RU2209494C1 - Rocket nose antenna cone - Google Patents

Abstract

FIELD: aviation and rocket engineering; ceramic rocket nose cones. SUBSTANCE: radioparent envelope has internal radioparent power element of porous crystal ceramic with polymer introduced in pores and external heat-shielding element of porous crystal ceramic; thickness of internal power element is 0.05-0.1 of total thickness of envelope wall or gradually increases from nose to base up to value corresponding to 0.1-0.9 of total thickness of wall; thickness of external heat-shielding element varies in inverse proportion, total electrical thickness of envelope wall being retained; outer surface of heat-shielding element is covered with moisture-repelling coat. Power element of envelope may be quantized in vicinity of joint with invar frame. EFFECT: enhanced carrying capacity and reliability. 2 cl, 2 dwg

Description

 The invention relates to the field of aviation and rocket technology, mainly to the designs of the head antenna fairings of rockets.

 Inorganic materials are used for the manufacture of highly loaded radiotransparent radome fairings of rockets. One of them is porous quartz ceramics, which has good dielectric, thermophysical and technological characteristics. Compared with other inorganic materials (alumina ceramics, ceramic, etc.), the low strength of porous quartz ceramics limits its use in the construction of highly loaded rockets.

 The reliability of the fairing design consists of the reliability of its elements. One of them is a radio-transparent element made of quartz ceramic, used for modern missiles.

 Known antenna fairing, according to US Pat. USA 4520364, IPC 6 H 01 Q 1/28, 1/42, 1985, including a radiolucent heat-protective element made of porous quartz ceramic.

 The lack of moisture protection of the material of the translucent porous fairing wall and reinforcing structural elements of the fairing wall does not allow to provide the required operational strength and radio technical characteristics.

 Known antenna fairing according to US Pat. RF 2090956, IPC 6 H 01 Q 1/42, 1994, selected as a prototype, including a radiolucent sheath made of quartz ceramics and Invar frame, connected by a sealant layer.

 The absence in the known design of the elements of moisture protection of the material of the porous wall, as well as the reinforcing elements in the wall structure, significantly reduces the operational characteristics of the fairing.

 This design is worked out, optimized and serially mastered in production, which allows for a statistical comparative analysis of this design with the proposed one.

Modern rocket technology is characterized by high speeds, therefore, high temperatures of aerodynamic heating, while the temperature on the outer surface of the fairing is unevenly distributed. In the bow, it can reach more than 2000 ^o C, and to the base is significantly reduced.

 The temperature on the inner surface of the fairing due to the heat-insulating properties of the wall is much lower than the temperature on its outer surface. Therefore, to the tensile stresses from the force aerodynamic effect, which reach the maximum value at the base of the fairing (10-20 times higher than the stresses from the force aerodynamic effect in the nose of the fairing), temperature stresses are added due to the temperature gradient across the thickness of the fairing wall.

 In the general case, the zone of maximum tensile stresses in the ceramic element is located in the inner layer of the fairing wall.

 One of the ways to increase the bearing capacity of the fairing is to strengthen the zones of the ceramic element most susceptible to tensile stresses.

 During operation, the fairing is exposed to external climatic influences - rain, frost, etc. - and internal - fogging, condensation. Moisture penetrating into the pores of quartz ceramics significantly reduces the radio technical characteristics of the fairing and therefore it is necessary to provide moisture protection for its porous wall in order to maintain the radio technical characteristics achieved by the fairing made of porous quartz ceramic under normal conditions, i.e. without exposure to moisture.

 The aim of the invention is to increase the reliability of the antenna fairing with a shell made of quartz ceramics by increasing its bearing capacity while providing the specified radio parameters.

The specified technical result is achieved by the fact that:
1. The head antenna cone of the rocket, which includes a radio-transparent shell made of quartz ceramic, connected by a sealant layer to Invar frame, is characterized in that the shell consists of a radio-transparent internal power element made of porous quartz ceramic with a polymer introduced into the pores and an external heat-protective element, the thickness of the internal force element is 0.05-0.1 of the total wall thickness of the shell or evenly increases from the toe to the base to a value corresponding to 0.1-0.9 of the total wall thickness, and the thickness of the outer heat-shielding element varies inversely with the preservation of the total electrical thickness of the shell wall, while a moisture-proof coating is applied to the outer surface of the heat-shielding element;
2. The head antenna fairing of the rocket according to claim 1, characterized in that the internal power element is made discrete in the area of connection with the frame.

In the claimed invention:
- the internal power element made of porous quartz ceramics with a polymer introduced into the pores has a higher structural strength than the external heat-protective element made of porous quartz ceramics, for example, as a result of a decrease in stress concentration in the pore region. This effect increases with increasing thickness of the power element, but its value is limited by the temperature of polymer destruction in the pores of the ceramics, since polymer destruction adversely affects the radio technical characteristics (PTX) of the fairing and, therefore, the thickness of the internal force element is selected based on the analysis of the results of statistical studies of the designs of various fairings from the ratio of its thickness to the total wall thickness of the fairing from 0.05-0.1 in the toe to 0.1-0.9 at the base of the fairing;
- moisture protection of the inner surface of the fairing is provided by a non-porous polymer film on the inner surface of the power element;
- the heat-protective element of the wall of the fairing made of porous quartz ceramics effectively provides protection against degradation of the heat-resistant polymer in the pores of the internal power element and the material of the heat-protective element has dielectric characteristics comparable in a wide temperature range with the dielectric characteristics of the material of the internal power element. The dielectric constant for both materials of the wall elements according to the results of experimental studies is 3, 38 - 3, 46, which makes it possible to obtain the radio technical characteristics of the proposed fairing the same as for a fairing with a radiotransparent shell made of porous quartz ceramic;
- moisture protection of the heat-protective element is provided by a moisture-proof coating (CDW). Depending on the operating mode, characterized by the temperature on the outer surface (T) of the fairing and the duration of the thermal aerodynamic effect, the GDP may be different. In the case of a hard operating mode, when Тн at the beginning of the rocket’s flight in the least heated area of the radome base is more than 1000 ^o С for 5-10 seconds, the CDW material is selected from the condition of its complete combustion without residues worsening the PTX of the radome. In the case of a soft operation mode of the fairing (T = 300 ... 600 ^o С throughout the flight), the CDW material is selected from the group of silicone polymers or from inorganic glazes with dielectric characteristics and geometric parameters taken into account in the radio engineering calculations of the developed fairing.

 In some cases of operational heat exposure, the design of the frame and the selected polymer for the formation of the sheath strength element, a slight decrease in the heat-strength bond of the sealant with the fairing sheath strength element is manifested. In these cases, it is advisable to perform a power element in the connection zone with the discrete frame, interrupted mainly in the middle connection zone, which makes up the majority of the length of the adhesive joint.

 In FIG. 1 shows a longitudinal section of a structural diagram of the proposed head antenna fairing of the rocket.

 Radiolucent fairing shell consists of an internal power element 1, an external heat-shielding element 2, a moisture-proof coating 3 and is connected to the Invar frame 4 by a layer of sealant 5.

 In FIG. 2 shows an antenna cowl in which the power element 1 is discrete.

 Fairings of the proposed design are implemented in various versions.

To cover all types of tested and introduced into production options for the proposed design, you can consider the following:
- A fairing made of quartz ceramics with a wall thickness of 10 mm, designed for soft operation. The internal power element, which mainly plays the role of CDW of the inner surface, has a thickness of 0.5-1.0 mm, made by impregnating the inner surface of the rim of porous quartz ceramic to a predetermined depth with a solution of a block polymer based on phenol-formaldehyde and organotitanium-silicon oligomer hot curing , during polymerization, forming a glossy waterproof film on an impregnated surface, while hot cured WDW is deposited on the outer surface of the fairing shell Nij representing the organosilicon enamel KO 5189.

 - Developed fairing according to the invention for hard operating conditions. The fairing is a shell of porous quartz ceramic with a wall thickness of 10 mm, which is impregnated on the inside with a solution of silicone resin MFSS-8 of a spirocyclic structure to a depth of 0.5-1.0 mm in the bow and with a uniform increase in the depth of impregnation to the base to 5 -6 mm with local interruption of the impregnation in the middle 80% zone of the joint by temporary waterproofing of the shell, is subjected to temperature polymerization, a hot-cured WDW is applied by spraying on the outer surface, consisting of and layers of epoxy primer and enamel Teflon AF 566.

 A comparative statistical analysis of the results of experimental studies of the radio engineering and strength characteristics of porous quartz ceramic fairings with a monolithic half-wave wall in comparison with the characteristics of laminated wall fairings showed that the presence of polymer in the pores of the inner force layer does not affect PTX, but significantly increases the carrying capacity of fairings due to increase the strength and stability of the strength characteristics of the internal power element.

The results of heat resistance tests and assessment of the influence of thermal effects and high humidity on the PTX experimental batches of fairings of the claimed design are as follows:
- the probability of failure-free operation of the fairings made according to the prototype, with the ground-based implementation of the specified heat and climate influences, corresponds to 0.5-0.9 and increases to 0.99-0.999 for fairings made according to the invention, depending on the thickness of the power element, t .e. reliability increases significantly;
- when the limit of the permissible thickness of the power element is exceeded, beyond which polymer destruction occurs in the pores of quartz ceramics during thermal operation, the PTX of the fairings deteriorate;
- in the absence of CDW on the outer surface of the fairing and the penetration of moisture into the pores, the radio technical characteristics of the fairings are also unacceptably deteriorating;
- in cases of manifestation of a negative effect of the onset of polymer degradation in a power element on the heat resistance of the sealant and in the absence of this effect on PTX, temporary waterproofing of a part of the connection zone during the formation of the power element discrete ensures the exclusion of this negative effect without reducing the bearing capacity and reliability of the fairing.

 Thus, the results of comprehensive experimental studies of the design of the fairing according to the invention have shown that the specified reliability provides the specified reliability of meeting the high requirements for heat resistance and radio engineering parameters under the operating conditions of the fairings of modern rockets of various classes.

Sources of information
1. US patent 4520364, IPC 6 H 01 Q 1/42, 1/28, 1985

 2. RF patent 2090956, IPC 6 H 01 Q 1/42, 1994 - prototype.

Claims (2)

 1. The head antenna fairing of the rocket, including a radiolucent shell made of quartz ceramic, connected by a sealant layer to Invar frame, characterized in that the radiolucent shell consists of a radiotransparent internal force element made of porous quartz ceramic with a polymer introduced into the pores and an external heat-protective element made of porous quartz ceramics, and the thickness of the radiotransparent internal power element is 0.05-0.1 of the total wall thickness of the radiotransparent shell or evenly increasing varies from sock to base to a value corresponding to 0.1-0.9 of the total wall thickness, and the thickness of the external heat-shielding element changes inversely with the preservation of the total electric wall thickness of the radiolucent sheath, while a moisture-proof coating is applied to the outer surface of the external heat-shielding element .  2. The head antenna fairing of a rocket according to claim 1, characterized in that the radiolucent internal power element is made discrete in the area of connection with the frame.

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