SE500952C2 - System for measuring burning speed in solid gunpowder rod - involves using rod placed in combustion chamber, ignited at one end, time taken for flame front to move from one point to another being measured - Google Patents

Abstract

The flame front passge through the selected measurement points is recorded contact-free with fibre-optic indicators (7,8) arranged in the combustion chamber which via optic fibres (9,10) communicate with detector units (13,14) outside the combustion chamber. The detector units convert the recorded radiation pulses to electrical signals which are taken up on a multi-channel transient recorder (21). The detector units are high frequency and incorporate a photo diode and an amplification circuit. The detector units have their spectral sensitivity within a specific wavelength range for the frame being investigated. They consist of a p-i-n-photodiode, a wavelength filter and a photo-conductive amplification circuit. The photo diode has silicon as detector material.

Description

It is an object of the present invention to provide a method and system for measuring the burning rate of solid propellants, by which the above-mentioned disadvantages of prior art methods are eliminated.

This is achieved through the method and system defined by the claims.

According to the invention, there is provided a method and system for measuring the burning rate of solid propellants, wherein a propellant rod is arranged in a combustion chamber and ignites at one end and the time of movement of the flame front along a defined distance, from one measuring point to another, is measured. Characteristic of the invention is that the passage of the flame front of the selected measuring points is registered contactlessly with fiber optic sensors arranged in the combustion chamber, which communicate via optical fibers with detector units arranged outside the combustion chamber. The detector units convert the radiation pulses registered by the sensors into electrical signals.

A photodiode and a gain circuit are preferably used as the detector unit.

The signals from the detector units are recorded on a signal collecting and processing unit, with which the time of the flame front's passage of the respective measuring point is determined and the burning speed can be calculated.

The invention will be described in more detail below in connection with the accompanying figures.

Figure 1 schematically shows an embodiment of a system according to the invention for measuring the burning rate of solid propellants.

Figure 2 shows a detailed view of a measuring head with side-registering fiber-optic sensors.

Figure 3 shows an embodiment of a circuit diagram for a detector unit according to the invention.

Figure 1 thus shows a system according to the invention for measuring the burning rate of solid propellants. The system comprises a combustion chamber 1, a holder 4 for a propellant rod 5, an igniter device 6 - soo 952 for igniting the rod at one end and means for measuring the movement of the flame front a defined distance from one measuring point to another. The passage of the flame front of the selected measuring points is registered non-contact with fiber optic sensors 7 and 8, which are arranged in the combustion chamber. The sensors communicate via optical fibers 9 and 10 with detector units 13 and 14, which are arranged outside the combustion chamber. In the detector units, the registered radiation pulses are converted into electrical signals, which are fed via conductors 19 and 20 to a multi-channel transient recorder 21 on which the signals are registered as curve peaks. From these curve peaks, the time of the flame front's passage of the respective measuring point can be determined. Since the burning distance is known, the burning speed can be calculated. The transient recorder can also be arranged in a computer and evaluations of the signals are done with software.

According to a preferred embodiment of the invention, the sensors are mounted on a measuring head 2, as shown in more detail in Figure 2. The measuring head is intended to be inserted into the combustion chamber and fixed by means of a base part 3, e.g. screwed into the chamber wall. The holder 4 for the fuel rod and the ignition device 6 are also located on the measuring head. In the embodiment shown, side-registering fiber-optic sensors are used, which are mounted parallel to the fuel rod and very close to it, for example at a distance of 5 mm. The optical fibers from the sensors are arranged in the direction of the rod 5 and pulled out through the base part 3 of the measuring head. Sharp bending of the optical fibers can be avoided in this way and all functions are assembled and easily accessible on the detachable measuring head 2.

Side-registering fiber optic transducers suitable for use in the system according to the invention are commercially available, eg model E39-F2 from OMRON.

In the embodiment shown, the ignition device 6 consists of a filament ignition. Current supply to the filament takes place through two current conductors 11 and 12 which protrude from the base part of the measuring head and via lines 15 and 16 through the base part are connected to a current source. The ignition takes place in the part of the propellant rod furthest away from the base part 3. Ignition of the powder rod can also be done with a laser pulse, in which case an optical conductor is arranged in a corresponding manner to the ignition end of the rod. Laser ignition may in some cases be preferable, especially when time counts from the moment of ignition are to be measured. 5 oo 952 The optical fibers may be of the standard type which may be cut to suitable lengths. To protect the optical fibers from the flame and the corrosive environment, the parts inside the combustion chamber are insulated with metal housings 17 and 18, preferably of stainless steel.

The optical fibers are drawn through the base part of the measuring head to the detector units 13 and 14.

Each detector unit comprises a photodiode and a gain circuit. The detector unit is high frequency and has its spectral sensitivity within a wavelength range specific to the flame examined. By selecting detector material in the photodiode in combination with a wavelength filter, the spectral measuring range of the detector unit can be limited to a relatively narrow wavelength range specific to the flame examined. A distinct signal is obtained and high precision is achieved in determining the time of the flame's passage of the respective sensor.

Figure 3 shows a circuit diagram of a preferred embodiment of the detector unit. It consists of a silicon p-i-n photodiode 22, a wavelength filter, e.g. a Wratten filter, 23 and a photoconductive amplification circuit 24. The spectral sensitivity is in the wavelength range red / IR with a maximum of about 0.8_pm. The response time of the detector unit is better than 1_fls.

Due to the arrangement with the Wratten filter and the choice of silicon photodiode, the spectral measuring range is limited to the range 0.8 - 1.0_pm. This filters out unwanted background radiation and noise.

The electrical signals from the detector units are recorded on the transient recorder 21. Other ways of processing the electrical signals to obtain corresponding time information are conceivable. The combination of a high-frequency detector unit with its spectral sensitivity within a wavelength range specific to the current flame and a multi-channel transient recorder, however, has been shown to provide great accuracy in determining the time for the flame front to pass the respective measuring point.

The device is used as follows: A fuel rod is placed in the measuring head holder 4 and the filament is connected to the current conductors 15 and 16. The measuring head is then screwed into the combustion chamber wall and the wires 19 and 20 are connected to the transient recorder 21. The rod is ignited by supplying current through the wires 15.16. When the flame front passes the first fiber optic sensor 7, it will register the radiation and the radiation pulse is transported through the optical fiber 9 to the detector unit 13. In the detector unit the radiation is converted into an electrical signal which after amplification is recorded on the transient recorder. obtained. When the flame front passes the next fiber optic sensor 8, the corresponding registration takes place and a new curve peak is obtained on the transient recorder. The curve peaks are obtained along a time axis and the distance between them is the burning time. Since the burning distance is known, the burning speed can be calculated.

The system according to Figure 1 was tested and compared with the standard Crawford method. A relatively fast-burning and smoky powder was chosen. It was a composite powder containing approx. 20% highly terminated polybutadiene fuel and 80% ammonium perchlorate oxidizer. The fuel rods were 100 mm long and had a square cross section with the side 5 mm. To ensure linear propagation of the flame, the mantle surface of the rod was insulated with a polymer. The distance between the fiber optic sensors was 67 mm and the detector units were of the design described above in connection with Figure 3. The combustion chamber was pressurized with nitrogen to 5 MPa and the initial temperature was 20 ° C. A total of 8 measurements were made, 4 with each method. The results are shown in Table 1.

Table.

Test Method Burning distance Burning time Burning speed no. (mm) (s) (mm / s) 1 Crawford 67 2.65 25.3 2 "67 2.56 25.8 3" 67 2.72. 24.8 4 "67 2.60 25.4 X = Zsšâ Zåeí S = 9291 Qsíê 5 Enl.uppf. 67 2.78 24.1 6" 67 2.75 24.4 7 “67 2.70 24.8 8" 67 2.70 24.5 x = gålå 24.3 S = 0.04 0.3 sno 452 ¥ x = average value s = standard deviation The standard deviation (s) was significantly smaller in the measurements according to the invention than in the measurement according to the Crawfort method, despite the fact that the burning times in this comparison were relatively long.

Claims (15)

# 500,952 Claims: A method of measuring the burning rate of solid fuels, wherein a fuel rod (5) is arranged in a combustion chamber (1) and ignites at one end and that the time for the movement of the flame front is a defined distance from one measuring point to another, characterized in that the flame - the passage of the selected measuring points is registered without contact with fiber-optic sensors (7,8) arranged in the combustion chamber which communicate via optical fibers (9, I0) with detector units (13,14) arranged outside the combustion chamber. Method according to Claim 1, characterized in that the detector units convert the recorded radiation pulses into electrical signals which are recorded on a multi-channel transient recorder (21,3l). 3. A method according to claim 1, characterized in that the detector unit is high frequency and comprises a photodiode and a gain circuit. 4. A method according to claim 3, characterized in that the detector unit has its spectral sensitivity within a wavelength range specific to the examined flame. Method according to Claim 4, characterized in that the detector unit consists of a p-i-n photodiode (22), a wavelength filter (23) and a photoconductive amplification circuit (24). Method according to claims 3-5, characterized in that the photodiode has silicon as detector material. A system for measuring the burning rate of solid propellants, which system comprises a combustion chamber (1), a holder (4) for a propellant rod (5), ignition device (6) for igniting the rod at one end thereof and means for measuring the time for the movement of the flame front a defined distance from one measuring point to another, characterized by fiber optic sensors (7,8) arranged in the combustion chamber with which the flame front's passage of the selected measuring points is registered without contact and detector units arranged outside the combustion chamber (13,14) optical fibers (9,10) communicate with the sensors. soo ešz> 8 System according to claim 7, characterized in that the fiber-optic sensors and the optical fibers emanating from them are arranged on a measuring head (2) which also comprises the holder (4) for the fuel rod (5) and which measuring head is intended to be introduced into the combustion chamber and while a base (3) is fixed in the chamber wall. System according to claim 8, characterized in that the fiber optic sensors are side-registering sensors (7,8) which are mounted in parallel with the drive rod and that the optical fibers (9,10) from the sensors are arranged in the direction of the rod and pulled out through the base of the measuring head. . System according to Claim 9, characterized in that the optical fibers arranged on the measuring head are surrounded by protective metal housings (17, 18). System according to claim 7, characterized in that the detector unit is high-frequency and comprises a photodiode and a gain circuit. System according to claim 11, characterized in that the detector unit has its spectral sensitivity within a wavelength range specific to the examined film. System according to claim 12, characterized in that the detector unit consists of a p-i-n photodiode (22), a path length filter (23) and a photoconductive amplification circuit (24). 14. A system according to claims 11-13, characterized in that the photodiode has silicon as detector material1. System according to claim 7, characterized by a four-channel transient recorder (21, 31) on which the radiation pulses converted in the detector units to electrical signals are registered.