RU2343509C1 - Radiolucent thermoregulating coating - Google Patents

Abstract

FIELD: physics, radio.

SUBSTANCE: radiolucent thermoregulating coating (RTRC) is intended mostly for thermal regulation and electrostatic protection in the form of screens or in the form of coating adhered to surface of spacecraft design elements. Coating contains external electroconductive light-reflecting layer and substrate from polymer material that are transparent for electromagnet radiation of wide frequency range, between which additional electroconductive layer is installed, being transparent for electromagnet radiation of wide range of radio frequencies and made from semi-conductor. On substrate rear side the second electroconductive light-reflecting layer is applied, with larger thickness. All layers are made from radiation-resistant materials that do not reflect thermal radiation. Thickness of light-reflecting layers lies within the range from 4×10^-8 to 20×10^-8 m. Light and easy-to-manufacture coating reflects at least 50% and transmits not more than 5% of solar radiation, which does not reflect thermal radiation and transmits more than 99% of electromagnet radiation in range of frequencies from several megahertz to dozens of gigahertz.

EFFECT: creation of coating that is simple and easy-to-manufacture for thermal stabilisation and reliable electrostatic protection of antenna systems.

3 cl, 1 dwg

Description

The invention relates to the field of temperature-controlled coatings, operated primarily as part of space technology.

Radiolucent thermal control coating (RTRP) is designed for thermal stabilization and electrostatic protection of antenna systems.

During operation, a spacecraft (SC), including its antennas, is periodically and unevenly illuminated by the Sun, exposed to flows of charged particles. Uneven heating and electrostatic charging of the surfaces of the spacecraft occur. As a result of uneven heating, distortion of the shape of the reflectors, rods, and antenna irradiators is observed (due to the greater thermal expansion of the warmer sections), which leads to a deterioration in communication quality (to a decrease in power and distortion of the received signal). Electrical discharges arising from the action of charged particles cause interference and malfunctions on-board equipment. To prevent these negative phenomena, it is necessary to provide thermal stabilization of antenna systems and protect them from electrification.

A comprehensive solution to the problems of thermal stabilization and electrostatic protection of antennas is achieved by the use of reflective electrically conductive screens "grounded" on the spacecraft hull. The use of metallic coatings commonly used to provide electrical conductivity and light reflection. unacceptable, since metal coatings do not transmit radio emission.

The temperature regime of the coating is ensured by the ratio of the thermal radiation characteristics As / ε of its surface. The smaller the As / ε ratio, the more efficient the coating. The required As / ε ratio can be achieved using a transparent dielectric material that provides a large ε value and a reflective layer of a material with small As on one side of the dielectric material or on both sides. Moreover, all coating materials must be radiolucent, that is, they must freely transmit electromagnetic radiation of the radio frequency range (from a few MHz to tens of GHz).

However, in addition to the electromagnetic radiation of the Sun, corpuscular radiation acts on the outer surface of the spacecraft - the fluxes of electrons and protons of the Earth’s radiation belts (RPZ). Under their action, an inhomogeneous electrostatic charge accumulates on the dielectric surfaces of the spacecraft. Periodically, discharges occur between surface areas with different electrical potentials, causing interference or even malfunctions of the on-board electronic equipment and contributing to the deterioration of the characteristics of optical surfaces. To protect against electrification, it is necessary to apply electrically conductive layers to the front surface of the coating, which do not impair the characteristics of As, ε and the radio transparency of the coating.

A multilayer coating is known, consisting of a substrate with a transparent conductive coating on the outer surface and a reflective coating on the back surface, made in the form of a metal film with high reflectivity in the wavelength range of 0.3-2.4 μm, characterized in that the transparent conductive coating includes at least 2 layers, and one of the layers contains cerium oxide, and the substrate is made of a polyimide film (patent RU 2269146, 04/30/2003).

The main disadvantage of this analogue is the opacity for electromagnetic radiation in the radio frequency range.

Known radiolucent sunscreen membrane (US 5373305, 12/13/1994), covering the antenna reflector, comprising at least two dielectric sheets of a polyimide film 25 μm thick, separated by a mat of fiberglass, and the front surface of the upper dielectric sheet is provided with an electrically conductive semiconductor coating such as germanium, a thickness (2-6) 10 ^-8 m. In addition, the inner dielectric sheet can be reinforced with a glued mesh of polyester or fiberglass.

The main disadvantages of this analogue are:

- insufficient conductivity of the front surface for effective removal of electrostatic charge;

- the presence of fiberglass in the composition of the membrane can lead to the appearance of fiberglass particles in the spacecraft’s own external atmosphere, which can lead to clogging of precision mechanical devices, errors in optical and navigation devices. In modern spacecraft, the use of materials containing open (not filled with binder) fiberglass is not allowed;

- large mass and design complexity.

The closest in technical essence is “Laminated sheath for providing thermal and electrostatic protection” (patent RU 2087392), containing an outer layer made of a conductive material transparent to a wide range of microwave frequencies, reflecting thermal radiation, a thermoregulatory layer made with thermally reflective coating and with an intermediate layer located between the outer conductive layer and the thermal reflective coating, characterized in that the outer conductive layer is made with equal numbered from 5 × 10 ^-8 to 25 × 10 ^-8 m thick and equipped with a substrate made of a polymer material transparent for a wide range of microwave frequencies, and the heat-reflecting coating is made of a polymer film material transparent for a wide range of microwave frequencies.

In a preferred embodiment, the germanium layer is about 11 x 10 ^-8 m thick, and the Kapton film serving as the film layer is about 1 mil (~ 25 μm) thick. Nomex fiber has a thickness of 4 to 5 mils (~ 100-125 μm) as an intermediate layer, and the Tedlar film used as a thermal reflective coating is about 1 mils (~ 25 μm) thick. In this design, the layered casing allows transmission of about 99% of the radio frequency emissions, passing only 4-5% of the light. Basically, the thicker the layers, the less light and radiation of the radio frequency passes through the layered shell. Thus, these sizes can be increased by decreasing the passage of light through the laminate at the cost of decreasing the transmission of radio frequency radiation.

This technical solution is taken as a prototype.

The main disadvantages of the prototype are:

- a large mass of the laminate. Since there are no significant mechanical loads on the thermal screens of antennas in outer space, the use of such a bulky coating in order to increase rigidity and strength is not justified;

- the complex structure of the laminate;

- the presence of a heat-reflecting coating can lead to overheating of the layered shell, since thermal reflection means a small value of the emissivity ε and a large value of the ratio As / ε;

- the external reflective conductive coating is single-layer, due to which its electrical conductivity can easily deteriorate during storage due to interaction with atmospheric oxygen, and it will no longer fully perform the function of protection against the accumulation of electrostatic charge;

- there is no conductive coating to remove electrostatic charge from the back of the shell. This can cause charge accumulation on the back side of the shell and the occurrence of electric discharges between the front and back surfaces, which leads to destruction of the shell at the breakdown site, deterioration of the reflective properties of the coating due to contamination by thermal decomposition products, interference and malfunctions of on-board electronic equipment.

The task to which the claimed invention is directed is to create a light and easy to manufacture radiolucent thermoregulatory coating for thermal stabilization and reliable electrostatic protection of antenna systems, reflecting at least 50% of the electromagnetic radiation of the Sun, transmitting not more than 5% of solar radiation, not reflecting thermal radiation ( the ratio As / ε is not more than 1) and transmitting more than 99% of the electromagnetic radiation of the antennas (in the frequency range from several megahertz to tens of gigahertz).

The task is achieved in that:

between the external electrically conductive reflective layer and the substrate there is an additional electrically conductive layer transparent for electromagnetic radiation of a wide range of radio frequencies and made of a semiconductor, and on the back side of the substrate a second electrically conductive reflective layer of a greater thickness is applied, and all layers in the coating composition are made of radiation-resistant materials not reflecting thermal radiation, and the thickness of the reflective layers is in the range from 4 × 10 ^-8 m to 20 × 10 ^-8 m.

The essence of the invention is illustrated in the drawing, which shows a cross section of the coating RTRP. It consists of a substrate 1. made in the form of a polymer film with a thickness of 12 to 60 microns. an external conductive reflective layer 2 on the front surface of the substrate, a uniform thickness (usually, but not necessarily, in the range from 4 × 10 ⁻⁸ to 10 × 10 ⁻⁸ m), an additional conductive layer 3 and a second conductive reflective layer 4 made of the same material as layer 2, but with a greater thickness (usually in the range from 8 × 10 ^-8 to 20 × 10 ^-8 m), while all layers of RTRP are made radiation resistant (while maintaining operational properties after irradiation, with absorbed dose over 3 × 10 ⁶ Gray) and transparent to elec electromagnetic radiation of a wide range of radio frequencies (at least from a few megahertz to tens of gigahertz).

During operation, the front surface of the RTRP coating is exposed to solar radiation and the flow of charged particles.

Solar radiation is reflected from the outer and second (back) electrically conductive reflective coating layers (~ 50%), part of the radiation is absorbed in the electrical conductive layers 2-4 and substrate 1 (~ 45%), the rest of the solar radiation (~ 5%) passes through the RTRP to the protected device. Due to the influence of the flows of charged particles in the RTRP coating, an electrostatic charge is accumulated, which flows through the external (2), additional (3) and rear (4) conductive layers to the ground point on the spacecraft’s hull (not shown). Since the largest amount of charge is achieved on the front side, the conductivity of the reflective layer 4 is sufficient on the back side. When the device protected by the coating is working, the electromagnetic radiation of the radio frequency range passes through the RTRP almost without loss both from the front and from the back of the RTRP.

In a preferred embodiment of the RTRP, the electrical resistivity of the additional electrically conductive layer 3 is selected at a level of 1 × 10 ⁶ to 5 × 10 ⁷ Ohm / cm ² since absorption of electromagnetic radiation of the radio frequency range occurs with a lower resistance, and an increase in resistance leads to a decrease in the removal efficiency excess electrostatic charge. The resistance of the second electrically conductive reflective layer 4 is preferably selected in the range from 1 × 10 ⁷ to 5 × 10 ⁹ Ohm / cm ² , for the above reasons, and the upper allowable boundary of the resistance is increased compared to layer 3, since through the substrate 1, layers 2 and 3, significantly less charged particles penetrate layer 4.

Moreover, due to the presence of an additional conductive layer 3, the second conductive reflective layer 4, the implementation of conductive reflective layers 2 and 4 with a thickness of 0.04 to 0.20 μm and the implementation of all layers of radiation-resistant materials that do not reflect heat radiation, at their high transparency for electromagnetic radiation of a wide range of radio frequencies, high efficiency of antenna protection from space factors is ensured during operation as a part of the spacecraft (up to 15 years at the geostationary orbit), the absence of interference with the passage of radio emission from both the back and the front side of the coating, with a low specific gravity and ease of manufacture.

Including:

- low specific gravity and ease of manufacture are achieved due to the small number of layers and their small thickness, and for applying all layers, one method can be used (for example, deposition in vacuum);

- the high efficiency of protecting the antennas from overheating by solar radiation is achieved by performing all layers not reflecting thermal radiation, the presence of two electrically conductive reflective layers (on the front and back side) and choosing their thickness in the optimal range (from 0.04 to 0.20 μm) moreover, layer 2 (on the front side) has a smaller thickness (providing the maximum light reflection coefficient), and layer 4 (on the back side) has a greater thickness, which ensures minimal transmission of solar radiation;

- the absence of interference with the passage of radio emission (electromagnetic radiation of a wide range of radio frequencies) is ensured by performing an additional conductive layer 3 transparent to electromagnetic radiation of a wide range of radio frequencies and making conductive reflective layers with a thickness of not more than 0.20 μm;

- high efficiency and reliability of protecting the antennas from the damaging effects of electrification factors is achieved by introducing into the coating composition an additional conductive layer 3 and a second conductive reflective layer 4, and due to the location of layer 3 between the substrate 1 and the outer conductive reflective layer 2, high stability of the electrical characteristics of the coating is ensured - both during storage in ground conditions, and when operating in near-Earth orbit as part of the spacecraft;

- the performance and reliable operation of the coating during the entire period of operation in harsh conditions of outer space is ensured by performing all layers of radiation-resistant materials, and the conductivity of layers 2-4, the optical properties of layers 2 and 4, and the mechanical strength of the substrate 1 should be considered the radiation resistance criterion.

Thus, RTRP has the following main features: high radio transparency and radiation resistance of all components, high electrostatic charge removal efficiency, As / ε ratio of no more than 1, low weight and ease of manufacture.

Owing to the combination of the indicated features, the RTRP coating possesses increased stability of operational characteristics throughout the entire life cycle period, from production to the end of operation as part of a spacecraft.

An example of the composition and typical characteristics of samples of various coating options are shown in table 1.

Table 1
The composition and properties of some variants of radiolucent thermoregulatory coating Front side Substrate 1 Backside Radio transmission Layer 2 (see figure 1) Layer 3 As ε R _p , MΩ Layer 4 ε R _p , GΩ Ge, 0.07 μm In ₂ O ₃ , 0.02 μm 0.45 0.65 10 Polyimide film 20 μm Ge, 0.1 μm 0.65 0.5 ≥ 99% Ge, 0.10 μm SnO ₂ , 0.02 μm 0.50 0.71 fifty 40 μm film Ge, 0.15mkm 0.71 0.2 ≥ 99% Ge, 0.15 μm InO _x , 0.01 μm 0.50 0.80 10 60 μm film Ge, 0.2 μm 0.80 0.1 ≥ 99%

The company developed and manufactured prototypes of the coating. The tests showed a high resistance of the coating to storage factors (exposure to variable temperatures and humidity) and operation (cyclical changes in temperature in vacuum (± 180 ° C), ionized radiation with an absorbed dose of up to 3 × 10 ⁶ Gy, exposure to solar radiation, electron fluxes). During electron irradiation in a vacuum, electrification of the coating surface is absent.

After simulating 4-8 years of storage, impact of shock, vibration and transportation loads, cyclical changes in temperature in vacuum, exposure to ionizing radiation and transatmospheric solar radiation, the coating retains the surface conductivity sufficient to remove excess electrostatic charge; radio transparency and optical characteristics of the coating meet the requirements for RTRP.

From known to the authors of patent information sources, the totality of features similar to those of the claimed subject matter is not known.

Claims (3)

1. A radiolucent thermoregulatory coating comprising an external electrically conductive reflective layer transparent to electromagnetic radiation of a wide range of radio frequencies, provided with a substrate of a polymer material transparent to electromagnetic radiation of a wide frequency range, characterized in that an additional electrically conductive layer is placed between the external electrically conductive reflective layer and the substrate, transparent for electromagnetic radiation of a wide range of radio frequencies and made of semi odnika, while the rear side of the substrate is applied the second conductive reflective layer, of greater thickness, and all the layers in the coating are made of radiation resistant materials that do not reflect the thermal radiation, and the thickness of reflective layer is in the range from 4 × 10 ^-8 × 20 10 ^-8 m. 2. The radiolucent thermal control coating according to claim 1, characterized in that the electrical resistance of the additional conductive layer is selected at a level of from 1 × 10 ⁶ to 5 × 10 ⁷ Ohm / cm ² . 3. The radiolucent thermal control coating according to claims 1 and 2, characterized in that the electrical resistance of the second electrically conductive reflective layer is selected at a level of from 1 × 10 ⁷ to 1 × 10 ⁹ Ohm / cm.