RU2187045C2 - Fuel sample burning rate meter - Google Patents

Abstract

FIELD: testing facilities. SUBSTANCE: device consists of hermetically sealed combustion chamber accommodating end burning fuel sample placed inside armored cup and light conduit with row of holes. Light conduit is installed along cup axis with inlet and outlet from side of open and heat-insulated ends of fuel sample. Geometric axes light conduit holes are square to geometric axis of light conduit. Light conduit is made of material transparent in visible spectrum and sublimating in burning zone. Radiation detector is installed opposite to outlet end of light conduit. Device includes also photoamplifier and recorder with time marker. Microdose of chemical composition of alkaline group additional element, volume from 0.0001 to 0.001 cm³, is fitted in each hole of light conduit, and monochromatic filter with transmission wave length equal to length of wave of saturated central part of resonant spectrum line of additional element is installed between outlet end of light conduit and radiation detector. EFFECT: possibility of changing burning rate at any degree of nonuniformity of burning process and obtaining maximum number of measurements of burning rate at one test. 2 dwg

Description

 The invention relates to techniques for testing combustible materials, in particular to devices for measuring the burning rate of fuel samples burning in parallel layers, for example, polymer composite material (PCM).

 A device for measuring the burning speed of PCM containing a sealed combustion chamber, placed in it in an armored cup a sample of PCM with two signal metal threads located at a known reference distance Δl from each other in the holes drilled in the sample perpendicular to its axis, a multi-channel recorder with a marker time (1).

Известно также устройство для измерения скорости горения ПКМ, содержащее герметичную камеру сгорания с размещенным в ней в бронированном стакане образцом топлива торцевого горения и светопроводом, выполненным из материала, прозрачного в видимой и ИК-областях спектра, и установленным внутри образца по оси последнего, с расположением входа и выхода соответственно со стороны открытого и термоизолированного торцов образца топлива, приемник излучения, установленный напротив выходного конца светопровода, регистратор с отметчиком времени (2).This device is ineffective, because it provides for one experiment to obtain only one value of the burning rate U by dividing the length of the control section Δl by the time Δt between the moments of burnout of metal threads recorded by the multichannel recorder when the combustion front moves

There is also known a device for measuring the burning speed of PCM, containing a sealed combustion chamber with a sample of end-face fuel placed in it in an armored cup and a light guide made of a material that is transparent in the visible and infrared regions of the spectrum, and installed inside the sample along the axis of the latter, with the location the input and output, respectively, from the open and thermally insulated ends of the fuel sample, a radiation receiver mounted opposite the output end of the light guide, a recorder with a timer ( 2).

 Closest to the claimed is a device for measuring the burning rate of a fuel sample (3). The device comprises a sealed combustion chamber with a sample of end-face fuel placed in it in an armored glass and a light guide with a number of openings located at a known distance from each other. The geometrical axis of the holes is perpendicular to the geometrical axis of the light guide made of a material that is transparent in the visible spectrum and sublimates in the combustion zone at a speed equal to the burning speed of the fuel sample. The optical fiber is installed along the axis of the glass with the location of the input and output from the open and thermally insulated ends of the sample. The device also contains a radiation receiver mounted opposite the output end of the light guide, a photo amplifier and a recorder with a timer.

 However, this device for measuring the burning rate has a significant drawback - reduced information content of the device with a high uneven burning rate of the PCM fuel sample. This is due to a sharp decrease in the number of burning rates determined in one test. This makes it difficult to assess the non-uniformity of fuel combustion during the combustion process and leads to the need to conduct an additional large number of fire tests of fuel samples from this PCM in order to establish the law of combustion of the latter.

 The low information content is due to the fact that with a high non-uniformity of the combustion process, due to an increase in the intensity of fluctuations in the flame temperature in the combustion zone, the resolution of the prototype device decreases (the signal-to-noise ratio decreases) and, therefore, the difficulty of extracting a useful signal from the signal recorded on the oscillogram increases the signal of the radiation receiver of a multi-frequency oscillatory process corresponding to temperature fluctuations.

 The objective of the invention is to provide a device that allows the measurement of the burning rate at any degree of unevenness of the combustion process and provides the maximum number of measurement results of the burning speed in one experiment.

The problem is solved due to the fact that in the known device for measuring the burning speed of a fuel sample containing a sealed combustion chamber with an end-face fuel sample placed inside it, located inside the armored cup, and mounted along the axis of the cup with the entrance and exit locations open and thermally insulated the ends of the fuel sample, a light guide with a number of holes whose geometric axes are perpendicular to the geometric axis of the light guide made of a material transparent in the visible region of the spectrum and sublimating in the combustion zone, a radiation detector mounted opposite the output end of the light guide, a photo amplifier and a recorder with a timer, a microdose with a volume of 0.0001 to 0.001 cm ^{3 of the} chemical compound of the alkaline group additional element is placed in each hole of the light guide, and between the output end a light guide and a radiation receiver have a monochromatic filter with a transmission wavelength equal to the wavelength of the saturated central part of the resonant spectral line of the additional element.

Among the elements of the alkaline group are metals: cesium, potassium, lithium, sodium. All these elements have a low excitation potential and give intense radiation primarily in the form of a resonance line of the spectrum. The central part of the line radiates most strongly, reaching saturation (i.e., emitting as a completely black body with a radiation black factor ε _λ = I) at a sufficient concentration of the additional element. Moreover, the required additives of the alkaline element are so small that they do not affect the kinetics of the fuel combustion process (5). Thus, when used as the additional saturated sodium element radiation center of the resonant line of sodium with a wavelength λ _res = 0.5893 microns is achieved when the concentration of sodium atoms in the flame October ¹³ -10 ¹⁴ atoms per 1 cm ^3, and temperatures of about 2000 K (4 ) The combustion temperatures of most modern PCMs exceed the indicated value of the temperature of ionization of sodium atoms. Therefore, all sodium atoms in the fuel combustion zone will be in an ionized state. The mass of sodium atoms in a microdose of a chemical compound of sodium, for example sodium chloride, placed in each hole of the light guide and providing a concentration of 10 ¹³ -10 ¹⁴ sodium atoms in 1 cm ³ , with the penetration of the combustion front into any hole of the light guide is 3.82 • 10 ^-10 ÷ 3.82 • 10 ^-9 g, and their volume is 3.94 • 10 ^-10 ÷ 3.94 • 10 ^-9 cm ³ .

These are very small quantities. Therefore, a microdose of sodium chloride with a volume of the order of 0.0001-0.001 cm ³ , placed in each hole of the light guide, can easily provide the required minimum concentration of 10 ¹³ -10 ¹⁴ sodium atoms in 1 cm ^{3 of} flame. Obviously, in this case, the passage of the combustion front of each of the light guide holes is accompanied by a significant abrupt increase spectral flux Φ _Res flame radiation corresponding to a wavelength λ _res = 0.5893 microns, since the spectral emissivity of radiation to a saturated central portion of the resonant line ε _λ = 0.5893 = 1 and many times exceeds the values of the spectral emissivity for other wavelengths. Installation monochromatic filters having transmission wavelength λ _res = 0.5893 microns allows the passage of radiation to the receiver advantageously _Res spectral flux Φ corresponding to the wavelength λ _res = 0.5893 microns, and strong suppression of spectral radiation flux corresponding to other wavelengths.

Thus, the placement of a chemical compound of an additional alkali group element in the microdose openings of the light guide and the installation of a monochromatic filter between the output end of the light guide and the radiation receiver can increase the resolution of the device for measuring the burning rate due to an increase in the recorded useful signal due to the increased spectral flux Φ _res , and by reducing the noise spectral respective streams with wavelengths different from the wavelength λ _res = 0.5893 km.

 In FIG. 1 is a structural diagram of a device for measuring the burning rate of a fuel sample. Figure 2 shows the waveforms of the signals of the radiation receiver (curve 1) and the timer (curve 2).

The device contains a fuel sample 1 with a light guide 2 installed along its axis with a number of holes in which microdoses 10 of the chemical compound of the alkali group additional element are placed, the sample being coated on the side surface with an armor coating 3, except for the front end, and placed in a large volume combustion chamber 4, filled with an inert gas under a certain pressure P _c .

The pressure P _{c is} controlled by a pressure sensor 5 (for example, type LH-410). A monochromatic filter 11 and a radiation receiver 6 (for example, type ФД-9Э111) are placed on the same optical axis with the light guide 2, the signal of which is amplified by the photo amplifier 7, made on the basis of the well-known circuit shown in p. 35 (5). The output of the photo amplifier and the pressure sensor through a strain gauge 6 are connected to separate inputs of a multi-channel recorder 9 with a timer (for example, a N-700 light-beam oscilloscope). The registrar records in time the amplified signals of the radiation receiver h _ic = f (t), the pressure sensor h _ig = f (t) and the timer in the form of a sinusoidal curve with a period Δ = 0.02 s. (figure 2).

The device operates as follows. When an open (front) surface of a fuel sample is ignited using PCM, the process of burning the sample in parallel layers begins, at which the combustion front, remaining perpendicular to the axis of the sample, moves to the left. When the combustion front reaches the front end of the fiber made of Plexiglas, the radiation flux Φ _io from the combustion front is output through the optical fiber 2 and a monochromatic filter 11 in the form of a spectral flux Φ _iλ = 0.5893 to the radiation receiver 6, which forms an electrical signal proportional to the flux on the oscillogram (curve 1 in figure 2) in the form of deviations h _ic from the zero line registered on the phototape in the absence of flux Φ _io .
The light guide, as in the prototype device, is made of organic glass of the SOL or ST. Brands (6), sublimating (bypassing the melting stage) at high temperatures (1500 ^o С and above) in the PCM combustion zone with the formation of gaseous products that clean the surface of the light receiving end light guide from pollution. Due to the low thermal conductivity, PCM sublimates only a thin layer of the light guide located in the reaction layer, where, in fact, the combustion process proceeds. At the same time, plexiglass retains its transparency in the process of burning fuel. However, the transmittance of the optical fiber due to the continuous shortening of the optical fiber, which occurs simultaneously with the shortening of the fuel sample, continuously increases, which leads to a continuous increase in the radiation flux Φ _iλ = 0.5893 of the electric signal at the output of the radiation receiver and the ordinate h _ic on the waveform h _ic = f ( t).

Since there are holes in the light guide with microdoses of an additional alkali group element placed in them, when the combustion front reaches each of the holes, an instantaneous change in the radiation flux Φ _io is observed both due to the difference in the optical properties of the light guide material and the gas located in the hole plane and due to the instant ionization of the atoms of the additional element, creating their own radiation flux Φ _res .
This change causes the appearance on the curve 1 (figure 2) of a pointed pulse (peak), and the number of peaks corresponds to the number of holes in the light guide.

для разных участков сгоревшего образца топлива.By measuring the time intervals Δti corresponding to neighboring peaks on the waveform and knowing the distance Δli between neighboring holes, the values of the burning rate are found

for different sections of a burnt fuel sample.

With a large number of holes in the light guide, the number of obtained values of U _{i is} also significant, which ensures an increase in the volume of measurement information obtained during one fire test of a fuel sample. This, in turn, makes it possible to assess the unevenness of fuel combustion during the combustion of the sample, to reduce the time and cost of tests associated with the establishment of the PCM combustion law.

LIST OF USED INFORMATION SOURCES
1. Sinaev K.I., Kazban B.M. Laboratory work on internal ballistics. Kazan: Publishing House of the Kazan Institute of Chemical Technology, 1968.

 2. Ignatiev BS, Ignatiev MB, Dadiomov Yu.R., Stafeychuk B.G., Yamov A.I. An improved photoelectric method for measuring the burning rate of polymer composite materials // International Scientific and Technical. conference "Advanced Chemical Technologies and Materials" (abstract). Perm, 1997.

 3. RF patent 2122683 "Device for measuring the burning rate of a fuel sample."

 4. Gordov A.N. Temperature measurement of gas flows. L .: Mashgiz, 1961.

 5. Scherbakov V.I., Grezdov G.I. Electronic circuits on operational amplifiers. Kiev: Engineering, 1983.

 6. Melnikov Yu.F. Lighting materials. M .: Higher school, 1976.

Claims (1)

A device for measuring the burning speed of a fuel sample, containing a sealed combustion chamber with a face combustion fuel sample located inside it, located inside the armored cup, and mounted along the axis of the cup with the location of the input and output from the open and thermally insulated ends of the fuel sample, a light guide with a number of holes, the geometric axes of which are perpendicular to the geometric axis of the light guide made of a material that is transparent in the visible region of the spectrum and sublimates in the combustion zone, a radiation detector mounted opposite the output end of the light guide, a photo amplifier and a recorder with a timer, characterized in that in each hole of the light guide there is a microdose of the chemical compound of an additional alkaline group element with a volume of 0.0001 - 0.001 cm ³ , and between the output end of the light guide and a radiation receiver monochromatic filter with a transmission wavelength equal to the wavelength of the saturated central part of the resonant spectral line of the additional element.

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