DE1208415B - High frequency triode vacuum tube - Google Patents

Description

High Frequency Triode Vacuum Tube The invention relates to triode vacuum tubes with a dynamic characteristic curve for the VHF and television sectors, with one in the Indirectly heated cathode extending longitudinally of the tube, with one at a distance from the cathode arranged, consisting of a wire mesh control grid, with one extending in the longitudinal direction of the tube over the entire length of the cathode Anode with an active anode part opposite the control grid and with inactive ones Anode parts that are at a greater distance from the grid than the active anode part, and with shield electrodes between the inactive anode parts and the control grid, extending in the longitudinal direction of the tube over the entire length of the cathode, grid and anode and each with an end zone in alignment with the end zones of the active anode surfaces against those extending in the longitudinal direction of the tube Connect the edges of the active anode surfaces and connect to the cathode potential are. The purpose of the invention is to create a new triode construction in order to the overall gain and efficiency in high-frequency amplifier circuits raise.

Technical and commercial triodes have a significantly lower one internal resistance as tetrodes and pentodes. In tetrodes and pentodes is through the insertion of the screen grid greatly increased the internal resistance, so that at their Output connected high-frequency output circuits work optimally.

The considerable internal resistance of the screen grid tubes is reduced the efficiency or the general quality of high-frequency output circuits.

The internal resistance of tetrodes and pentodes is on the order of magnitude of a few hundred thousand ohms. In contrast, triodes have an internal resistance in the order of 1000 ohms and in special constructions a few at most ten thousand ohms. Therefore, a high efficiency or a high quality can all in one Triode high frequency output circuit does not reach a maximum value.

In a given electrode arrangement of a triode, the inner Resistance increased by reducing the capacitance between anode and control grid will.

Such an increase also increases the gain factor, p of the triode. In tetrodes and pentodes, the grid-anode capacitance is determined by the inserted screen grid completely reduced. In caseode circles, the second triode is used as a lattice base amplifier switched to achieve appropriate results. With pentodes and tetrodes Screen grid currents increase the noise curve of the tube, and therefore such tubes are inferior to triodes if the effect of the intoxication is important, such as for example when watching TV. For television voting groups, especially in the area from 54 to 216 MHz, the high internal resistance of tetrodes and pentodes cannot are always fully used as in steps of the high frequency band. With specially designed Triodes for simple high-frequency amplifier stages is the usable internal resistance about half to a third smaller than that for the highest efficiency required value.

The aim of the invention is to increase the capacitance between the anode and the control grid a triode in a new way in a ratio of 2 to 3: 1. The internal resistance of a triode should be so high that in an amplifier stage an overall effect is guaranteed that is similar to that of tetrode, pentode and cascode amplifiers etc. is comparable, while the negative conductance of is of the same order of magnitude.

The reduction in the interelectrode characteristic impedance between The anode and control grid increases the internal resistance of the triode and accordingly causes in an output circuit with high efficiency in connection with the tube better overall gain. This advantageous effect is intended for the subject matter of the invention without one Increase in the noise factor or a decrease in others advantageous characteristics of the triode can be achieved.

As is well known, a triode is essentially a diode in which A control electrode is inserted between the cathode and anode for the purpose of controlling the flow of electrons to control the anode. The control electrode is designed as a sieve or grid and thereby acts as an imperfect electrostatic screen. Usually the control grid acts at a negative potential with respect to the cathode and influences thereby the electron current passing through between the grid wires on his Way to the anode.

If the control potential is negative, practically no grid current flows, and the amplification of a triode is compared with a screen grid tube with a relatively low noise curve. The electron current reaching the anode is under the usual load-limiting conditions practically by the electrostatic Field determined between cathode and grid. As soon as the electrons pass through the grid they move very quickly to the anode, with space charge effects between grids and anode can be neglected.

The gain factor of a triode is determined by the constant ß. , u is a measure of the relative ineffectiveness of grid and anode voltage as a result the generation of electrostatic fields on the surface of the cathode and is consequently a measure of the grid effect of the control grid. The constant /, is determined by the geometric structure of the triode and is usually independent of the grid and Anode voltage.

The gain factor depends mainly on the structure and the Construction of the grid and is increased by everything the grid electrode causes more complete shielding of the cathode from the anode. Narrower The spacing of the grid wires or a larger diameter of the grid wires result accordingly a higher, ci-factor. Also an increase in the distance between the grid and anode causes an increase in the / -z factor. Commercially available ones suitable for high frequency amplifiers Triodes of previous designs have an Iz factor of around 5 to 100. It a triode has already been proposed, which consists of a cathode, a grid, consists of an anode and an auxiliary electrode in which the anode has two halves, which each have an indentation. However, this triode has an asymmetrical design on what creates inhomogeneous fields and stray currents.

In a triode described in more detail in the first paragraph, the invention characterized in that with a coaxial arrangement of the electrodes to each other the cathode and the control grid as a tube enclosing an anode essentially circular or elliptical closed cross-sectional line with two on opposite Make from this against the control grid protruding active anode surfaces with smaller radius of curvature than the inactive anode surfaces adjoining on both sides and that the screen electrodes over their entire surface both from the control grid as also have a constant distance from the inactive anode surfaces.

In other words, the shielding means cause a wider change the anode voltage for a given electrostatic change on the cathode surface, than would be required for the same triode without shielding means. The result is a higher gain or M-factor for the tube, as detailed below is set out. These shielding means also correspond to the inner one Triode resistance increased.

Details and exemplary embodiments are based on the drawing explained in more detail. In the drawing, F i g. 1 is a schematic representation of a practical form of a triode, F i g. 2 is a perspective view of the electrode arrangement according to FIG. 1, Fig. 3 is an elevation of a triode according to FIGS. 1 and 2, FIG. 4 shows a schematic representation of a further embodiment of a triode, F i G. 5 is a partial perspective view of the internal parts of a triode tube according to FIG F i g. 4th

In Fig. 1 shows a practical embodiment of a triode, which contains the essence of the invention. The triode 20 contains an evacuated one Glass bulb 21. In this bulb 21 are a generally cylindrical anode 22, a central tubular cathode 23 and a helically wound one Grid 24 arranged between the anode 22 and the cathode 23.

The anode arrangement contains two active anode surfaces 26, 26 directed towards the control grid 24 and the cathode 23. The radial distance between the active anode surfaces 25, 26 and the cathode 23 is smaller than that of the remaining anode surface. The anode assembly 22 is preferably made from two individual semi-cylindrical parts which are joined together along the seams 27, 28 by spot welding. The shielding means of the triode consist of two metallic cylinder sectors 30, 31 which are inserted between the inactive anode surfaces 32, 33 and the control grid 24. The radial distance of the curved shield members 30,31 is kept the same as that of the active anode surfaces 25, 26. The screen surfaces 30, 31 of the formation are of an electrostatic screen between the cathode 23 and the grid 24, in particular with respect to the said inactive anode surfaces 32 , 33. The screen surfaces 30, 31 restrict the electrostatic field between the entire anode surface 22 and the control electrode 24 and thereby restrict the emission of electrons from the cathode 23 and give more emitted electrons the direction from the surface of the cathode 23 to the active anode surfaces 25, 26.

The shielding surfaces 30, 31 are connected to the potential of the cathode 23. These screens 30, 31 are preferably connected to the base potential of the signal voltage or another corresponding potential in order to achieve the inventive effect. The electrostatic screens 30, 31 screen the control grid 24 and its carrier 34, 34 from the inactive surfaces 32, 33 of the anode arrangement 22.

F i g. FIG. 2 is a perspective view of the arrangement of the components of the FIG. 1 shown triode. The cylindrical cathode 23 is arranged coaxially in the tube, and the grid electrode 24 is helically wound around the supports 34, 34 (see FIG. 1). Fastening tabs 35 extend from each end of the anode assembly and are used for fastening by means of mica washers 36, 37 (Fig. 3) in the tube. Similar flaps 38, 33 extend from the shielding plates 30, 31 to Attachment to the mica plates 36, 37. F i g. 3 shows the mutual fastening arrangement the electrode parts of the vacuum tube in the eva- kuierten glass bulbs 21. Details of this arrangement tion are not shown, as such are known per se are. The upper fastening tabs 38 of the shielding plates 30, 31 are elec- trisch connected to a genuinely fine To achieve the potential of both plates. One of lower anode tab 35 is through a conductor 42 connected to a socket 41, which consists of the evacuated piston 21 leads out. Same is a lower tab 38 of the faceplates 30, 31 through a conductor 44 connected to a socket pin 43. The grid electrode 24 is connected by the conductor 45 the socket pin 46 connected. The cathode 23 is connected by the conductor 47 to the socket pin 43 bound. The heating for the cathode 23 is through connect the conductors 51, 52 with the socket pins 49, 50 bound. For the F i g. 1 to 3 is important that a important result of the triode according to the invention arrangement using shielding plates 30, 31 as set out. F = arin there is that the active Control effect, the active anode surfaces 25, 26 exert on the surface of the cathode 23 is weakened is, although it does not change the influence that Has continuous emitter 24 on the surface of the cathode 23. Therefore a: wider change of the anode Voltage required, 11111 dicwvl @ ov @ Plckl = rostatic Alteration part: T; _t111 to reach -F719 c12, -, @ i # r cathode 23, than with an identical triode: without the plates '1 (), 31 would be reached. Dci factor, i, <is defined as Quctiont at constant anode current 1 i ,. He, and E ,. are glass Ai3eci% ii- and the grid: rpctenttial. , c, is effectively a N ', a Mir eire kl; @ine A i1C'en'iln` e .-- er c a @@ Ja ° n @ pallillü "i, J, the ci'rorrzi'licli is, do a cc-level el;: '-, ti-ostatisclie A nderuw tili dc1 'litaile @ l ° @ zil E'rG @? Igen, die: der- those of Pedingurg c: üiwv constant anode Change dci- am Lattice lie @ -eticeil @@@ a r >>i; ai ^ iq'üvalcl; is. p is therefore the cafcktive @ Jet'stiir.unasftikt @: r the tube. iNenn the Schirin plates 30, 3 @ for these considerations required d egg erllölien, so darmis follows, as the ß p-factor of the Rölirä 20 due to the electrostatic Shielding sheets 30, 31 is increased. With deal symbol i '"the inner resistance is one workcwli Ti ° iode b @@ zicl # lla. The inner resistance is a function of the effect of dE ;, .find der Effect;? It caniit contiguous anode Stromes you ,. The relationship is: rp = j "v at kcnst; inter grid tension. If inside the tube fol`e shielding plates 30, 31 have a stronger change of the anode potential is necessary to the to bring about the same relief of the anode current, so the internal resistance rp is correspondingly elevated. It was practically established that the inner Resistance rp as well as the amplification factor, ic at triodes constructed in this way with built-in decorated active anode surfaces (corresponding to 25, 26) and shielding plates (corresponding to 30, 31) for shielding shielding of the inactive anode surfaces (according to 32, 33) practically two to three times the value were increased compared to unshielded triodes. Such higher gain and the higher anode resistance of the triode are not increased noise curve added, since no current through the shielding plates lying at the signal base potential 30, 31 flows. Even when using the tube in a high-frequency tuning circuit is the overall quality and the efficiency and also the resulting resulting high frequency gain is higher. As a result of the active parts of the anode assembly 22, in particular the surfaces 25. 26 as parts of the whole Anode assembly 22 are rigidity and lack of Microphone effect ensured. In other words: While advantageously maintaining the previous one Volume of the glass bulb 21 is the anode arrangement tion 22 is much wider than the required union active anode surfaces 25, 26 and gives the mounted between the glimmer plates 36, 37 Anode electrode rigidity. The anode assembly 22 Also grants adequate heat radiation surfaces, mainly for the heat generated by the Anode current if the tube is in normal high frequency circles is used. With weak input signals, especially in the The order of magnitude of microvolts is a microphone effect stability are important factors that depend on the according to the inventive arrangement are delivered. at strong input signals, of the order of Volts, with a relatively higher required current the inactive anode surfaces or F1ügen132,33 act adequate heat radiation. F i g. 4 ?. and 5 show a variant of the E'lek trodenanordniiAig of the triode, where i = n basic crack elliptical shape is applied in1 difference for 1 = rice-like arrangement in a ° _r triplet, according to the F i Q. 1 to 3. The triode 60 comprises a h @ ilPi; ei # glass flask 61, in which a ° elllptisviie Anode assembly 62 with reduced active anode share 63, 64 with the inactive anode parts 65, 66 included the central axis of the tube 60. The central cathode 67 is of generally legal angular shape and lies in its longitudinal direction in the Longitudinal axis of the elliptical anode 62. The control grid 68 is elliptical an2eorcnet and the elliptical shape of the anode 62, like from Fig. 4 and 5 can be seen. The support pins 69, 69 keep. the grid 63 upright in a helical shape. the Shielding parts 729, 71 are elliptical segments and extend against the inactive anode parts 65,66. The shielding plates 70, 71 run parallel with it the inactive anode parts 65, 66 and others include irin their end zones against the active anode parts 63, 64 to provide effective electrostatic shielding between the grid electrode 68 and the inactive ones To achieve anode parts 6s, 66, as is also the case with the F i g. 1 to 3 was the case. The improved Gain factor and the increased internal resistance stand of the triode 60 are finitely comparable to those that the shielding means of the tube 20 are almost identical Have given reflections and of the same kind.

Claims (1)

Claim: Triode vacuum tube with dynamic characteristic for the VHF and television range, with an indirectly heated cathode extending in the longitudinal direction of the tube, with a wire mesh control grid arranged at a distance from the cathode, with one in the longitudinal direction of the tube over the entire length of the cathode extending anode with an active anode part opposite the control grid and with inactive anode parts that are at a greater distance from the grid than the active anode part, and with screen electrodes between the inactive anode parts and the control grid, which extend in the longitudinal direction of the The tubes extend over the entire length of the cathode, grid and anode and each of which is connected to the cathode potential with an end zone in line with the end zones of the active anode surfaces against the edges of the active anode surfaces extending in the longitudinal direction of the tube and connected to the cathode potential. mark t that with a coaxial arrangement of the electrodes to one another, the anode (22) surrounding the cathode and the control grid as a tube has an essentially circular or elliptical closed cross-sectional line with two active anode surfaces (25,26) projecting from this at opposite points towards the control grid with a smaller radius of curvature than the inactive anode surfaces (32, 33) adjoining on both sides and that the screen electrodes have a constant distance over their entire surface both from the control grid and from the inactive anode surfaces. Documents considered: German Patent No. 933 465; U.S. Patent Nos. 2146 016, 2,615,138; "Valvo Reports", Vol. 111, 1957, Issue 4, pp. 182 to 187. Older patents considered: German Patent No. 1081975.