SE505241C2 - Method and apparatus for determining the moisture content of a material - Google Patents

Abstract

PURPOSE: To at a high speed and continuously measure water content of a material by a method in which a microwave signal is fed into the material and the speed change of the signal passed is measured, based on the known interdependent relationship between the speed change of the signal and the water content of the material. CONSTITUTION: A directionality coupler 6 divides a microwaver signal into a first component I and a second component II, and the component I is fed to a transmitter 7 and the signal is fed into a material to be measured. A receiver 8 receives a microwave signal I passed through the material to be measured. The transmitter 7 and receiver 8 are disposed counter to each other across the material. On the way of passing the material, the signal I is decelerated more than the signal component II used as the reference amount in a mixer 9, and delayed in a time manner. The mixer 9 mixes the signals I, II to generate an intermediate frequency signal Δf, which is fetched out from an output gate IF to measure frequency of the signal Δf in a counter 3. Water content of the material to be measured can be acquired from this frequency based on the known interdependent relationship between the signal Δf and the water content.

Description

505 241 2 v = c / »Aff + lgh / z * <1) u '----- \ dar ler': ßrlz + erl | 2 5, '= the real part of the relative dielectric constant of the material. eQ '= the imaginary part of the relative dielectric constant of the material. c = speed of light.

The dielectric constant of water is large compared to the dielectric constant of most other materials, which is why the speed of a microwave passage through a damp material decreases more than the speed of a path passing through a dry material. This makes it possible to measure the moisture content of the material. The time delay 6 caused by the decrease in the speed of the road can be calculated from the formula (2) below: = d / v = d / (c / yKer '+ | er |) 2) * (2) where 6 = the time delay = the distance that the microwave moves in the material v = velocity of the microwave in the material er '= the real part of the relative dielectric constant of the material Q = the relative dielectric constant of the material.

In the method according to the present invention for determining the moisture content of a material, a microwave signal is passed through the material to be measured, the change in the speed of the signal passing through the material being measured and the moisture content of the material being determined on the basis of the measured change and a known relationship between the changes in the velocity of the microwave signal and the moisture content of the material.

According to one embodiment of the method, the change in the speed of the microwave signal is measured by means of frequency modulation, the transmission time of the microwave pulse, expansion or pulse sequence or noise correlation.

According to one embodiment of the method, the transmission time of the microwave pulse, the expansion or the sequence of the pulse which has passed through the material, is measured in a constant measuring gap.

According to one embodiment of the method, the transmission time in the measuring gap is measured directly, using a clock, such as constituting the time interval between the transmitted and received microwave pulses, the expansion or the pulse sequence.

According to one embodiment of the method, the transmission time of a continuous or intermittent pulse type or pulse sequence type microwave signal which has passed through the material to be measured can be determined by using correlation techniques, i.e. by emitting broadband noise or by modulating the random noise signal or digital random signals and determination of the transmission time by the cross-correlation function of the transmitted and received signals.

According to one embodiment of the method, the change that occurs in the speed of the microwave signal as it passes through the material to be measured is determined by frequency modulation, whereby a microwave signal is generated, the frequency of the microwave signal being varied according to a mathematical function from the lower limit to the upper limit. its frequency range and / or vice versa within a certain time period T, the microwave signal being divided into a first and a second component, the first component being transmitted through the material at the measuring point, the first component passing through the material being mixed with the second component, a intermediate frequency signal ¿\ f corresponding to the delay, is formed by the mixed signal thus obtained, and the moisture content of the material is determined during measurement of the signal ¿; f on the basis of a known relationship between the moisture content and the intermediate frequency signal A f. 505 241 The intermediate frequency as follows: A f = B ~ d ~ ((e, '+ | e, |) / 2) ä / uc) (3) where B = fz-fl = the sweep width (the width of the band within which the frequency varies) fl = the lower limit of the sweep band = the lower frequency fz = the upper limit of the sweeping band = the higher frequency d = the travel distance of the microwave in the material er '= the real part of the relative dielectric constant in the material sr = the relative dielectric constant in the material T = the sweeping time c = the speed of light Table 1 shows typical intermediate frequency values A f for certain materials obtained from formula (3). The _parameters used are B = 2 GHz, T = 10 ms, d = 30 cm and c = I108nVs.

Material ef 'ef' 'A f (Hz) Water 80 5 1788 Moist wood 23 2.5 959 Dry wood 3 0.1 346 Air 1 0 200 Table 1. Calculated_A f values for different materials.

It can be read from the table that the dielectric constant for water is high in comparison with the dielectric constants of the other materials. Therefore, the intermediate frequency is higher in the case of damp wood than in the case of dry wood.

The moisture content of a given material is determined by the frequency of the intermediate frequency signal A f either by calculation or by graphical means, provided that the relationship between the moisture content of the material and the frequency of the intermediate frequency signal is known. This relationship can be determined by performing several measurements using the method and device according to the invention on a material whose moisture content is known or is to be measured. Based on the measurement result, a function is formed that describes the relationship between the two quantities. This function is then used in measurements performed using the method and device according to the invention to determine or calculate the moisture content of the materials. The communication function can be included in a computer program that calculates the final value of the moisture content.

According to one embodiment of the method, the frequency of the microwave signal is continuously and cyclically varied from the lower frequency f1 to the upper frequency fz and then from the upper frequency fz to the lower frequency fr. According to one embodiment of the method, the material to be measured consists of a material stream, such as wood chips, a paper web or a water suspension, for example chemical or mechanical wood pulp, which is passed through a measuring gap.

According to an embodiment of the method, the determination of the moisture content is implemented as a continuous measurement process.

The device according to the invention consists of a transmitter device which emits a microwave signal through the material to be measured, and a detection device and a counting device which measures the change in speed of the signal transmitted through the material and determines the moisture content of the material based on a known relationship in the change. speed of the microwave signal in question and the change in moisture content of the material.

According to an embodiment of the advertisement according to the invention, the transmitter device consists of an oscillator, which is arranged to generate a signal with a frequency in the microway range and to vary the signal frequency from a lower frequency fl to an upper frequency fz and / or vice versa within a given time period T according to a mathematical function, an isolator, arranged to transmit the signal in the oscillator circuit in only one direction, a direction switch, arranged to divide the signal into a first component and a second component and a transmitter (e.g. a transmitting antenna) arranged to transmit the first signal component, which obtained from the directional coupler, by the material to be measured: the detection device consists of a receiver (eg a receiver antenna) arranged to receive the first signal component after it has passed through the material to be measured, a mixer provided with a first input port , a second input port and an output port and set up to receive the first component from the receiver via its first input port and the second component directly from the directional coupler via its second input port and mixing the signals supplied to the input ports, to provide from the signal thus formed an intermediate frequency signal corresponding to the delay and output it through the output port: and counting oscillator and measuring the frequency of the intermediate frequency signal obtained from the output port of the mixer and determining the value of the moisture content of the material during measurement from the intermediate frequency signal on the basis of a known relationship between the signal and the moisture content.

According to an embodiment of the device, the transmitter and receiver are arranged on different sides relative to the material during the measurement.

According to an embodiment of the device, the transmitter and the receiver are on the same side relative to the material to be measured and a reflector plate is arranged on the opposite side to reflect the microwave signal emanating from the transmitter for returning it to the receiver after having passed through the material.

According to an embodiment of the device, the counting device is arranged to control the oscillator so that the frequency of the microwave signal is continuously varied from the lower frequency f1 to the upper frequency fz and then from the upper frequency fz to the lower frequency fr According to an embodiment of the device the device is provided with a first electrical line, a second electrical line, and a third electrical line, the first electrical line conducts the microwave signal from the directional coupler to the second input port. In the mixer, the second electrical line conducts the signal from the directional coupler to the transmitter, and the third electrical line leads the signal from the receiver to the first input port of the mixer, the lengths of the first, second and third electrical cables being selected so that the frequency of the intermediate frequency signal is within a range which is technically easy to measure. The frequency of the intermediate frequency signal can also be adjusted to the desired level by changing the sweep width (B), the sweep time (T) or the distance (d) traveled by the microwave in the material during measurement.

According to known technology, the so-called microwave frequency modulation technology (FM-CW) has been used for short-range radar applications, for example for measuring the level of a surface or the thickness of ice.

Such applications are described, for example, in the following publications: "An FM Radar for Accurate Level Measurements", 9th European Microwave Conference, Brighton 1979, pages 712-715, and Jakkula P., Ylinen P., Tiuri M .: "Measurement of Ice And Frost Thickness with an FM-CW Radar ", 10th European Microwave Conference, Warsaw 1980.

In these prior art radar applications, the distance between the measuring object and the radar transmitter / receiver varies, the material, usually air, between the transmitter / receiver and the reflecting object remaining unchanged with respect to the microwave.

According to the present invention, the microwave frequency modulation technique (FM-CW technique) can be used in a completely new field of application, i.e. measuring the moisture content of a material where it has never been applied before.

The invention has the advantage that the moisture measurement can be carried out very quickly and continuously, for example in the case of a moving material stream. Thus: the measurement results can be used for real-time control of continuous processes.

A further advantage of the invention is that the output signal which is measured can be easily processed or consists of an expansion signal, the frequencies of which can be easily measured and do not necessarily place particularly high demands on the electronics used in the device.

The invention makes it possible to utilize all the advantages of the FM-CW technology in connection with the measurement of the moisture content of the materials.

In the following, the invention will be described in detail with reference to the accompanying drawing, in which Fig. 1 illustrates the circuit test according to the invention, Fig. 2 illustrates the circuit principle of another embodiment of the device according to the invention, Fig. 3 shows the oscillator frequency and mixer output in the device according to Figs. Fig. 4 shows a detail of the time, Fig. 4 shows a detail of a third embodiment of the device according to the invention, and Fig. 5 shows measurement results obtained with a fourth embodiment of the method and apparatus according to the invention. The measuring device shown in Fig. 1 emits a microwave signal through the material during measurement, measuring the change in velocity of the signal which has passed through the material and determining the moisture content of the material on the basis of a known relationship between the velocity change of the microwave signal in question and the change. in moisture content of the material. The device consists of a transmitter device 1, a detection device 2 and a counting device 3. The measurement of the speed change can be based on frequency modulation or on the transmission time or the noise correlation in a microwave pulse, expansion or pulse sequence.

In the second embodiment of the device according to the invention, shown in Figs. 2, a microwave signal is similarly transmitted through: the material, using the frequency modulation device measuring the change in velocity of the signal which has passed through the material and determining the moisture content of the material on the basis of a known relationship between the change in velocity of the microwave signal and the change in the moisture content of the material.

The device consists of a transmitter device 1, a detection device 2 and a counting device 3.

The transmitter device 1 consists of an oscillator 4, an insulator 5, a directional coupler 6 and a transmitter 7. The detection device 2 consists of a receiver 8 and a transmitter 9.

Oscillator 4 generates a signal with microwave frequency. Controlled by the counter 3, the oscillator changes the signal frequency in a linear relationship over a certain frequency range within a certain time period. Then the signal frequency changes again linearly from the upper limit of the range to its lower limit. These cyclical variations are continued without interruption.

The isolator 5 ensures that the microwave signal is only allowed to move in one direction in the oscillator circuit. 10 505 241 The directional switch 6 divides the microwave signal into a first component I and a second component II. The first component I of the microwave signal is passed through the second electrical line 12 to the transmitter 7.

The transmitter 7 transmits the signal through the material during measurement.

The receiver 8 receives the microwave signal I which has passed through the material during measurement. The transmitter and receiver are located on opposite sides of the material. On its way through the material, the signal I is retarded and is delayed in comparison with the second microwave signal component II which was used as a reference quantity in the mixer 9.

The mixer consists of a first input port RF, a second input port LO and an output port IF. The second input port LO of the mixer is fed by the second signal component II, which is supplied directly from the directional coupler 'via line 11. The first input port RF of the mixer 9 is fed by means of the first signal component 1, which is supplied by the receiver via line 13.

In the mixer, the signals I and II which are applied to its input ports RF and LO are mixed. From the signal thus obtained, the mixer generates an intermediate frequency signal A f, which is obtained from the output port IF.

By appropriately selecting the lengths of the electrical lines 11, 12 and 13, the intermediate frequency signal_A f is adjusted to each other in the delay to a level which allows technically simple measurement.

The counting device 3 measures the frequency of the intermediate frequency signal A, f obtained from the output port IF in the mixer. The value of the moisture content of the material during measurement can be determined from this frequency on the basis of a known relationship between the intermediate frequency signal_A f and the moisture content. For a given material, when this relationship is known, the value of the moisture content is obtained either by calculation or by graphic means.

The relationship can be determined by performing several measurements using the method and device according to the invention on a material with known values for the moisture content. Based on the measurement results, a function is formed that describes the relationship between the quantities. This function is then used in calculating the value of the moisture content of the materials in measurements performed by the method and device according to the invention.

Fig. 3a shows a curve representing the frequency of the microwave signals at the first input port RF and at the second input port LO in the mixer 9. The signal frequency varies from a lower frequency f1 to a higher frequency fz during a time period T, the rise of the change being constant.

The signal I, which is applied to the first input port RF in the mixer, is delayed by a time length 6 as compared with the signal II which is applied to the second input port LO. The continuous line represents the signal II at the input port LO while the broken line represents the signal I at the first input port RF. The time difference 6 arises from the fact that the microwave signal is delayed on its way from the transmitter 7 to the receiver 8. From the signals I and II the transmitter generates an intermediate frequency signal A f which is proportional to the moisture content of the material during measurement.

The curve in Fig. 3b represents the amplitude of the intermediate frequency signal A f as a function of time.

Fig. 4 shows an embodiment in which the transmitter 7 and the receiver 8 are placed on the same side of the material during measurement with a reflector plate 10 arranged on the opposite side. The plate reflects the microwave signal transmitted by the transmitter 7 to the receiver 8.

Fig. 5 presents the results of measurements on wood chips. These measurements were performed by the method of the invention to determine the relationship between the moisture content and the frequency of the intermediate frequency signal. The measurement parameters were B = 0.9 GHz, T = 11.1 ms and d = 5 cm. The measurements were performed on wood chips with six different known values of moisture content, so that the corresponding six frequencies of the intermediate frequency signal Alf were obtained. Due to the desire to express the moisture content of wood chips in terms of weight percent at each measuring point, the frequency values were divided by the density of the sample during measurement, thereby eliminating the effects of different densities on the results.

The figure presents the measurement results and the connection function obtained from them, in the form of a curve. The vertical axis represents the frequency of the intermediate frequency signal _A f divided by the density of the material being measured. The horizontal axis represents the moisture content of wood chips in terms of weight percent. The data for wood in Table 1 include the size class that refers to solid wood and are therefore not comparable with the results in Fig. 5 which are measured on wood chips.

The present invention is not limited to the embodiments described above, but instead several variations may be possible within the scope of the appended claims.

Claims (9)

505 241 B Patent claims A method for determining the moisture content of a material, in which method a microwave signal is passed through the material to be measured, characterized in that the change in speed of the signal which has been moved through the material is measured by frequency modulation, whereby a microwave signal generated, the frequency of which is varied according to a mathematical function from a lower limit f, to an upper limit fz of its frequency range and / or vice versa within a predetermined time period T, the microwave signal being divided into a first component and a second component, the the first component is emitted by the material at the measuring point and, after passing through the material, is mixed with the second component, an intermediate frequency signal Af corresponding to the delay formed by the mixed signal thus obtained, and the moisture content of the material being measured by the signal Af based on a known relationship between the moisture content and the intermediate frequency the signal Af. Method according to claim 1, characterized in that the frequency of the microwave signal is varied continuously and cyclically from the lower frequency f1 to the upper frequency fz and then from the upper frequency f, to the lower frequency fr. A method according to claim 1 or 2, characterized in that the material to be measured is caused to pass through a measuring gap and consists of a material stream, such as wood chips or an aqueous suspension, for example chemical or mechanical wood pulp. Method according to one of Claims 1 to 3, characterized in that the determination of the moisture content is implemented as a continuous measurement process. 505 241 s H Device for determining the moisture content of material, characterized in that it consists of a transmitter device (1) which transmits a microwave signal through the material to be measured, which transmitter device (1) consists of an oscillator (4) arranged generating a signal with a frequency in the microwave range and varying the signal frequency from a lower frequency f, to an upper frequency fz and / or vice versa within a given time period T according to a mathematical function, an isolator (5) arranged to input the signal into the oscillator circuit ( 4) in only one direction, a directional coupler (6) arranged to divide the signal into a first component (I) and a second component (II), and a transmitter (7) arranged to transmit the first signal component obtained from the directional coupler through the material to be measured; a detection device (2), which consists of a receiver (8) arranged to receive the first signal component (I) after it has been moved through the material to be measured, a mixer (9) arranged with a first input port (RF), a second input port (LO) and an output port (IF) and arranged to receive the first component (I) from the receiver (8) via the first input port (RF) and the second component (II) directly from the directional switch (6) via. its second gateway (LO) and. mixing the signals applied to the input ports (LO) and (RF) to generate from the signal thus formed an intermediate frequency signal Af corresponding to the delay and outputting it through the output port (IF); and a counting device (3), which is arranged to control the oscillator (4) and to measure the frequency of the intermediate frequency signal Af obtained from the output port (IF) of the mixer (9) and to determine the value of the moisture content of the material while measuring the intermediate frequency signal on basis of a known relationship of the signal Af and the moisture content. Device according to claim 5, characterized in that the transmitter (7) and the receiver (8) are located on different sides of the material to be measured. ,, sos 241 Device according to claim 5 or 6, characterized in that V, that the transmitter (7) and the receiver (8) are located on the same side in relation to the material to be measured and that a reflector plate (10) is set up on the opposite side to reflect the transmitted microwave signal to the receiver. Device according to one of Claims 5 to 7, characterized in that the counting device (3) is arranged to control the oscillator (4) so that the frequency of the microwave signal is varied continuously and cyclically from the lower frequency fl to the upper frequency fz and then from the upper frequency fz to the lower frequency fr Device according to any one of claims 5-8, characterized in that the device is provided with a first electrical line (11), a second electrical line (12) and a third electrical line (13) of which it the first electrical line (11) leads the microwave signal from the direction switch (6) to the second input port (LO) in the mixer (9), the second electrical line (12) leads the signal from the direction switch to the transmitter (7) and the third electrical line ( 13) leads the signal from the receiver (8) to the first input port (RF) of the mixer, the lengths of the first, second and third lines being such that the frequency of the intermediate frequency signal Af is within a range which is technically easy to measure.