CS201771B1 - Rezonators of outlet circuits of the tube amplifier with electromagnetic linkage - Google Patents

Description

(54) Output Magnetic Coupling Resonators of Electron Amplifier Circuits ElectroThe present invention relates to resonators of electronic amplifier coupled electronic circuit amplifier output circuits for use in power amplifiers of television, repeater and other transmitters transmitting broadband RF frequencies.

The output circuits of these RF amplifiers are most often realized as two, less than three capacitively coupled resonant circuits. Their disadvantage is manifested on the lowest radio frequency channels, where the necessary transmission width for example for television purposes reaches 20 to 40% of the carrier frequency. For the transmission of this relatively wide bandwidth, a large coupling capacitance is required, which adversely affects a capacitor connected in parallel to the anode working resistor, as this reduces both the RF output power and the gain of the amplifier. In such conditions, it is preferable to use a magnetic coupling that does not cause this decrease in output power. However, the realization of variable magnetic coupling is more demanding in terms of production and the more difficult it is to miniaturize the amplifier dimensions.

These drawbacks are overcome with resonators of the output circuits of the tube amplifiers solved according to the invention.

The subject of the invention is resonators of output electron amplifiers with electro201771 magnetic coupling, controlled by the electric component of mutual field, which are formed by a part of one or more parallel open-ended high-frequency lines to which a resonant capacitor is connected, optionally directly via an anode tube capacitor. the end is short-circuited directly or via a decoupling capacitor, characterized in that the internal conductors of the at least one coupled pair of resonators are fixed in a common conductive housing consisting of a base plate and an amplifier outer housing in which they are arranged equidistantly in straight, circular and helical shapes; combinations of these, which connect the short-circuit ends with their resonant capacitors or the anode of the tube, so that the capacitors together with the anode are located on one side an electrically conductive thin-walled shielding is inserted into the mutual field of the inner conductors, which on one side is connected directly or via a separating capacitor either to the base plate or to the outer shell, while on the opposite side it is insulated.

The principle of the invention consists in that the inner conductors of at least one coupled pair of resonators are fixed in a common conductive cover, which consists of a base plate and an outer

Live jacket of amplifier acting as external conductor common for both resonators. These inner conductors are equidistantly arranged in straight, circular and helical shapes or in any combination thereof, which means here that the same distance between the resonator sections is always maintained between them regardless of whether their axes are straight lines or curves placed in a plane or in space. The internal conductors further connect their short-circuit ends to their resonant capacitors and, at the input resonator, also to the tube anode so that these capacitors and the anode are located side by side on the one side of the resonators. An electrically conductive thin-walled shielding is inserted into the mutual field of the inner conductors, which on one side is connected directly or via a separating capacitor either to the base plate or to the outer housing, while on the opposite side it is insulated.

Here, the decoupling capacitor is intended to separate the uniform potential required for powering the electronics from the high frequency, which can be achieved by a suitable amount of capacitance, whose reactance in the field of transmitted frequencies is negligibly small. Therefore, it is most often used in the implementation of anode resonators, where it is connected in series to the internal conductor either at the anode of the electronics or at its short-circuit end.

The physical nature of the invention can be illustrated by the example of two adjacent resonators whose axes are parallel and the common wall of the outer conductors is removed between them. The resulting pair of resonators has a single common outer conductor and is bound by an electromagnetic field formed between their inner conductors. If both resonators are oriented so that their resonant capacitors are located on the same side of the inner conductors and on the opposite side are their shorts, then the voltage induced on the adjacent resonator by the magnetic component is opposite to the voltage induced by the electric component of the same mutual field. Due to the shortening of the electrical length of the resonator by the resonant capacitors relative to a quarter wavelength and also due to the choice of a small value of the wavelength between the internal conductors relative to the wavelength of the resonator itself, the magnetic component is reliably larger than the electrical component. The resulting coupling of the pair is proportional to the difference of the induced voltages from the two named components. Thus, if the relative electrical component is reduced relative to the magnetic component, the degree of mutual coupling increases and vice versa. It will also be appreciated that this physical phenomenon will be retained, even though the inner conductors are not routed only in straight sections, but are arbitrarily shaped similarly to planar or spatial curves that maintain the same distance over a certain section.

Compared to a purely capacitive coupling whose degree increases as the field strength increases, it is apparent that the new method of controlling the electromagnetic coupling has the opposite effect.

If the coupled pair is applied to the output circuits of the tube amplifiers, its first resonator, which is connected to the tube anode, forms an anode circuit, and the second to which the coaxial output line is connected directly or via a capacitor to produce an amplified signal circuit. In the case of a plurality of resonators, a cascade of coupled pairs is formed, the first resonator being connected to the anode of the vacuum tube and the last signal being discharged through the coaxial line.

The parallel connection of multiple resonators is used at high frequencies, where the power tube greatly reduces its length due to its large dispersion capacity. In order to evenly distribute the circulation currents on the electrode ring terminals, the parallel connection of the resonators is made just opposite one another. The opposite ends of their inner conductors shall be short-circuited with the common outer conductor symmetrically to the axis of the electronic tube. Similarly, the output circuit is made by connecting two resonators in parallel to a common resonant capacitor. The array of resonant capacitors and vacuum tube is then located in the middle of the parallel connected resonator pairs.

The highest degree of coupling of a pair of resonators is best achieved by inserting the conductive shield between the open ends of the resonators, which are connected to the resonant capacitors or the anode of the tube, since the intensity of the electrical component of the mutual field is greatest. The tuning of the resonators will not be affected if the electrical and magnetic components of the mutual field do not change. In practice, this can be achieved when the shape of the shield merges with the zero equipotential surface of the electric field, when the shield is negligibly thin and its surface is divided into strips imitating the Faraday cage.

Shielding shapes can be divided into the following types:

In the first case, the shielding is part of a cylindrical shell whose axis is parallel to the axes of the inner conductors of the straight section at the open end of the resonators. In the latter case, it is in the shape of a segment of the rotating body whose axis is identical to the axis of rotation of the inner conductor profiles from which the circular sections are formed. In the third case, it is in the form of a portion of the cylinder movable coaxially between the helices of the inner conductors. In the fourth case, it is part of the plate rotatable parallel to the planes in which the axes of the inner conductors forming the straight or circular sections lie. In the fifth case, part of the thin wall is displaceable along the axes of the inner conductors of the straight sections at the open end of the resonators. Optionally, to enhance the screening effect, the shield edges are provided as parts of flanges of suitable profiles or shaped as canopies or arches.

The latter method of controlling the electrical component is based on reducing the capacitance coupling of the resonant capacitor of the output circuit with a hinged or hinged plate coupled to the anode of the tube, which is used when the anode resonator is greatly shortened by the large dispersion capacity of the tube.

The progress of the invention is evident in amplifying a wide bandwidth by allowing to achieve the same output power and gain of an amplifier as with magnetically coupled circuits, and the degree of coupling can be easily changed without changing the position of the internal conductors. The losses incurred are the same as for the capacity coupling. By guiding the inner conductors equidistantly along each other and with the same orientation of their open and short ends, a high degree of coupling can be achieved without difficulty, even though the resonators are considerably shortened, since this shortening does not affect that part of the resonators where By varying the position of the shield, it is common to achieve a ratio of the greatest and the lowest bandwidth of 1: 2 or more. Since the internal conductors of the resonators still retain their original position, they can easily fill the amplifier space for miniaturization, kinking straight sections, or twisting into arcs and helices. Substitution of individual resonator shells with a common outer cover, which has no partitions, contributes substantially to this. These circumstances reduce manufacturing effort, make the amplifier compartment available to take out the vacuum tube for cooling air in and out, and facilitate handling during maintenance and repair of equipment.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be explained in more detail with reference to the drawings, in which in FIG. 1 is a plan view taken along line C-D in FIG. 2 of a first exemplary embodiment of a pair of resonators of the output circuits of an electromagnetic coupled tube amplifier. Fig. 2 is a plan view taken along line A-B in Fig. 1. Fig. 3 is a plan view of a second embodiment. Fig. 4 is a third exemplary embodiment in plan view. Fig. 5 is a fourth embodiment in side view. A fifth exemplary embodiment is shown in FIG. 6 in a cross-sectional view along the plane G-H of FIG. 7 and in FIG. 7 in a plan view taken along the E-F plane of FIG. 6. FIG. 8 is a sixth exemplary embodiment in plan view.

In all embodiments, a single pair of coupled resonators is used for the output circuits of the tube amplifiers, consisting of a common outer conductor formed by the motherboard 3 and a portion of the conductive housing 4 of the amplifier, and inner conductors 1 and 2. Directly conductively or via a decoupling capacitor with an anode 7 of the tube, optionally with a resonant capacitor

5. The short-circuit end 8 is connected directly or via a separating capacitor to the amplifier base plate 3 or housing 4. Similarly, at the open end of the second resonator, the inner conductor 2 is connected to its resonant capacitor 6 and its short-circuit end 9 to the base plate 3 or the amplifier housing 4. At any point of the inner conductor 2, an inner conductor of the coaxial conduit 17 is connected via a movable coupling or capacitor, through which the amplified RF signal is sent. From each figure, it is clearly evident that the array of anode tube radiator has a resonant capacitor 6 of another circuit, and possibly with its own resonant capacitor 5 on one side of the resonators. 3, 4, 5, 6, the respective electrical shields 11, 12, 13 and 14 are inserted between the inner conductors 1 and 2 up to their open end where the intensity of the electrical component of the mutual field is greatest. As a result, the bond of the pair is greatest. When these shields are pulled out of this position, the mutual electrical component is restored and the coupling is reduced. An exception is the screen 10, from the first exemplary embodiment, which is only half inserted between the inner conductors 1, 2.

The first example in Figs. 1, 2 uses only straight sections of the inner conductors 1, 2, which form conductive cylinders with mutually parallel axes. The short-circuit ends 8, 9 are provided with flanges which are directly conductively fastened to the ceiling wall of the amplifier housing 4. The movable short circuit 18 is common to the two inner conductors 1, 2 and is realized by a plate parallel to the amplifier base plate 3, on which there are rims and rows of shear contacts ensuring their conductive connection with the amplifier housing 4. The tube anode 7 is also connected via a shear contact ring to an inner cylinder coaxially located in the inner conductor cylinder 1. The two cylinders are insulated from each other by a dielectric 15 to form a decoupling capacitor allowing application of the supply voltage to the tube anode 7. The resonant capacitor 5 of the anode resonators is omitted. The resonant capacitor stator 6 is of the coaxial type and its rotor is connected to the base plate 3. The conductive electrical shield 10 is realized by half of a cylindrical sheath whose axis is parallel to the axis of the inner conductors 1, 2. Its surface is divided into strips parallel to the its axle and its lower edge is provided with a flange pressed by two fastening screws to the base plate 3. This provides a direct conductive connection to the external common conductor.

In the embodiment of Figs. 1, 2, the axis of the anode tube radiator is identical to that of the inner conductor 1, but for ease of removal of the tube, another variant is possible in which these axes are perpendicular to each other.

A second embodiment of FIG. 3 uses circular inner conductors 1, 2. Their short-circuit ends 8, 9 are connected as fixed couplings to the base plate 3. Resonant; the anode resonator capacitor 5 is also omitted here and only the tube anode 7 is connected to the inner conductor 1 via a decoupling capacitor. The tuning of the anode resonators is accomplished by a movable short-circuit 19 which contacts the shear contacts of the surface of the inner conductor 1. These contacts are fastened to a movable arm pointing towards a common pin located in the axis of rotation. Here, shear contacts are provided for the conductive connection of the movable short-circuit 19 to the base plate 3. An adjustable short-circuit 20 is fastened to the inner conductor 2. Between the inner conductors 1 and 2 is shielded 11 forming a segment of the rotating body. as for the circular sections of the inner conductors 1, 2. The bottom of the shield 11 is arranged similarly to the circular sector so that a pivot bearing can be inserted therein. It is provided with shear contacts for conductive connection to the base plate 3.

The third embodiment of FIG. 4 has internal conductors provided in coaxial helices which are fixed by insulating ridges. The smallest diameter of the helical section has an inner conductor 1 which, with its open end, is connected to the anode 7 of the tube and at the same time to the resonant capacitor 5. Its short-circuit end 8 is connected to the separating capacitor plate. 16. The larger helix diameter has an inner conductor 2, which is short-circuited with its short-circuit end 9 connected directly to the rear wall of the sheath 4. At the opposite end, a resonant capacitor 6 is connected. placed in a row side by side. The cylinder-shaped shield 12 has its axis identical to the helices of the two inner conductors 1, 2.

The fourth embodiment of FIG. 5 has three straight sections of inner conductors 1, 2 whose axes lie in two parallel planes in which they are perpendicular to each other. In addition, a quarter of a circular section is inserted between the straight section at the open end of the resonators and the next straight section. The inner conductor 1 is connected conductively to the anode 7 of the tube and its short-circuiting end 8 provided with a flange to the separation capacitor plate. The second electrode of the separating capacitor is formed by the base plate 3 and the side wall of the housing 4 and is separated by a dielectric 16. The inner conductor 2 is again connected directly to the base plate 3 by its short flange 9 and its opposite end to its An adjustable short-circuit 20 moves along it. The shielding 13 forms part of a plate that rotates in a plane parallel to the axes of the inner conductors 1, 2 and extends therebetween.

A fifth exemplary embodiment is illustrated in FIGS. 6, 7. It uses two resonator pairs connected in parallel. The inner conductors 1, 2 are formed by a strip guided above the amplifier base plate 3. Both passports have their longer edges parallel and on both opposite sides are short-circuit ends 8, 9 provided with fixed couplings directly connected to the amplifier base plate 3. In the middle of the anode waist, a hole for a flange carrying sliding contacts that cut into the lead anode of the vacuum tube is cut. Between the flange and the waist of the inner conductor 1 there is a dielectric 15 to form a decoupling capacitor. On the left edge of the inner conductor waist 1, a resonant capacitor 5 is connected symmetrically to the opposite short-circuit ends 8, which serves to fine-tune the resonators. Similarly, the stator of the resonant capacitors 6 is connected symmetrically to the opposite short-circuit ends 9, the waist edges of the two inner conductors 1, 2 being parallel to each other. The inner conductor 1 is provided with symmetrically displaceable short circuits 19 by which the anode resonator can be tuned roughly. FIG. 7 shows an array of anode tube 7 and resonant capacitors 5, 6 side by side on a single side of parallel connected resonators. The thin-walled shield 14 with a canopy parallel to the waist edges is inserted between the inner conductors 1, 2. The resonator coupling can be reduced by shifting the shield 12 from the plotted position on either side to the short-circuit ends 8, 9.

In Fig. 8 there is an arrangement with three straight sections of inner conductors 1, 2, but the axis of the tube is perpendicular to the planes interspersed with the axes of inner conductors 1, 2. To control the intensity of the electric component of the mutual field, a capacitor 21 is used. the resistor capacitor 6 and the second realized movable plate connected via shear contacts to the inner conductor 1. If the capacitance of this capacitor 21 decreases, the intensity of the electrical component decreases and thus the coupling of the pair of resonators increases and vice versa. A thin shielding wall 14 interposed between the inner conductors 1 and 2 disturbs the electrical component of the mutual field.

The output circuits of the tube amplifiers according to the invention are not limited to the examples given, but can also be extended to double-acting amplifiers. In this case, there are at least two or more resonator pairs which are connected together at the short-circuit ends of the internal conductors. Since an electric short circuit is created automatically by the action of a double-acting amplifier on such connected resonators, its mechanical realization is usually omitted. Then, the composite pair of resonators at each end of the inner conductor has a tube anode connected, possibly with a fine-tuning capacitor, or only the resonant capacitor of the output resonators. Again, the inner conductors of the coupled pair are guided equidistantly in a common outer housing in straight, circular and helical sections sequentially arranged one after the other. This results in U-shaped straight sections or O-shaped circular sections in turn. A special formation is developed from the sixth embodiment of FIGS. 6, 7 by attaching the bench-shaped inner conductor bands to their mirror images. This results in a formation whose projection to the front is a horizontal rectangle, on whose other sides resonant capacitors are connected in the middle and possibly double-acting tubes.

Claims (7)

OBJECT OF THE INVENTION CLAIMS 1. Resonators for output circuits of electronically coupled amplifier tubes controlled by an electrical component of a mutual field, which are formed by part of one or more parallel connected high-frequency lines with one open con. to which a resonant capacitor is connected, optionally directly via an anode tube capacitor, while the opposite end is shorted directly or via a capacitor separator, characterized in that the inner conductors (1, 2) of at least one coupled pair of resonators are fixed in a common conductive a housing consisting of a base plate (3) and an outer housing (4) of an amplifier in which they are arranged equidistantly in straight, circular and helical shapes or in combinations thereof that connect the short-circuit ends (8, 9) with their resonant capacitors (5, 6) optionally with an anode (7) of the tube, such that the capacitors (5, 6) together with the anode (7) are placed on one side next to each other, and an electrically conductive thin-film shield is inserted into the mutual field of the inner conductors (1, 2). a casing which is connected either directly or via a decoupling capacitor either the base plate (3) or to the outer shell (4), while the opposite is insulated. 2. The resonators of the output amplifier tubes of claim 1, wherein the shield is part of a cylindrical sheath (10) whose axis is parallel to the axes of the inner conductors (1, 2) forming a straight section at the open end of the resonators. 10) is optionally provided at least as part of a flange of a suitable profile. 3. Resonators of the output circuits of the tube amplifiers according to claim 1, characterized in that the shielding is in the form of a segment of a rotating body (11) whose axis is identical to the axis of rotation of the inner conductor profiles (1, 2). 4. The resonators of the output circuits of the tube amplifiers according to claim 1, characterized in that the shield is in the form of a part of a cylinder (12) movable coaxially between the helices of the inner conductors (1, 2). 5. The resonators of the output amplifier tubes of claim 1, wherein the shield is in the form of a portion of the plate (13) rotatable parallel to the planes in which the axes of the inner conductors (1, 2) of the straight and circular sections lie. ) is optionally shaped as a canopy or arch. 6. The resonators of the output amplifiers of the tube amplifiers according to claim 1, characterized in that the shield is in the form of a thin wall (14) movable parallel along the axes of the inner conductors (1, 2) forming a straight section at the open end of the resonators. ) is optionally shaped as a canopy or arch. 7. The tube amplifier output circuit resonators according to claim 1, wherein the resonant capacitor (6) of the output circuit of the pair of resonators is capacitively coupled to at least one turntable (21) connected to the anode (7) of the tube.