RU202250U1 - WIRELESS MODEM - Google Patents

Abstract

The utility model is a device intended for use in aeronautical satellite communication systems with steerable antennas. A wireless modem can be used as an onboard aviation modem as part of a mobile (airborne) satellite communications station, including, in particular, a receiver (operating, for example, in the radio wave range from 10.95 to 12.75 GHz) and a transmitter (operating, for example, in the range of radio waves from 13.75 to 14.5 GHz), a controllable transmit-receive antenna, a control system for a transmit-receive antenna. When using the claimed utility model, a technical result is provided, which consists in ensuring the possibility of using a wireless modem as an on-board aviation modem by increasing resistance to external physical influences, in particular to external electromagnetic radiation, changes in temperature, pressure, ambient humidity, mechanical shock, vibration , accelerations, as well as due to the simultaneous reduction of the level of its own electromagnetic radiation of the wireless modem. A wireless modem containing a modem card, a power management device and a computing module installed in a first housing formed by the base and also by the first and second covers, indicator lights, and a second housing housing the first housing. As a modem board, a satellite modem board is used, in the first case between the base and the board of the computing module and the board of the power control device, which are planarly placed relative to each other, a plate with resistive electric heaters fixed in its slots is installed, the satellite modem board is placed between the second cover and the base, which is made heat-conducting and is in thermal contact with the satellite modem board, the plate and a half-open second casing, on which a radiator casing equipped with heat dissipating elements is installed on its open side, ensuring its electrical contact with the second casing. 5 p.p. f-ly, 6 dwg

Description

A wireless modem is a device designed for use in aeronautical satellite communications systems with steerable antennas. The wireless modem can be used as an onboard aircraft modem as part of a mobile (airborne) satellite communication station, including, in particular, a receiver (operating, for example, in the radio wave range from 10.95 to 12.75 GHz) and a transmitter (operating, for example, in the range of radio waves from 13.75 to 14.5 GHz), a controllable transmit-receive antenna, a control system for a transmit-receive antenna.

Known wireless modular modem (US patent No. 9380357, CL. H04M 1/00, op. 06/28/2016), containing a supporting base, on which the modem module (in a case equipped with a cooling radiator in the form of fins) and a network module are fixed with screws access. The supporting base with the elements installed on it is placed in an outer casing with a hinged cover.

The disadvantage of the known device is the presence of the problem, which consists in the impossibility of using the known device as an on-board aviation modem due to its insufficient resistance to external physical influences such as, for example: electromagnetic radiation; changes in temperature, pressure, humidity of the environment; mechanical shock, vibration, acceleration. At the same time, the known device is characterized by a too high level of its own electromagnetic radiation into the external space.

Closest to the claimed is a wireless modem (US patent No. 6026119, CL H04B 1/38, op. 02/15/2000), containing a modem board, a power control device installed in a first case, including a base, first and second covers, and a computing module, a group of light indicators and a second building.

The disadvantage of the known device is the presence of the problem, which consists in the impossibility of using the known device as an on-board aviation modem due to its insufficient resistance to external physical influences such as, for example: electromagnetic radiation; changes in temperature, pressure, humidity of the environment; mechanical shock, vibration, acceleration. At the same time, the known device is characterized by a too high level of its own electromagnetic radiation into the external space. The presence of this problem is determined by the fact that complex requirements are imposed on the on-board aviation equipment to ensure the possibility of its functioning under conditions of constantly changing physical parameters of the environment in flight. Such requirements are set forth, for example, in a regulatory document: Qualification requirements KT-160D "Operating and environmental conditions for airborne aviation equipment (External influences) Requirements, standards and test methods", published by the Aviation Register of the International Aviation Committee - ARMAK, 2004. , 324 p.

When using the claimed utility model, a technical result is provided, which consists in providing the possibility of using a wireless modem as an on-board aviation modem by increasing resistance to external physical influences, in particular, to external electromagnetic radiation, changes in temperature, pressure, ambient humidity, mechanical shock, vibration, acceleration, as well as by simultaneously reducing the level of its own electromagnetic radiation of the wireless modem.

The specified technical result is achieved in that a wireless modem containing a modem board, a power control device and a computing module installed in the first housing formed by the base, as well as the first and second covers, light indicators and a second housing containing the first housing, which differs the fact that a satellite modem board is used as a modem board, a plate with resistive electric heaters fixed in its slots is installed in the first case between the base and the computational module board and the power control board, which are planarly placed relative to each other, the satellite modem board is placed between the second cover and the base , which is thermally conductive and is in thermal contact with the satellite modem board, the plate and a half-open second housing, on which a radiator housing equipped with heat dissipating elements is installed on its open side, providing its electrical connection clock with the second body.

The specified result is achieved, in particular, in that the radiator case is provided with a cover, and through ventilation holes are made in the opposite side walls of the radiator case, which are equipped with electric fans connected to the output of the power control device board. The heat dissipating elements of the radiator housing, in particular, can be made in the form of a finned radiator. The first and second covers, the plate, the base, the second housing, and the radiator housing, in particular, are made of a deformable nickel-plated aluminum alloy. In this case, a groove can be formed in the end part of the side walls of the second housing along its perimeter, in which an elastic conductive gasket can be installed, which, in particular, can be made of an electrically conductive silicone elastomer.

The drawings show the construction of a wireless modem.

FIG. 1 shows a general view of the assembled wireless modem (axonometric projection).

FIG. 2 shows a spatial diagram of the arrangement of wireless modem elements related to the first housing and its contents.

FIG. 3 shows a spatial diagram of the arrangement of the wireless modem elements related to the second housing and the heatsink housing.

FIG. 4 shows a general view of a wireless modem assembled with a removed wall of the second housing and local sections.

FIG. 5 shows a general view of a wireless modem with the second housing removed (axonometric projection).

FIG. 6 shows a general electrical block diagram of a wireless modem.

Implementation of the utility model

The wireless modem contains the first housing 1 (Fig. 5), formed (as shown in Fig. 2) by the base 2, the plate 8, as well as the first 3 and second 4 covers. In the first housing 1, a satellite modem board 5 is installed (Fig. 2), a power control device board 6 and a computing module board 7 are planarly placed relative to each other. As a satellite modem card 5, for example, a UHP-210 open-frame satellite modem card can be used (see the publication: http://www.eastar.ru/products/hardware/UHP-210/).

Boards 6 and 7 can be made, in particular, by printed wiring.

In the first housing 1, between the base 2 and the board 7 of the computing module and the board 6 of the power control device, which are planarly placed relative to each other, there is a plate 8 made of D16 aluminum alloy with resistive electric heaters (hereinafter, heaters) 10 fixed in its recesses 9 on electrical insulating substrates, 11, 12 and 13 (Figs. 2, 4, 6).

The satellite modem board 5 is located between the second cover 4 and the base 2, which is thermally conductive and is in thermal contact with the satellite modem board 5, plate 8 and the second body 14 half-open on one side (Figs. 1, 3, 4), in the cavity of which the first housing 1 is installed. Thermal contact between these elements is ensured due to the fact that a heat-conducting paste is applied on their surfaces at the interface between them.

The guaranteed thermal contact of the base 2 with the second body 14 can be provided, in particular, by the fact that the base 2 is provided with projections 15 made with the possibility of mating by means of screws 33 when assembling the wireless modem with the counter projections 16 of the second body 14 through the supports 43 (Fig. 3 , 4, 5).

On the second housing 14, from its open side, a housing-radiator 19 equipped with heat-dissipating elements 17 and, in the particular case, a cover 18, is installed. The heat-dissipating elements 17 mounted on the housing-radiator 19 can be made, in particular, in the form of a finned heatsink (as shown in Fig. 3). Moreover, these heat dissipating elements 17 can be made, for example, as a whole with a radiator housing 19 (for example, by casting, milling from a solid workpiece or by 3D printing) or can be made as a separate block by any of the indicated methods with subsequent installation such a block in the housing-radiator 19 with the condition of ensuring reliable thermal contact between them. In both cases, the heat dissipating elements 17 can be made, in particular, of an aluminum alloy D16.

In this case, a reliable electrical contact must be provided between the second housing 14 and the radiator housing 19, which can be created, for example, by tightly pressing their contacting surfaces against each other when tightening with screws 34 (Fig. 3). Providing the specified electrical contact reduces the intrinsic (parasitic) electromagnetic radiation of the wireless modem, thereby increasing the level of its electromagnetic compatibility with the surrounding equipment.

An optimum in terms of reliability electrical contact between these housings can be ensured when a groove 20 is made in the end part of the side walls of the second housing 14 along its perimeter, in which an elastic conductive strip 21 (made, for example, of a conductive silicone elastomer) is installed, partially in an uncompressed state protruding from the specified groove (Fig. 3, 5). In this case, when installing the radiator housing 19 on the second housing 14 and tightening them together with screws, the conductive spacer 21 is resiliently compressed, which increases the reliability of the electrical contact between the said housings.

In a particular case, the radiator case 19 can be provided with a cover 18. In the opposite side walls of the radiator case 19, through ventilation holes 22 are made, which are equipped with electric fans 23 (Fig. 3). The fans 23 are electrically connected to the group output of the board 6 of the power control device (Fig. 6). Electric fans 23 relative to the ventilation openings 22 are arranged so that they have the ability to provide supply and exhaust ventilation of the internal cavity of the radiator housing 19 (Fig. 3).

As a board 7 of the computing module can be used, for example, the board included in the commercially available computing module VM - 03 (see http://uav-siberia.com/catalog/product/vm-03/). The specified board is equipped with a sensor 24 of its temperature. The satellite modem board 5 is equipped with a temperature sensor 25. The power control device is located on the board 6 and is equipped with a temperature sensor 26 of the board 6 of the power control device.

Temperature sensors of boards 5, 6 and 7 can be used, in particular, thermistors installed by soldering directly on these boards, for example, of the type NCP18WB473F10RB, see publication https://www.murata.com/en-us/api/ pdfdownloadapi? cate = & partno = NCP18WB473F10RB.

Temperature sensors 24, 25, 26 (as shown in Fig. 6) are connected to the first inputs of the operational amplifiers 40.

As operational amplifiers 40, for example, operational amplifiers of the TLE2024BMDW type can be used, see the publication https://ru.mouser.com/ProductDetail/Texas-Instruments/LE2024BMDW?qs=sGAEpiMZZMvtNjJOt4UgLRcOdEb8Mg41rc8.

The operational amplifiers 40 are connected with their second inputs to the microcontroller 39. They are also connected to the second input / output of the pulse converter 38, to the second input / output of the pulse converter with galvanic isolation 36, as well as to bipolar transistors 41 and to the second input / output of the pulse converter 37.

As the microcontroller 39 can be used, in particular, a microcontroller installed by soldering directly on the board, for example, of the ATMEGA328P-MU type, see publication https://www.microchip.com/wwwproducts/en/ATmega328P.

As a pulse converter with galvanic isolation 36 can be used, in particular, a converter installed by soldering directly on the board, for example, type TEN20-2422WTN, see the publication https://www.tracopower.com/products/browse-by-category / find / ten-20win / 3 /.

As a pulse converter 37 can be used, in particular, a converter installed by soldering directly on the board, for example, of the MAX17503ATP type, see publication https://www.maximintegrated.com/en/products/power/switching-regulators/MAX17503. html.

As a pulse converter 38 can be used, in particular, a converter installed by soldering directly on the board, for example, of the type MAX17504ATP see publication https://www.maximintegrated.com/en/products/power/switching-regulators/MAX17504. html.

As bipolar transistors 41 can be used, in particular, soldered directly on the board 6 transistors, for example, of the type PHPT60410NY see the publication https://assets.nexperia.com/documents/data-sheet/PHPT60410NY.pdf.

The power connector POWER 46, installed on the second housing 14, is connected via the "Power" bus (Fig. 6) to the first inputs / outputs of the pulse converters 36, 37 and 38. The output of the pulse converter with galvanic isolation 36 via the "Power U1" bus is connected to the power inputs of the satellite modem board 5 and the computational module board 7. The output of the pulse converter 38 via the Power U2 bus is connected to the electric fans 23. The bipolar transistors 41 are connected via the Power U3 bus to the heaters 10, 11, 12, 13.

Further in the text, the term "connector" (provided with a digital and / or letter designation) is used to denote a mechanical part that provides the possibility of electrical connection to the same input / output of the satellite modem 5, the "port" of the computing module 7 or serves to supply power to the boards and elements wireless modem.

The first and second inputs / outputs of the satellite modem 5 are connected, respectively, to the first 28 (Eth1) and second 29 (Eth2) Ethernet connectors of the wireless modem installed on its second housing 14.

The high-frequency output of the satellite modem 5 is connected to the high-frequency connector 31 (Tx output) installed on the second housing 14 of the wireless modem.

The high-frequency input of the satellite modem 5 is connected to the high-frequency connector 30 (Rx input) installed on the second housing 14 of the wireless modem.

The first input / output of the computing module 7 is connected to the third Ethernet connector 32 (Eth3), also installed on the second housing 14 of the wireless modem.

The described arrangement of the boards in the wireless modem minimizes the length of the wiring between the boards and, thus, increases the immunity of the wireless modem to external electromagnetic radiation and, at the same time, reduces the level of inherent electromagnetic radiation of the wireless modem.

To ensure the minimum values of the contact resistance between the structural elements of the wireless modem and thereby achieve the required resistance to external electromagnetic radiation while reducing the level of its own electromagnetic radiation, structural elements (Fig. 4): base 2 and the second housing 14 - by means of screws 33 , the second case 14 and the radiator case 19 - by means of screws 34, the cover of the radiator case 18 and the radiator case 19 - by means of screws 35, the first cover 3 and plate 8 - by means of screws 49, base 2 and the second cover 4 - by means of screws 42 , as well as base 2 and plate 8 - by means of screws 50, are rigidly tightened to each other. At the same time, this measure achieves the resistance of the wireless modem to mechanical shock, vibration, acceleration.

FIG. 3, the screws 33 are schematically shown installed in the supports 43 of the protrusions 16 of the second housing 14.

The enhancement of this effect in the proposed wireless modem is achieved by the fact that the zero potential buses 44 on the boards 5, 6 and 7 are brought out to the contact pads (not shown) having electrical contact with the electrically conductive racks 45 on which the boards are installed (Fig. 2). The electrically conductive struts 45 can be made in one piece with the base 2 and the first cover 3, for example, by casting. These racks can also be pressed into the listed structural elements of the wireless modem to provide electrical contact with these elements.

For the same purpose, the first 3 and second 4 covers, base 2, plate 8, second housing 14, radiator housing 19 and its cover 18 are preferably made of a deformable aluminum alloy (for example, D16) with a nickel coating and have electrical contact with the grounding pin 27 of the wireless modem (Fig. 1).

The second housing 14 of the wireless modem also has a POWER connector 46 (Fig. 1, 6) for powering the entire device, as well as light indicators 48 (Fig. 3), which can be, for example, LEDs.

A wireless modem, assembled from the described parts and assemblies, is installed, for example, in an aircraft on-board satellite communication station using screws (shown) and threaded holes 47 intended for fastening the modem.

The described design of a wireless modem as a device, in combination with the circuit solutions used in it, makes it possible to use it as an onboard aviation modem by increasing its resistance to external physical influences, in particular, to external electromagnetic radiation, changes in temperature, pressure, humidity environment, mechanical shock, vibration, acceleration, as well as by simultaneously reducing the level of its own electromagnetic radiation of the wireless modem.

Description of the operation of the wireless modem

When operating as an onboard aircraft modem, it is enabled by supplying an operating supply voltage (eg, 28 Volts DC) to the POWER connector 46. The specified supply voltage is supplied to the first inputs of the voltage pulse converters 36, 37, 38. Temperature values from the temperature sensor 24 of the board 7 of the computing module, from the temperature sensor 25 of the board 5 of the satellite modem, as well as from the temperature sensor 26 of the board 6 are transmitted to the operational amplifiers 40, and then to the microcontroller 39. The latter calculates the arithmetic mean of the temperatures of the boards 5, 6 and 7.

Depending on the obtained arithmetic mean value of the temperatures of the boards 5, 6 and 7, the microcontroller 39 controls the supply of voltages to the satellite modem board 5, the computing module board 7, fans 23 and electric heaters 10, 11, 12, 13.

Controlling the supply of supply voltage U1 to boards 5 and 7 occurs by supplying a signal from microcontroller 39 through operational amplifiers 40 to a switching voltage converter 36.

The supply of voltage U2 to the fans 23 is controlled by supplying a signal from the microcontroller 39 through the operational amplifiers 40 to the pulse voltage converter 38.

The voltage from the pulse converter 37 is supplied to the operational amplifiers 40, the microcontroller 39 and the bipolar transistors 41, which serve as switches for supplying voltage to the heaters 10, 11, 12, 13. When a signal from the microcontroller 39 is applied to the bipolar transistors 41, the latter supply the supply voltage U3 to the heaters 10, 11, 12, 13.

Heaters 10, 11, 12, 13 and fans 23 are actuators.

The logic of turning on / off the executive elements of the wireless modem, as well as turning on / off the power supply U1 of boards 5 and 7, depending on the arithmetic mean values of the temperatures of boards 5, 6 and 7, is shown in Table 1.

Since the electric heaters 10, 11, 12 and 13 are located directly between the base 2 and the plate 8, the heating of the boards 5, 6 and 7 occurs by transferring heat to them from the base 2 and the plate 8.

The fans 23 are the inducers of air movement in the radiator housing 19 and provide supply and exhaust ventilation of its inner cavity through the holes 22, which increases the heat transfer from the heat dissipating elements 17.

Performing the steps listed in Table 1 ensures that the wireless modem meets the KT-160D Qualification Requirements, thereby ensuring its use as an onboard aviation modem by increasing its resistance to external physical influences, in particular, to changes in ambient temperature and pressure and ambient humidity, directly affecting the temperature regime of the wireless modem as an electronic device.

In the presence of supply voltage on the board 7 of the computing module and the board 5 of the satellite modem, the wireless modem performs its work.

The computing module located on the board 7 is equipped with software (hereinafter referred to as software), for example, the software “SatUnion” registered in the Russian Federation (according to the certificate of state registration of the computer program No. 2015613858). The computing module, receiving information about the coordinates from the onboard inertial system of the aircraft (AC) from the external connector 29, automatically (using the specified software) calculates the availability of all satellites of the current profile and if the current satellite is unavailable (having, for example, negative or zero elevation values), or due to the loss of the communication channel, submits to the control system of the transmitting and receiving antenna (antenna and its control system - antenna system - not shown) a request for reorientation to the next of the available satellites indicating its number.

Via the RS-232 interface between the fourth port of the computing module 7 and the second input of the satellite modem 5, the settings of the satellite modem 5 are changed, which are required for the newly selected satellite.

The satellite modem card 5 receives and transmits traffic at a stable speed. During operation, through the high-frequency connector 30 (Rx input), the satellite modem card 5 receives a high-frequency signal from the antenna system and then modulates it into a digital signal, which is output to user devices (not shown) through connectors 28 and 29. Also, through connectors 28 and 29, the satellite modem 5 receives digital traffic, then modulates it into a high-frequency signal and through the high-frequency connector 31 (Tx output) sends it to the power amplifier of the control system of the receiving-transmitting antenna. Depending on the coordinates obtained from the onboard inertial navigation system of the aircraft (not shown), the computing module 7 automatically controls the settings of the satellite modem board 5 through the RS-232 interface connecting them. The antenna system is controlled via connector 32.

Claims (6)

1. A wireless modem containing a modem card, a power management device and a computing module installed in the first housing formed by the base, as well as the first and second covers, light indicators and a second housing containing the first housing, characterized in that the modem board uses a satellite modem board, in the first case between the base and the computational module board and the power control board, which are planarly placed relative to each other, a plate with resistive electric heaters fixed in its slots is installed, the satellite modem board is placed between the second cover and the base, which is heat-conducting is in thermal contact with the satellite modem board, the plate and a half-open second casing, on which a radiator casing equipped with heat dissipating elements is installed on its open side, ensuring its electrical contact with the second casing. 2. A wireless modem according to claim 1, characterized in that the radiator case is equipped with a cover, and through ventilation holes are made in the opposite side walls of the radiator case, which are equipped with electric fans connected to the output of the power control device board. 3. A wireless modem according to claim 1, characterized in that the heat dissipating elements of the radiator housing are made in the form of a finned radiator. 4. Wireless modem according to claim. 1, characterized in that the first and second covers, plate, base, second housing and radiator housing are made of a deformable aluminum alloy with a nickel coating. 5. The wireless modem according to claim 1, characterized in that a groove is made in the end part of the side walls of the second housing along its perimeter, in which an elastic conductive gasket is installed. 6. A wireless modem according to claim 5, wherein the elastic conductive pad is made of an electrically conductive silicone elastomer.

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