JPH0376412B2 - - Google Patents

Description

Detailed description of the invention [Technical field to which the invention pertains] The present invention condenses water vapor in the gas to be measured on a cooled mirror surface with which the gas to be measured comes into contact, detects reflected light from the mirror surface, and detects the reflected light from the mirror surface. This invention relates to a dew point meter that measures dew point from temperature. In particular, the present invention relates to a dew point meter that can identify when frost has formed on a mirror surface.

[Description of prior art]

When the mirror surface that comes into contact with the gas to be measured is cooled, dew condensation occurs on the mirror surface. This dew condensation can be detected by a photoelectric conversion system using reflected light from the mirror surface, and the dew point can be measured. Conventional devices are configured to measure the temperature of a mirror surface by finding a state in which there is no increase or decrease in dew condensation on the mirror surface, that is, an equilibrium state in which light reflected from the mirror surface does not change.

Such a device has the disadvantage that the measurement error becomes large when the dew point is in the range of approximately 0 to -20°C. In other words, in this temperature range, dew condensation takes the form of either dew (water droplets) or frost (ice). In this temperature range, even if an equilibrium state is created and the temperature is detected, the dew point will not be accurate. Depending on whether the condensation is dew or frost, the measured dew point temperature is approximately 0.5 to 3
A difference in temperature occurs. In conventional devices, this difference was considered to be included in the error range. Furthermore, when the temperature is low, that is, below -20°C, dew condensation becomes frost, so in this case, calibrating everything as frost will eliminate errors.

[Purpose of the invention]

An object of the present invention is to provide a dew point meter that can accurately measure dew point by identifying whether condensation is dew or frost.

[Features of the invention]

The device of the present invention is configured so that the temperature of the mirror surface is controlled by an electronic cooling means, and the control means for controlling this control current is controlled so that an increase or decrease in the amount of dew condensation is in an equilibrium state, as shown in the flowchart of FIG. Means to determine whether the measured temperature is below 0°C Change the cooling current by a predetermined amount (ΔI) for a predetermined time (t ₁ ) when it is determined that the measured temperature is below 0°C Means The present invention is characterized in that it includes means for transmitting a frost signal when a large change in the reflected light is not detected due to this change.

Preferably, the control means is implemented by a microcomputer program.

It is preferable that the frost signal is displayed by a luminescent display or other display means.

The dew point display can be configured to automatically correct when a frost signal is sent.

[Explanation based on examples]

FIG. 2 is a block diagram of an apparatus according to an embodiment of the present invention. The dark box 1 is a light-tight sealed box, and is configured so that the gas to be measured flows in through an inlet 2 and the gas inside the box flows out through an outlet 3. A mirror surface 4 is provided inside the dark box 1 so as to be in contact with the gas to be measured, and this mirror surface 4 is configured to be cooled by an electronic cooling device 5. Electronic cooling device 5
A cooling current I is supplied from outside the dark box 1. A resistance temperature detector 6 is provided in contact with the mirror surface 4 , and a resistance measurement lead wire of the resistance temperature detector 6 is connected to a temperature measurement device 7 placed outside the dark box 1 . The mirror surface 4 is irradiated with the output light of the light emitting element 9, and the mirror surface 4
The reflected light is configured to be incident on the light receiving element 10.

Inside the dark box 1, a mirror surface 12 which is not cooled is separately provided as a reference, and the mirror surface 12 is also irradiated with the output light of the light emitting element 13, and the reflected light is made to enter the light receiving element 14. The outputs of the light receiving elements 10 and 14 are respectively connected to two inputs of a comparison circuit 15. The output of the comparison circuit 15 is connected to one input of the differential amplifier circuit 16. The output of the differential amplifier circuit 16 is connected to the base input of the transistor 17. The collector of the transistor 17 is connected to the power supply terminal +V, and is configured to provide a cooling current for the electronic cooling device 5 from its emitter.

Furthermore, the output of the temperature measuring device 7 and the output of the comparison circuit 15 are connected to the input of the analog-to-digital converter 19, and the output of the analog-to-digital converter 1
The output of 9 is connected to the input of microcomputer 20. The cooling current control output of this microcomputer 20 is connected to the input of a digital-to-analog converter 21, and the output of the digital-to-analog converter 21 is connected to the other input of the differential amplifier circuit 16.

The frost signal output of the microcomputer 20 is connected to the base of a transistor 23, and the collector of this transistor 23 is connected to a light emitting diode 24 for displaying the frost signal.

The operation of the circuit configured in this way will be explained.
In the absence of the cooling current I, the mirror surfaces 4 and 12 are in the same state and reflect all of the output light from the light emitting elements 9 and 13, respectively. The amount of light incident on the two light receiving elements 10 and 14 is equal, and the comparator circuit 15
has no output signal. When power +V is supplied and the output of the digital-to-analog converter 21 is increased, a cooling current I flows and the electronic cooling device 5 turns into a mirror surface 4.
to cool down. When the temperature of the mirror surface 4 reaches the dew point of the gas to be measured in the dark box 1, dew condensation occurs on the mirror surface 4. As a result, the amount of reflected light reaching the light receiving element 10 is reduced, and an output signal is sent to the comparison circuit 15. This output signal is input to the differential amplifier circuit 16,
It acts to reduce the emitter output cooling current I of transistor 17. Therefore, the amount of dew condensation on the mirror surface 4 is reduced. Through this loop control, the amount of dew condensation increases or decreases to a balanced state. At this time, the microcomputer 20 stops increasing the output of the digital-to-analog converter 21. If the temperature of the temperature measuring device 7 is measured in this equilibrium state, the temperature will indicate the dew point.

At this time, the apparatus of the present invention performs the following operation in order to identify whether the condensation on the mirror surface 4 is dew (water droplets) or frost (ice).

The microcomputer 20 takes in the output of the temperature measuring device 7 via the analog-to-digital converter 19. It is determined whether this output temperature is below 0°C. When this temperature exceeds 0° C., no frost forms on the mirror surface 4, so the output of the digital-to-analog converter 21 continues to send out a constant value. When it is determined that the output temperature is 0° C. or lower, the control output is changed by a predetermined amount for a short predetermined time _t1 , and the cooling control current I is changed by ΔI. By changing ΔI in the negative direction,
It is preferable to increase the temperature of the mirror surface 4. After time _t1 has elapsed, the cooling control current I is returned to its original value. In this example, _t1 is 5 seconds and ΔI is -1%.

At this time, the microcomputer 20 converts the comparator circuit 1 through the analog-to-digital converter 19.
5 is taken in, and changes in the output of this comparison circuit 15 are observed. When the condensation is frost, this output changes little. However, when the condensation is dew, this output changes significantly. This is because when dew condensation is frost, the state of the condensation does not change unless energy equivalent to the heat of melting ice is applied, but when dew condensation is frost, even a relatively small amount of energy can cause some of it to vaporize. This is thought to be because the state of dew condensation changes.

In the example, when the cooling current is changed by -1%, almost no change is observed when the dew condensation is frost, but when the dew condensation is frost, the output of the light receiving element 10 changes by about 50%, making identification possible with extremely high sensitivity. We were able to.

Practically speaking, it is preferable to set a range of change in the output of the light receiving element 10 in advance, and if the change is within this range, it is determined that it is frost.

When it is determined that the dew condensation is frost, the microcomputer 20 sends a frost signal to the transistor 23, and the light emitting diode 24 lights up. Thereby, the measurer knows that frost is condensing, and performs frost correction based on the measurement results of the temperature measuring device 7.

Furthermore, as shown by the broken line in FIG. 2, a frost signal can be sent to the temperature measuring device 7 to automatically correct the displayed temperature to reduce errors caused by frost.

In the above example, it was explained that dew or frost identification is performed when the temperature is below 0℃, but when the temperature is below -20℃, dew condensation becomes frost, so it is not necessary to identify dew or frost in this case. without performing any identification.
Dew condensation may be treated as frost.

The time t ₁ and the amount of current change ΔI shown in the above example are all examples, and the optimum values can be set depending on the state of the apparatus, the state of the gas to be measured, and so on.

[Explanation of effects]

As described above, according to the present invention, it is possible to identify with high sensitivity whether dew condensation is frost or dew. This has the excellent effect of reducing the measurement error of the dew point meter.

[Brief explanation of drawings]

FIG. 1 is an operational flowchart of the control means of the present invention. FIG. 2 is a configuration diagram of an apparatus according to an embodiment of the present invention. 1...Dark box, 2...Inlet of gas to be measured, 3...
Outlet of gas to be measured, 4... Mirror surface, 5... Electronic cooling device, 6... Measuring resistor, 7... Temperature measuring device,
9... Light emitting element, 10... Light receiving element, 12... Mirror surface for reference, 13... Light emitting element, 14... Light receiving element, 15... Comparison circuit, 16... Differential amplifier circuit,
17...Transistor for controlling cooling control current,
19...Analog-digital converter, 20...
Microcomputer, 21...Digital/analog converter, 23...Transistor for frost signal control, 24...Light emitting diode, 25...Start signal input terminal, I...Cooling current.

Claims (1)

[Claims] 1. A dark box into which a gas to be measured is supplied;
The inside of this dark box includes a light emitting element, a mirror surface that comes into contact with the gas to be measured and reflects the output light of the light emitting element, a light receiving element that receives the reflected light of this mirror surface, and a light receiving element that receives the reflected light from this mirror surface. An electronic cooling means for condensing water vapor in the measurement gas on the mirror surface, and further controlling the cooling current of the electronic cooling means in accordance with the output of the light receiving element so that the increase or decrease in condensation is in an equilibrium state. A dew point meter comprising a control means and a temperature measurement means for measuring the temperature of the mirror surface, and configured to determine the dew point from the temperature measured by the temperature measurement means, the control means including a temperature measurement means for measuring the temperature of the temperature measurement means. A means for determining whether the temperature is below 0°C; and when the means determines that the measured temperature is below 0°C, the cooling current is changed by a predetermined amount (ΔI) for a predetermined time (t ₁ ). and means for transmitting a frost signal when a change in the output of the light receiving element due to the change is less than a predetermined value. 2. The dew point meter according to claim 1, which includes means for displaying a frost signal. 3. The dew point meter according to claim 1 or 2, including means for automatically correcting the dew point display when a frost signal is sent.