SU1187022A1 - Apparatus for determining permeability to gas of porous materials - Google Patents

Abstract

A DEVICE FOR DETERMINING THE GAS-LIGHTING EQUIPMENT OF POROUS MATERIALS, comprising a measuring chamber for accommodating a test sample, a stabilized compressed air source connected to two symmetrically arranged tapering nozzles placed in the measuring chamber, a turbine-type flow sensor, placed in a measuring chamber, which has a surface, which has a surface area, which has a surface area, which has a surface area, which has a detachable nozzle. from different sides of the turbine-type flow sensor, a radiation source and a phototransmitter connected to the electronic input Measuring circuit, characterized in that, in order to expand the range of measuring gas permeability to small values and improve measurement accuracy, a calibrated orifice is made in the measuring chamber between the turbine-type flow sensor with the test sample, the first key, the control input which is connected to the output of the measurement time generator, and the pulse addition and subtraction circuit, counter, first c A coincidence, the output of which via a trigger is connected to the input of a single vibrator, a nonlinearity correction circuit and a digital indicator, the output of the pulse addition and subtraction circuit is connected to the input of the counter, the output of which is connected to the inputs of the nonlinearity correction circuit, the digital indicator and the first coincidence circuit, the output the one-shot is connected to the meter reset bus, the first and second outputs of the nonlinearity correction circuit are connected with the corresponding ones; the inputs of the pulse addition and subtraction circuit, while the nonlinearity correction circuit consists of a decoder of correction sites, at least two coincidence circuits, a second pulse body, the output of which is connected to the first and second outputs of the nonlinearity correction circuit through the second and third keys, and the input is connected to the outputs of the second and third matching circuits, the first inputs of which are connected to the input of the decoder of the correction section of the non-linearity correction circuit and connected to the input of the non-linearity correction circuit, the second inputs of the circuit coincidence and control inputs of the second and third keys are connected to the respective outputs of the decoder linearity correction portions.

Description

The invention relates to a means of measuring the characteristics of materials, in particular, porous compacted materials used in the foundry industry (molding and core mixtures) and in construction. The purpose of the invention is to expand the range of measurement of gas permeability towards small values of gas permeability and increase the measurement accuracy. Figure 1 shows a diagram of a device for determining the gas permeability of porous materials, figures 2 and 3 are graphs explaining the principle of correction of a non-linearity meter. The device contains a source of compressed air with pressure-stabilized test chamber 2, in which there is a seat made of elastic material on which the sleeve 4 is hermetically sealed with a standard mold 5 made of a molding mixture (of a different porous material) molded into it. In the chamber 2, there is an air flow concentrator, made of two nozzles 6 symmetrically located with the Oka-Irvcss, as well as a turbine-type air flow sensor, made in the form of a knuckle 7, fixed in the supports 8. The radiation source 9 and the phototransducer 10 are located on different sides of the curtain. In chamber 2, a calibrated orifice 11 (or choke), located after pin 7 along the air flow, is also completed. The phototransducer 10 is electrically connected to a pulse counting device containing a pulse former 12, connected via a switch 13, and a pulse addition and subtraction circuit 14 with a counter 15. 1 Clock 13 is controlled by a measurement former 16). The number in the counter 15 is highlighted on the digital indicator 17. The counter 15 is connected to the circuit 18 by subtracting the number containing the series 19 coincidental circuits, the trigger 20 and the single-vibrator 21. The counter 15 is also connected to the correction circuit 22 (and the nonlinearity containing the decoder 23 numbers plot, correction, coincidence circuit 24, pulse shaper 25, two switches 26 and 27 whose outputs are connected to the corresponding inputs of pulse addition and subtraction circuit 14. The device works as follows: Sleeve 4 with the molded standard The sample 3 from the molding sand is sealed onto the elastic seat. Place 3, after which the source 1 of compressed air is turned on, which injects air into the test chamber 2 under constant pressure. The air flow is concentrated by the nozzles 6 and rotates the impeller 7, After that, the light flux between the radiation source 9 and the phototransducer 10 repeatedly interrupts, due to which pulses 12 are generated by the shaper, which are transmitted through the switch 13 on. counter 15. Since the frequency of the pulses is proportional to the flow rate of air passing through chamber 2 and sample 5 (we assume opening 11 is closed), then the choice of time during which key 13 is opened (this time is set by measurement time generator 16) is obtained in numerical form, gas permeability of the test sample 5, which is illuminated on the digital indicator 17. If the gas permeability of sample 5 is small, then the torque of the crutch 7, created by the air flow, may be less than the moment of frictional rest force. This explains the presence of a dead zone in a known device. In order to get rid of the latter, a calibrated orifice (or choke) 11 is inserted into the device, which is made in the case of measuring chamber 2 above the wheel 7. Due to this, even at zero gas permeability of sample 5 (no air flow through the sample) a certain air flow passes through the test chamber . Since the air pressure is stabilized and the throttle 11 is calibrated, this flow rate has a well-defined value, which is chosen so that a reliable rotation of the impeller 7 is ensured. At the same time, a certain number is recorded in the pulse meter, and the readings are zero . Therefore, an initial number 18 subtraction circuit is introduced into the pulse meter. The code of the number to be subtracted is fed to the coincidence circuit 19 from the outputs of the counter 15. When this number appears in the counter, the coincidence circuit is triggered, after which the flip-flop 20 tilts and starts the one-shot 21, which generates a reset pulse to the counter 15. In other words, during the measurement, which is determined by the measurement time generator 16, the counter 15 records the number reduced by such an amount, the code of which is typed by wiring the coincidence circuit 19. Adjusting the zero readings of the device is done either by setting the appropriate code on the matching circuit 19 or adjusting the throttles 11. With this arrangement, the impeller 7 is in a rotary motion even at zero gas permeability of the sample 5, thus eliminating the effect of friction rest forces. Already at low gas permeability, the additional air flow through the sample is summed with the air flow through the throttle 11 and increases the rotational speed of the ratchet 7, which leads to the appearance of a number in the counter 15 after the end of the measurement time. This number corresponds precisely to the value of the additional flow through the sample, since the number corresponding to the flow through the choke 11 is subtracted from the readings. The accuracy of the gas permeability measurement is achieved in the proposed device by introducing, into the pulse-count meter of the nonlinearity correction circuit 22, which allows piecewise linear approximation characteristics. Its principle of operation of the circuit is explained using graphs (Fig. 2). The entire measurement range is divided into sections (for example, in Fig. 2, the range is divided into 5 sections). At the end of the first section, the measurement error is (. Formed (f corrective pulses that are generated near the input pulse. After each, i.e., the correction is, aN that after passing through the input pulse 1, the passage is denied.) 15 of one input pulse, i.e., one input pulse is crossed out. In the second section, the number of crossed out pulses is SL, cc are crossed out dN after every n input pulse. If in some area, for example, the third, (FIG. 2) it turns out that the rectification is not carried out in this area. In the fourth and fifth sections (Fig. 2) of the correction, the difference is 1/3 - "/ 4 and is positive, i.e. in these areas, the correction pulses do not cross out the input pulse, but add to the input The pulses, i.e., in the fourth section, each n, j and yi — the input pulse causes one additional correction pulse to be added to the counter 15, and in the fifth section an additional pulse is formed after the initial dN input pulse. In order to do this, it is necessary to define the number of the correction area, which, using the number code in the counter 15, determines the number of the area. A controlled frequency divider is also required, which provides an output pulse through each N or nj or Hj, etc. input pulses, which, depending on the area number, are either added to the number of input pulses of the counter 15, or they cross out the next input pulse. In the proposed device, in order to simplify the construction, instead of the controlled divider, counter 15 is used with coincidence circuits 24, to which the outputs of the corresponding triggers of counter 15 are connected. Depending on the section number, which is determined by the decoder 23 by the number code in counter 15, receive permission from decoder 23 corresponding schemes 24 matches. When trig is triggered

Claims (1)

DEVICE FOR DETERMINING GAS PERMEABILITY OF POROUS MATERIALS, containing a measuring chamber for accommodating the test sample, a stabilized pressure compressed air source connected to two symmetrically arranged tapering nozzles placed in the measuring chamber, a turbine type flow sensor located in the measuring chamber, the axis of which is vertical, and located From different sides of the turbine-type flow sensor, the radiation source and photoconverter connected to the electronic input an integrated circuit, characterized in that, in order to expand the range of gas permeability measurement to small values and increase the measurement accuracy, a calibrated hole is made in the measuring chamber between the turbine-type flow sensor and the test sample, and the electronic measuring circuit contains a first pulse shaper connected in series, the first key, the control input of which is connected to the output of the shaper of the measurement time, and a circuit for adding and subtracting a pulse, a counter, a first matching circuit, the output of which through the trigger is connected to the input of the single-vibrator, a nonlinearity correction circuit and a digital indicator, the output of the pulse adding and subtracting circuit is connected to the counter input, the output of which is connected to the inputs of the nonlinearity correction circuit, a digital indicator and the first coincidence circuit, the output of the single vibrator is connected to the bus counter reset, the first and second outputs of the nonlinearity correction circuit are connected to the corresponding inputs of the pulse addition and subtraction circuit, while the nonlinearity correction circuit consists of de the encoder of the correction sections of at least two coincidence circuits, a second pulse shaper whose output through the second and third keys is connected to the first and second outputs of the nonlinearity correction circuit, and the input is connected to the outputs of the second and third coincidence circuits, the first inputs of which are connected to linearity correction decoder input portions and connected to an input of circuit linearity correction, the second inputs of the coincidence circuits and the control inputs of the second and third keys are connected to the corresponding decoder ¹ outputs conductive and non-linearity correction sections. SU .... 1187022 1 1187022 2