the photosensitive cell and the other parts of the system are different. One terminal of the impedance 41 is connected to the cathode of the Cell 23 connected and the other adjustable by a conductor 67 to the resistor 34. The connection point between impedance 41 and cathode of cell 23 is through the conductor 68 in connection with the grid 28 of the tube 24. The anode of the cell 23 is by a conductor 69 to the connection point of the instrument 48 and the Resistor section Os 33 connected.

The elements of the system according to Fig. I are dimensioned so that a change the normally fully lit or excited state of the. photoelectric cell, d. H. of a 100% excitement, up to a state of complete darkness Voltage change of io volts in the grid bias caused by the grid impedance 41 is generated. To achieve this, the voltage drop is used of the resistor 32 consisting of several sections are composed of 100 volts between the terminals of resistor 33, 100 volts between the junction of resistors 33, 34 and the point of contact of conductor 42 and about 100 volts for the remaining part of resistors 34 and 36.

It may further be assumed that the voltage between the two thread clamps or preferably between a point in the middle between them, which is the conductor 63 , and the anode 27 is 100 volts, further that the voltage between the outer terminal of the grid resistor 4i and the center of thread 26 (represented by conductor 63) is io volts b - carries.

The total grid bias between grid 28 and the center of the Winding i 9 and thus to thread 2 6 is - i o - i o = -2o volts and settles together of the drop across the impedance 4i and the drop in that part of the resistance 34 between the connection point of the resistors 33, - 34 and the tap of the Head 42.

If here certain values of the different voltages in different Parts of the circuit are given, these are of course only for explanation and not given as a limitation. The exact values depend on the type of hot cathode tube and on the type of photoelectric cell.

It has been shown that with a circuit as shown in Fig. I, an essentially complete compensation for smaller voltage fluctuations can be achieved, ie the readings in the instrument q.8 will not change noticeably even if the voltage of the supply source changes by 30/0 , changes.

Such compensation occurs "for the following reasons: If that System is set in the manner described, the fluctuations in the anode voltage have stronger effects than the changes in the grid bias. If the supply voltage falls, the light intensity of the lamp 56 drops, and so does the excitation the light-sensitive cell also becomes smaller. The effects of the voltage changes at the grid and at the anode of the hot-cathode tube will be so that they the fluctuations balance on the grid as a result of the change in the excitation of the cell, which is from the change in the luminosity of the light source.

It has been found that with a circuit as shown in Fig. there is a 250/6 change in the readings of the instrument 48 when there is a 3% change in the voltage of the supply circuit. This lack In terms of compensation can be explained as follows: When the circle is in exactly the same Way has been set, as it is described above with respect to Fig. I, the Effect of the voltage fluctuation on the grid and on the anode of the hot cathode tube cause a decrease in the anode current because the effect of the anode voltage fluctuation is greater than the effect of the grid voltage fluctuations. The fluctuation the The light intensity of the lamp is, in percentage terms, four times the voltage fluctuation.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for - display or recording of changes in an amount that regulates the conductivity of a photoelectric Cell acts, the changes of which are amplified in a three-electrode tube, wherein photoelectric cell, cooperating light source and electrodes the amplification tube draw voltage from the same electrical network, thereby characterized, -that to compensate for the effects of voltage fluctuations of the Netzes "the photoelectric cell in the grid circle of the three: electrode reinforcement tube is in series with a grid bias impedance in parallel with a potential and connected to a source of negative potential greater than that Grid bias potential so that a change in the output of the amplifier due to changes in the anode voltage and the normal grid bias (as a result of changes in the mains voltage) of the same order of magnitude but opposite Polarity is like the change in the output of the amplifier as a result of changes in the regulating grid voltage, which results from changes in the electrical conductivity of the light, electric cell, which result from changes in brightness of the light source caused by these fluctuations in the mains voltage will. 2. Circuit arrangement according to claim i, characterized in that the Grid tension in relation to the anode and filament tension of the three-electrode tube is brought about that a change in the mains voltage, as a result of which the mentioned The voltages change in the same ratio to a change in the anode current which is of opposite polarity and equal to the change in the anode current, which is due to the change in the grid voltage, which in turn is due to the change in the excitation source of the photoelectric cell b: e is influenced. 3. Circuit arrangement according to claim i or 2, characterized in that one off multiple sections of potentiometer resistor from the same source is excited, which also feeds the light source, and at its ends the supply voltage is arranged in a manner known per se in such a way that @er voltage also Cathode-anode circuit of the three-electrode tube, further a negative voltage to the Grid bias resistor circuit and an even more negative voltage to that Circles three-electrode tube grid - photoelectric cell supplies.