RU2175803C1 - Safety device for radio-frequency connectors and cable terminations in connectors against in- service adverse impacts - Google Patents

Abstract

FIELD: antenna-feeder lines. SUBSTANCE: connector has plug and socket as well as respective cable terminations. Safety device has safety sleeve, locking brackets for safety bushings, and fixture for mounting safety sleeve on support. Safety sleeve has central section, two arched sections, and open end sections. Central section accommodates radio-frequency connector and cable terminations and each end section receives one safety sleeve. Safety sleeve is mounted on support with its open ends downwards to earth surface. EFFECT: enhanced safety against wind and moisture effects dispensing with stuffing arrangements. 5 cl, 6 dwg

Description

 The invention relates to an antenna-feeder path and can be used in radio equipment, in outdoor radio communication systems.

 The prior art.

 A connector refers to a device designed to join cables together. The connector consists of two parts: plugs and sockets. One of the articulated cables is plugged into a socket, the other into a plug.

 A first device is known for protecting connectors and terminations of electrical cables into connectors against external operating factors [Weatherproof cover for electrical cable connector, U.S. Patent 3792415, Feb. 12, 1974, Alvin W. Fuller, Shelton, Conn.], Consisting of two separate caps. One of the caps is mounted on a power outlet, the other on a plug. Each of the caps consists of a housing and two sealing sleeves. The first sealing sleeve of the cap covers the cable sheath, the second sleeve serves to connect with another cap. The caps are installed on the cable before terminating the cables in the connector. After connecting the plug and socket, the caps are pulled onto the plug and the socket and connected to each other. At the junction, a junction of two caps is formed.

 The first known device has the disadvantage that due to the loose fit of the sealing sleeve to the cable sheath, the gaps at the junction of the caps, the roughness of the surfaces of the contacting structural elements, the tightness of the protection of the connector and cable terminations in the connector is violated. With temperature fluctuations, moist atmospheric air is drawn into the protected volume, forming condensate, which does not subsequently evaporate from the protected volume. Moisture accumulating in the connector interferes with the normal operation of the connector. The capillary effect, also due to the presence of microscopic gaps at the points where the cap covers the cable sheath and at the junction of the caps, facilitates the penetration of moisture from the outside of the protective device into the inside, which also leads to the accumulation of water inside the protective device. Penetrating into the protected volume air, carrying mold spores, contributes, together with other factors (darkness, humidity, heat, lack of draft), the development of mold fungi. This protective device protects the connector poorly from mechanical influences such as vibration and shock, as it does not have structural elements that rigidly fix the position of the cables and the connector. The device is made of polymeric materials, which in themselves are unstable to external operating factors, such as high humidity, solar radiation, which can significantly reduce the life of the device. The need to put caps on the cables before terminating the cables in the connector narrows the scope of the first known device. For cables already plugged into the connector, the use of this device is difficult.

 A second device is known for protecting radio-frequency connectors and cable terminations in the connector from external operating factors, which is a heat-shrinkable tube made by radiation modification of a TEP DMG 7.975.015 TU tube [Heat-shrinkable tube RD 107.460007.100-92 (limitation of DMG 7.975.016 TU) industry guidance document, group L27, date of introduction 01.10.93]. This device protects the RF connector by sealing. Tightness is created by thermal shrinkage of the tube with tight coverage of the connector and the sheaths of the adjacent parts of the cables.

The second known device eliminates the disadvantages of the first known device due to the fact that the first known device consists of two separate parts. However, the roughness of the cable insulation surface or the presence of scratches on it leads to a loss of tightness. As a result, moisture penetrates into the protective tube in the form of water vapor absorbed by temperature fluctuations and atmospheric pressure changes. Water from the outer surface of the protective device penetrates into the protected volume due to the capillary effect. The water inside cannot completely evaporate or spill out and therefore accumulates. The service life of the device is limited by the material from which it is made. Under the influence of humidity, heat, solar radiation, the polymer tube loses its physical and mechanical properties. Another disadvantage of the second known device is that it requires the use of special equipment in the form of a heating cabinet during installation. The need to heat the tube to install it to one hundred and forty degrees Celsius for five minutes narrows the scope of the device. It excludes the possibility of protecting such a device with radio frequency connectors and cables having elements of fusible materials (the melting temperature of which is below 140 ^o C), for example, polyethylene. The device is intended for single use. Disassembly of the protected connector is not possible without the destruction of the protective tube.

 A third device is known that protects the RF connector and the cable terminations in the connector from external operating influences Cold Shrink [3M Cold Shrink Weatherproofing kits, Andrew Corporation Catalog 1999], comprising a plastic protective tube having mechanical memory. The tightness of the protective device is ensured by the shrinkage of the protective tube and at the same time by its coverage of the connector and the cable parts closest to it. The known third device eliminates the disadvantages of the second known device, due to the need for heating the tube during installation of the device. However, in the known third device, the tightness can be broken if the inner surface of the protective tube or the surface of the cable sheaths deviate from the ideal shape. Fluctuations in air temperature contribute to the absorption inside the device of water vapor, which then condenses on the inner wall of the tube, connector, cables. In gaps formed due to imperfect adhesion of surfaces, moisture penetrates into the protected volume due to the capillary effect. The accumulation of water occurs due to the difficulty of condensate evaporation in a limited space, as well as due to the lack of other effective ways to remove moisture. The polymeric material from which the protective tube is made is itself subject to the influence of operational influences from which the connector and cable terminations in the connector are protected, such as temperature, humidity, solar radiation, leading to premature aging and loss of the necessary physical and mechanical properties. The Cold Shrink device does not allow multiple articulation and dismemberment of the shielded RF connector. A third known device is a disposable device. The Cold Shrink device is selected by the authors as a prototype of the invention.

 SUMMARY OF THE INVENTION

 When outdoor antenna systems or other devices are required that require connection using radio frequency connectors, the problem arises of protecting the connector and cable terminations in the connector from the destabilizing effect of external operating factors.

 One of the hardest climatic effects is exposure to high humidity. Moisture getting on the connector helps to accelerate the corrosion processes of its housing, especially in the presence of impurities in the atmosphere. The formation of a moisture film on insulating materials leads to rapid ionization of the film, to an increase in their surface conductivity. These phenomena provoke the appearance of breakdown due to the surface effect. In addition, the water film contributes to the occurrence of a capacitive effect due to the high value of the dielectric constant of water. Moisture absorption by electrical insulating materials also leads to a deterioration in a number of their mechanical parameters.

 The largest share of damage to the connectors from the action of the biological environment occurs in fungal infections. Fungal formations in the process of life release metabolic products, which mainly consist of organic acids that cause metal corrosion and decomposition of electrical insulation material.

 Under the influence of solar radiation, photochemical oxidation of such common materials as polyethylene and polystyrene occurs. Solar radiation leads to a significant change in the internal structure of dielectric molecules. The formation of cross-links in polyethylene and polystyrene causes the appearance of internal stresses and increases its fragility. Ultraviolet radiation activates the surface of metals, affecting the rate of atmospheric corrosion.

 Dust, due to the hygroscopicity of some particles, favors corrosion, worsens the electrical parameters of the connector, and promotes the development of molds.

 Shocks can lead to fatigue changes in the design of the connector or to mechanical damage. Vibration causes mechanical resonance in the connectors and the occurrence of dangerous voltages in the structural elements, which can lead to disturbances in electrical contact and a change in the transition resistance.

 The connector and cable terminations in it can be protected from external operating factors by sealing. The disadvantage of this protection is the accumulation of moisture in the protected device, which occurs due to difficulties in providing a high degree of sealing of the joints of the surfaces.

 The proposed technical solution eliminates the above disadvantages due to the fact that it is made in the form of a curved arc of a protective tube with downward facing open ends, into which are inserted the first and second safety sleeves that protect the cable from abrasion, and the protected RF connection is located in the center of the tube, and fixing the position of the cables and the connector is carried out using the first and second fixing brackets located on the left and right ends of the protective tube, respectively. The first and second fixing brackets - each, consists of a large clamp designed to be mounted on the protective tube, a small clamp fixing the position of the cable, and a rod connecting the large and small clamps, while the protective tube has a device for fixing the entire structure. The inner dimensions of the protective tube are such that the RF connector assembly passes freely through it, and a distance sufficient to protect from the connector located in the center of the tube to the ends of the tube is provided.

 Opaque walls of the protective tube made of metal protect the elements of the connector from exposure to solar radiation. The arcuate shape of the protective tube protects the protected device from wind loads. Due to the special shape and the open ends of the protective tube, moisture is removed from the protected place, leaking out under the influence of gravity, as well as through natural ventilation. The presence of draft in the tube prevents the development of mold. The curved shape and orientation of the protective tube with its ends facing down to the Earth, prevent atmospheric precipitation and water spray from entering the protected connector. The connector is mechanically protected by reliably securing its position. This is also facilitated by the strength and stiffness of the material of which the protective tube is made. The device allows multiple articulation and dismemberment of the protected connector.

 Enumeration of figures.

 In FIG. 1 shows, in accordance with the present invention, a device for protecting radio frequency connectors and cable terminations in a connector from external operating factors; a radio frequency connector is placed in the protection device, into which the cables are embedded.

 In FIG. 2 shows a protective tube of the present invention.

 In FIG. 3 shows a fixing bracket.

 In FIG. 4 shows the safety sleeve.

 In FIG. 5 depicts one of two safety sleeves mounted on the right end of the protective tube.

 In FIG. 6 shows an example of installing a protection device on a support. The device of the invention protects the connector and terminations of cables connecting the antenna to the transmitter.

 5. Information confirming the possibility of carrying out the invention.

 The device for protecting radio-frequency connectors and cable terminations in the connector from external operating factors (Fig. 1) consists of a protective tube 1, first and second fixing brackets 2, first and second safety bushings 3, and a device 4 for mounting the tube to the support (the support is not shown ) In the center of the protective tube there is a radio frequency connector 5 and cable ends 6 embedded in it.

 The protective tube 1 (Fig. 2) has a central section 7, first and second arcuate curved sections 8, end sections 9. The Central section 7 of the protective tube 1 for a more convenient location in it of the RF connector 5 is made in the form of a cylinder. The inner diameter of the protective tube 1 is larger than the larger diameter of the connector 5. The first and second curved sections 8 are located to the left and to the right of the central section 7, respectively. They have a sufficient radius of curvature for the inside of the protective tube 1 of the connector 5 and cables 6. The end sections 9 of the protective tube 1 to provide the possibility of punching its ends when installing the safety sleeves 3 have a thinning of the walls from the outside.

 In each of the ends 9 of the tube 1 (Fig. 3) are inserted and secured by punching along one safety sleeve 3.

 The safety sleeve 3 (FIG. 4) has the shape of a hollow cylinder equipped with a protruding limiting circular step 10 and a groove 11 to provide the best conditions for fixing the sleeve by punching. To facilitate the passage through the sleeve 3 of the connector 5 and cables 6, the edges of the inner surface of the safety sleeve have fillets 12.

 The locking bracket 2 (Fig. 5) includes a large clamp 13, a small clamp 14 and a connecting rod 15. The large clamp 13 of the fixing bracket 2 is made in the form of an open ring 16, having jaws 17 in place of the gap, intended together with the screw 18 for tightening a large clamp. The small clamp 14 of the fixing bracket 2 consists of a support half ring 19 having a sponge 20 with a threaded hole and a sponge 21, as well as a pressure half ring 22 having a hook 24 that engages in assembling a small clamp for a sponge 21 of the supporting half ring 19, and a sponge 23 with an opening screw 25. The small clamp 14 is tightened with the screw 25. The rod 15 is connected at one end to the middle of the open ring 16 of the large clamp, and at the other end to the middle of the support half ring 19 of the small clamp. The fixing brackets 2 are mounted on the protective tube 1 by means of large clamps 13, which are each tightened at their end of the protective tube.

 The device 4 (Fig. 1) mounting the tube to the support is made in the form of a mounting tab welded to the middle of the protective tube 1. Installation is carried out in such a way that both ends of the protective tube 1 are directed downward to the Earth's surface.

 To reduce the influence of external operational factors on the protective device, its elements are made of resistant materials and have protective coatings. The protective tube 1 and mounting tab 4 are made of the same metal: steel, copper, brass, etc., and have a protective paintwork or metal coating: PF-115 enamel, nickel, chrome, etc. Fixing brackets 2 metal (steel, copper, brass, etc.) have a paintwork or metal protective coating. Safety sleeves 3 are made of light stabilized polyethylene.

 Installation of the protection device is carried out in the following order. Small clamps are dismantled 14. The end of the cable 6, sealed in the plug, is inserted with it into one of the ends of the protective tube 1, is threaded through it. After that, the plug of the RF connector mates with a socket into which the end of another cable is sealed. The installation procedure may be the reverse: the end of the cable plugged into a socket is first threaded into the protective tube, after which it connects to the plug into which the end of the other cable is plugged. Then the connector 5 is drawn into the protective tube 1 so that it is in the center of the tube. The ends of the cables protruding from the protective tube are covered by small clamps 14 of the fixing brackets 2, after which the small clamps 14 are tightened.

 The device operates as follows. Opaque walls of the protective tube 1, made of metal, protect the elements of the connector from exposure to solar radiation. The arcuate shape of the protective tube protects the protected device from wind loads. Due to the curved shape and the presence of open ends of the tube facing the Earth's surface, moisture is removed from the protected place, leaking under the action of gravity, as well as through natural ventilation. The presence of draft in the tube prevents the development of mold. The downward curved shape and orientation of the protective tube prevents atmospheric precipitation and water spray from entering the protected connector. The mechanical protection of the connector is ensured by reliably securing its position. This is also facilitated by the strength and stiffness of the material of which the protective tube is made.

 In FIG. 6 shows an example of the use of the proposed protective device. Antenna 26 is mounted on mast 27 using a collar 28. A device 29 for protecting radio frequency connectors and cable terminations in the connector from external operating factors is mounted on mast 27 using an arm 30. The end of cable 31 from the antenna is connected to the feeder 32 using an RF connector, which is located inside the protection device 29. The feeder 32 is attached to the mast 27 with clamps 33.

When using the proposed device for the protection of the radio-frequency connector, consisting of the SR-75-168P socket and the SR-75-167P plug, and the PK-75-9-13 cable plugs into the socket and into the plug, the length of the central section 7 of the protective tube 1 is 36 mm . The radii of curvature of sections 8 of the protective tube 1 are 85 mm, the bend angle is 60 ^o . The inner diameter of the protective tube 1 is 28 mm, the inner diameter of the safety sleeve 3 is 24 mm. The internal size of the small clamp 14 of the fixing bracket 2 is 12 mm.

Claims (5)

 1. A device for protecting radio frequency connectors and cable terminations in a connector from external operating factors, comprising a protective tube and a device for fixing the position of the radio frequency connector and cables relative to the protective tube, characterized in that it further includes a device for mounting the protective tube to the support, the protective tube is curved in an arc, both ends are open and directed downward to the surface of the earth, and the radiofrequency connector and cable terminations in the connector are located in ntralnom portion of the protective tube.  2. The device according to claim 1, characterized in that the device for fixing the position of the radio frequency connector and cables relative to the protective tube is made in the form of the first and second fixing brackets fixed to the respective ends of the protective tube.  3. The device according to claim 2, characterized in that each of the fixing brackets consists of a large and small clamps connected by a bar, and the large clamps of the brackets are fixed at the respective ends of the protective tube, and the small clamps of the brackets cover the ends of the cables protruding from the protective tube.  4. The device according to claim 3, characterized in that the device for mounting the protective tube to the support is made in the form of a petal.  5. The device according to p. 4, characterized in that it further comprises a first and second safety sleeve, which are inserted into the respective ends of the protective tube.

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