RU172101U1 - Band filter - Google Patents

Abstract

The band-pass filter is designed to suppress out-of-band emissions in digital television transmitters of the decimeter range. The filter contains U-shaped 2n coaxial resonators 1, where n = 2, 3 or 4, which are electrically connected in series by means of inductive couplings 2. In this case, at least two adjacent resonators are connected by means of transverse coupling 3, all resonators are structurally identical and consist of an outer screen 4, a short circuit 5 with an annular contact 6 and made in the form of a hollow pipe of the Central conductor 7, mounted with the possibility of longitudinal movement in the contact. In this case, the hollow tube is closed at the open end of the resonator, and the communication loops of the first and last resonators are respectively input 8 and output 9 of the device. Each central conductor 7 is equipped with a sleeve 10 of heat-conducting material, located opposite the contact 6 of the short circuit. The outer diameter of the sleeve 10 is made on a sliding fit with the inner diameter of the conductor 7, the sleeve is provided with two holes 11 through which the evaporative ends of the first 12 and second 13 heat pipes are passed to ensure thermal contact with the sleeve. A cooling radiator 14 is installed on the condensation ends of the heat pipes outside the resonator 14. The filter can be additionally equipped with a fan 15. The technical result when implementing the claimed device is a decrease in the temperature instability of the frequency response of the filter and an increase in the power transmitted by the filter, due to a decrease in the temperature of the central conductors of the resonators. 1 s.p. f-ly, 7 ill.

Description

The utility model relates to communication technology, namely to band-pass filters, and can find application in high-power digital television transmitters of decimeter wavelength range (DVB-T2 standard).

The prior art bandpass filter on quarter-wave resonators with sequential and non-sequential connections between them according to patent EP No. 1258941 A3, designed for analog television broadcasting in the decimeter wave (UHF). The filter consists of 4 cylindrical central conductors placed in square screens. Each central conductor has a fixed part with contacts and a movable part driven by a steel rod. The central conductor in the screen forms a volumetric tunable resonator. All four resonators are U-shaped so that the first, input resonator is located next to the last, output resonator. The electrical connections between the resonators are made in the form of adjustable inductive coupling loops and adjustable capacitive probes. To increase the stability of the frequency response of the filter when changing the ambient temperature and signal power (thermal stability), the following techniques were used:

- the rods are made of INVAR alloy;

- the optimal ratio of the screen sizes to the diameter of the central conductor is selected in the resonator, while the overall dimensions of the resonators and the filter are significant;

- silver plated internal surfaces of the resonator.

In this design, despite the measures taken, the thermostability of the frequency response of the filter is not ensured.

The closest analogue of the proposed model is a band-pass filter according to US patent No. 8143973, consisting of an even number of 2n coaxial resonators, where n = 2, 3 or 4. The filter was specifically designed for analog and digital television broadcasting in the UHF range. The number of resonators 4, 6 or 8 is determined by the requirements for the selectivity of the filters put forward by the standards for broadcast television of analog and digital transmitters. For DVB-T2 digital transmitters with a critical mask [1], for example, a filter of 8 resonators is required. A 4-cavity filter is sufficient for an analog transmitter. Filters are available in separate sizes for each power level, for example 2.5 kW, 5 kW, 10 kW, and have an efficiency of about 90%.

The closest analogue can be built, for example, from six resonators. Each resonator has an external conductor (screen) and a cylindrical central conductor. These two conductors are connected at one end by a short circuit (cover), and the other end of the central conductor is free. The central conductor consists of a fixed and movable part, which for adjustment can be moved in contacts along its circumference. The lengths of the central conductors of the resonators are fixed after tuning with steel rods. For temperature stabilization of the frequency response, the rods are made of INVAR alloy. In resonators, measures have been taken to reduce the loss of the transmitted signal: optimization of the ratio of the screen and central conductor sizes, silvering and polishing of the internal surfaces. Frequency response with high selectivity is achieved by a U-shaped arrangement of resonators and electrical connections not only between sequential, but also between non-sequential resonators. Serial communications are made in the form of adjustable inductive loops. Inconsistent (transverse) connections are made between adjacent resonators and can be either inductive, for example, the first with the sixth, or capacitive (the second with the fifth).

In this design, the resonator elements (screen and center conductor) are heated unevenly. The central conductor heats up significantly higher than the screen, which does not allow for temperature stability of the frequency response of the filter (thermal stability). The overall dimensions and weights of the filter are also significant.

Standard [1] stipulates the basic requirements for the frequency characteristics of filters of digital television broadcasting transmitters: bandwidth of about 1% of the average operating frequency, slope steepness of the characteristic up to 150 dB / MHz, change in the frequency of points with a level of -3 dB on slopes of the characteristic not more than 110 kHz when the temperature of the filter changes.

The measurements showed that, with a transmitting signal power of several kilowatts, the moving central conductors and contacts in a filter of a similar design are heated 60-80 ° C higher than the screen. The ring contact area is most heated. From this overheating, the voltage of the onset of electric thermal breakdown of air in the resonators [2] and, therefore, the power transmitted by the filter are reduced by 20%. Temperature instability of the frequency response exceeds the permissible value of 2 kHz / deg. The challenge is to eliminate this overheating.

Today, to reduce overheating, maintain stability and filter power, firms are increasing the size of the central conductors and filters in general. The dimensions and cost of the filters make up a significant part of the transmitter. For example, a CTV / U / DVB6-5 filter [3] for a 5 kW transmitter weighs 58 kg with dimensions of 725 × 500 × 440 mm.

Thus, the technical task of the proposed model is to reduce the temperature instability of the frequency response and increase the power transmitted by the filter by lowering the temperature of the central conductors of the resonators while maintaining their mobility.

The problem is solved due to the fact that in the band-pass filter containing 2n coaxial resonators connected electrically in series and arranged U-shaped, at least two adjacent resonators are connected via transverse coupling, and all the resonators are structurally identical and consist of an external screen, a short circuit with an annular contact and made in the form of a hollow tube of a Central conductor installed with the possibility of longitudinal movement in the contact. In this case, the hollow tube is closed at the open end of the resonator, and the communication loops of the first and last resonators are the input and output of the device, respectively. Each central conductor is equipped with a sleeve of thermally conductive material, located opposite the contact of the short circuit, and the outer diameter of the sleeve is made on a sliding fit with the inner diameter of the conductor. The bushings are provided with two holes through which the evaporative ends of the heat pipes are passed to ensure thermal contact with the sleeve, and a cooling radiator is installed on the condensation ends of the heat pipes outside the resonator. This filter design solution is reliable for many years of operation.

The essence of the utility model is illustrated by drawings.

In FIG. 1 shows a band-pass filter (top view), in FIG. 2 is a side view with a section along AA of resonator screens, FIG. 3 shows a central section of the resonator conductor. In FIG. 4 is a photo of a heat-conducting sleeve with holes and heat pipes soldered into them; FIG. 5 is a photo of the center conductor in the ring contact of the short circuit. In FIG. 6 shows the actual frequency response of the bandpass filter, and FIG. 7 - photo of a real filter for transmitters with a power of 5 kW, six resonators, n = 3.

The band-pass filter contains U-shaped 2n coaxial resonators 1, where n = 2, 3 or 4. Consider the filter design using the example of a filter consisting of six resonators placed close to each other. The resonators are interconnected electrically in series by means of inductive loops 2, passed through common slots in the screens. In this case, the adjacent resonators (the first and sixth) are also connected by means of the transverse loop 3 of the inductive coupling, and the adjacent resonators (second and fifth) are connected by the transverse loop 3 of the combined inductive-capacitive coupling. All resonators are structurally identical. Each consists of an outer screen 4, a short circuit 5 with an annular contact 6 and made in the form of a hollow tube of the Central conductor 7. The Central conductor is mounted with the possibility of longitudinal movement in contact, while the hollow tube is closed at the open end of the resonator. A steel rod 16 made of Invar alloy with a small coefficient of thermal expansion is fixed to this end in the center axis axis. The force applied to the opposite end of this rod can move the conductor. The rod is attached by a latch 17 to the short-circuit breaker (cover) 5. The inductive coupling loops of the first and last resonators are designed to connect to the central conductors of the coaxial feeder paths to which the filter is connected. They are respectively input 8 and output 9 of the device.

Each hollow central conductor 7 is provided with a thick-walled sleeve 10 made of heat-conducting material, for example, copper, located opposite the contact 6 of the short-circuiting device 5. The outer diameter of the sleeve 10 is made on a sliding fit with the inner diameter of the conductor pipe, the sleeve is provided with two holes 11 parallel to its axis, through which evaporative the ends of the first 12 and second 13 heat pipes with one-piece thermal contact with the sleeve, for example by soldering. The heat pipes 12, 13 are fixed to the short-circuit breaker (cover) 5 by a clamp 18. On the opposite, condensing ends of the heat pipes, a cooling radiator 14 is installed outside the resonator. The radiator is made with two holes for heat-conducting connection with the heat pipes 12, 13 and a central hole for the rod 16. It is removable, and for this is cut along the axis of the holes into two halves. The halves are connected (screwed), the heat pipes are covered by the halves tightly through the grease with a heat-conducting paste, the rod passes through its gap with a gap. The band-pass filter is additionally equipped with a fan 15. The fan is mounted above the short-circuits (covers) of 5 resonators so that at the same time it cools (blew) and all cooling radiators 14 of the heat pipes 12, 13.

Before work, the bandpass filter is set up. In all resonators, heat-conducting sleeves 10 with soldered heat pipes 12, 13 are lowered along a sliding fit into the central conductors 7 to a position opposite the ring contacts 6 and are fixed to short-circuiting (covers) 5 by latches 18. Coaxial connectors input 8 and output 9 the filter is connected to the circuit with a propagating UHF signal from the device - measuring transmission coefficients S11 and S21. Loop conductors of consecutive 2 bonds and transverse 3 bonds provide input - output of energy in the filter - measuring line system. Choosing the lengths of the central conductors 7 with the rods 16 and immersing the loops 2, 3 in the resonators, using the known tuning techniques, they achieve the required frequency response (see Fig. 6). When setting up, each conductor 7 slides between the ring contact 6 and the sleeve 10. In the tuned position of the conductor 7, the rod 16 moving it is fixed by the latch 17. The radiators 14 are fixed through the heat-conducting paste to the heat pipes 12, 13 outside the resonator after adjustment.

The number of resonators is related to the type of required frequency response. A filter of six resonators, n = 3, implements a slope of about 100 dB / MHz (see Fig. 6), for a slope of 150 dB / MHz, n = 4 is necessary.

The number of heat pipes 12, 13 in the conductor 7 may be more than two. It is important that the design mechanically firmly holds the heat-conducting sleeve 10 and the radiator 14, and the total thermal resistance of the circuit from the serial connection of the ring contact 6, the wall of the hollow pipe 7, the gap between the hollow pipe and the heat-conducting sleeve 10, sleeve 10, heat pipes 12, 13 and the radiator 14 did not exceed 2 ° C / W. To do this, if necessary, the forced cooling fan 15 is turned on.

Configured in FIG. 6, the filter for operation is included in the coaxial path of the transmitter and performs its function of suppressing out-of-band emissions without any adjustments over the entire long-term life of the transmitter.

During operation of the filter as part of the transmitter, the thermal power of 30-40 W, which is released in contact 6 and the central conductor 7 of each resonator, is transmitted and dissipated by the radiators 14, the internal components of the resonators do not overheat with respect to short-circuits (covers) 5. Due to this, the proposed utility model of a band-pass filter has twice the temperature stability of the frequency response. Its overall dimensions are 570 mm × 380 mm × 375 mm, and the weight is 36 kg, which is 25% ÷ 40% less than the mentioned filter [3] and analogues of other companies. The developed filter (see Fig. 7) is implemented in a digital DVB-T2 television transmitter NEVA Ts5 with an average power of 5 kW.

Literature

1. Digital broadcast television. DVB-T / T2 digital terrestrial broadcasting equipment. Technical requirements. Main settings. Measurement Methods. GOST R55696, M., Standardinform, 2014

2. Afanasyev V.V. Air circuit breakers. Calculations and design. M., Energy, 1964, fig. 2-59.

3. WWW Sira . mi . it Sira catalogo_vhf_vhf 150218_bassa.pdf Sistemiradio, p. 37.

Claims (2)

1. A band-pass filter containing 2n coaxial resonators located U-shaped, where n = 2, 3 or 4, are connected electrically in series, while at least two adjacent resonators are connected through transverse coupling, all the resonators are structurally identical and consist of an external screen, a short-circuit with an annular contact and made in the form of a hollow tube of a central conductor installed with the possibility of longitudinal movement in contact, while the hollow tube is closed at the open end of the reson torus, and the communication loops of the first and last resonators are the input and output of the device, characterized in that each central conductor is equipped with a sleeve of heat-conducting material located opposite the contact of the short circuit, the outer diameter of the sleeve is made by sliding fit with the inner diameter of the conductor, the sleeve is equipped with two holes through which the evaporative ends of the first and second heat pipes are passed to ensure thermal contact with the sleeve, and at the condensation ends of the heat pipes Ub outside the resonator mounted radiator. 2. The band-pass filter according to claim 1, characterized in that it is additionally equipped with a fan.

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