JP2005055246A - Gas sampler - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas sampler capable of preventing the surface of a catalyst from being deteriorated by the drain caused by the dew condensation in each pretreatment part immediately after an energization or catalytic efficiency is deteriorated by the oxidation of a catalyst caused by the suction of the atmosphere at the time of stop of a boiler. <P>SOLUTION: In a gas sampling flow channel 4 equipped with a pretreatment part 8 for performing the pretreatment of the sample gas S supplied to a gas analyzer 5, three-way changeover valves 9 and 10 are respectively provided on the upstream and downstream sides of the pretreatment part 8 and connected so as to bypass the pretreatment part 8. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a gas sampling apparatus having a sample gas pretreatment section having a long life, such as a NOx converter catalyst.

JP 2002-148193 A

Conventionally, in order to measure the concentration of nitrogen oxides (NOx) contained in the exhaust gas discharged from boilers such as thermal power plants and factories, the exhaust gas is sampled from the flue and the concentration of NOx contained in this is sampled. An exhaust gas analyzer that uses a gas analyzer for measurement is used. In addition, the exhaust gas sampling apparatus includes a NOx converter catalyst that converts nitrogen dioxide (NO ₂ ) into nitrogen monoxide (NO), a mist catcher, an ammonia scrubber, a chlorine scrubber, etc. as a pretreatment unit for pretreating sample gas. Often provided.

  However, it has been unavoidable that the pretreatment parts are deteriorated due to various disturbance effects. For example, in the case of a NOx converter catalyst, there is one in which activated carbon is impregnated with a chemical agent such as a molybdenum compound, a manganese-potassium compound, and phosphoric acid, which has a predetermined life. When the pretreatment unit is deteriorated, there is a trouble that the measured value data of NOx includes an error. Therefore, it is desirable to replace the pretreatment unit at a cycle as early as possible. Since the processing unit is relatively expensive, there is a problem that the running cost is increased if the processing unit is frequently replaced.

  On the other hand, as shown in Patent Document 1, it is considered to use the catalyst to the maximum extent by accurately determining the degree of deterioration of the catalyst and using it to the limit of the allowable range. .

  By the way, in the pretreatment unit using a long-life packing such as a NOx converter catalyst, the occurrence of condensation is a major cause of deterioration. Generally, the exhaust gas flowing through the flue is, for example, about 50 ° C. saturation. Since it has a high humidity, the surface of the catalyst may be washed by, for example, dew condensation occurring in the NOx converter catalyst, and the activated carbon surface may be exposed, resulting in a decrease in catalyst efficiency and life. Therefore, it is possible to prevent the occurrence of condensation in the pretreatment unit by providing a drain separator using an electronic cooler or the like in the gas sampling device or attaching a heater to the pretreatment unit such as a NOx converter catalyst. Has been done.

  The exhaust gas analyzer having the gas sampling device described above is designed on the assumption that continuous measurement is performed under a stable condition free from the influence of disturbance. However, the user is not limited to using this continuously, for example, a boiler 1 There are cases where the vehicle is operated for 8 hours a day or stopped on Saturdays or Sundays, which may accelerate the deterioration of each part constituting the gas sampling device.

  In other words, immediately after the start of energization of the gas analyzer including the gas sampling device, a predetermined time is required after the energization is started so that the sample gas can be sufficiently dehumidified by the drain separator using the electronic cooler or the like. there were. In addition, a predetermined time is required for the heater provided in the pretreatment unit to become high enough to prevent condensation. On the other hand, with the operation of the suction pump immediately after the start of energization, a predetermined flow rate of sample gas is sucked into the gas sampling device to form a stable flow of sample gas.

  For this reason, the sample gas that has not been sufficiently dehumidified immediately after the start of energization until the drain separator functions sufficiently flows into each pretreatment section, and the temperature of each pretreatment section is low. Condensation may occur in the pretreatment section. That is, there is a problem in that each pre-processing unit constituting the gas sampling device is rapidly deteriorated according to the number of activations, and it is necessary to replace these pre-processing units with a short cycle.

  Similarly, the operator of the gas sampling device may keep the sampling device operating even when the power generation boiler is stopped, but this causes a large amount of air sucked in to cause deterioration of the pretreatment unit. There was also. In particular, in a catalyst such as a NOx converter catalyst, when a large amount of air flows into the catalyst, a high concentration of oxygen contained in the air may oxidize the catalyst and rapidly deteriorate the catalyst. In some cases, the service life may be reduced.

  The present invention has been made in consideration of the above-mentioned matters. The purpose of the present invention is to cause the catalyst surface to be deteriorated by condensate in each pretreatment section immediately after energization, or to oxidize the catalyst by atmospheric suction when the boiler is stopped. It is an object of the present invention to provide a gas sampling device that can prevent deterioration of catalyst efficiency.

  In order to achieve the above object, a gas sampling device according to the present invention includes a pretreatment unit that performs pretreatment of a sample gas supplied to a gas analyzer. The gas sampling device includes an upstream side and a downstream side of the pretreatment unit. A three-way switching valve is provided on each side, and the three-way switching valves are connected so as to bypass the pretreatment section (claim 1).

  The three-way switching valve is a three-way solenoid valve, and the sample gas flows through the pretreatment section when the three-way solenoid valve is off, and the sample gas flows through the bypass passage when the three-way switching valve is on. (Claim 2).

  The sample gas immediately after the start of energization may be configured not to come into contact with the pretreatment unit by controlling the three-way switching valve to be turned on for a predetermined time immediately after the start of energization.

  A humidity detection sensor for detecting the humidity of the sample gas is provided. While the humidity detected by the humidity detection sensor is greater than the threshold value, the three-way switching valve is switched on to control the sample gas immediately after the start of energization. You may comprise so that it may not contact a pre-processing part (Claim 4).

  By controlling the three-way switching valve to be turned on when the boiler is stopped, the sample gas may be configured not to contact the pretreatment section when the boiler is stopped.

  Using the measured value data of the sample gas from the gas analyzer, the measured value data of oxygen is compared with a predetermined threshold value. When the measured oxygen value is larger than the threshold value, the three-way selector valve is turned on. By controlling, the sample gas may be configured not to contact the pretreatment section when the boiler is stopped (Claim 6).

  According to the first aspect of the present invention, the three-way switching valve is provided on the upstream side and the downstream side of the pretreatment unit, and by switching the three-way switching valve, the sample gas flows through the bypass flow path, and the pretreatment unit is located upstream of the pretreatment unit. Since it is completely cut off from the flow of the sample gas both on the downstream side and the downstream side, the pretreatment unit does not come into contact with the sample gas with high humidity. Moreover, when the state of the gas sampling device is stable and the exhaust gas of the boiler to be measured is being sampled, the sample gas can be pretreated appropriately by returning the two three-way switching valves.

  In addition, since the configuration in which the two three-way switching valves and the bypass flow path are provided is very simple, it is possible to suppress the deterioration of the pretreatment unit as much as possible while suppressing the increase in manufacturing cost, and to save the labor for maintenance. Running costs can be kept low. In addition, since the configuration of the present invention only provides two three-way switching valves and a bypass flow path for the existing gas sampling device, the existing gas sampling device can easily have the characteristic configuration of the present invention. The gas sampling device can be modified (improved). It is desirable that the two three-way switching valves can be switched simultaneously by interlocking. Further, the three-way switching valve in this specification indicates a valve configured to be switchable so that the sample gas flows through either the main gas sampling flow path or the bypass flow path. The thing which provided the on-off valve in each of a path and a bypass channel is included.

  The two three-way switching valves are three-way solenoid valves, and when these three-way solenoid valves are in an off state, the sample gas flows through the pretreatment unit, and when in the on state, the sample gas flows through the bypass flow path. In the case where it is configured (Claim 2), the sample gas can be caused to flow through the bypass flow path by energizing the three-way solenoid valve. Can be shed. That is, sample gas flow path switching control can be automated. In addition, by allowing the sample gas to flow through the pretreatment unit when the three-way solenoid valve is in the off state, the power consumption by the three-way solenoid valve can be eliminated in the state where normal gas sampling is performed, It becomes energy saving.

  When the sample gas immediately after the start of energization is configured not to come into contact with the pretreatment section by controlling the three-way switching valve to be turned on for a predetermined time immediately after the start of energization (Claim 3). It takes a certain amount of time from the start of energization of the gas sampling device until the drain separator provided in the gas sampling device and the heater provided in the pretreatment unit can fully exhibit their capabilities. Can reliably prevent the sample gas with high humidity from coming into contact with the pretreatment section by switching the two three-way switching valves and flowing the sample gas into the bypass flow path. That is, it is possible to reliably prevent the occurrence of dew condensation in the pretreatment unit, thereby prolonging the life of the pretreatment unit and extending the maintenance cycle.

  In general, in a gas analyzer connected to a gas sampling device, an abnormal analyzer contact indicating a warm-up operation signal (warming up signal) is output for 60 minutes, for example, immediately after energization. This indicates that the measured value data is not accurate. Therefore, by using this warm-up signal or by switching the three-way switching valve to the on state in accordance with the time when this warm-up signal is output, the pretreatment device is disconnected from the sample gas flow during the warm-up. When is finished, the three-way switching valve is turned off, sample gas pretreatment using the pretreatment device can be started, and NOx measurement can be started. Here, in the state where the three-way switching valve is switched on, sample gas pretreatment is not performed, so accurate measurement cannot be performed, but the problem is that the measured value is not accurate during warm-up. Don't be.

  A humidity detection sensor for detecting the humidity of the sample gas is provided. While the humidity detected by the humidity detection sensor is greater than the threshold value, the three-way switching valve is switched on to control the sample gas immediately after the start of energization. When configured so as not to contact the pretreatment section (Claim 4), when the humidity of the sample gas is high, the humidity is high by switching the three-way switching valve and flowing the sample gas to the bypass flow path. It is possible to reliably prevent the sample gas from coming into contact with the pretreatment unit, to reliably prevent the occurrence of dew condensation in the pretreatment unit, and thus to prolong the life of the pretreatment unit and extend the maintenance cycle. As the humidity detection sensor, a drain sensor that detects dew condensation using a change in resistance value caused by dew condensation generated on the hot wire element may be considered.

  When the boiler is stopped, the three-way switching valve is controlled to be turned on so that when the boiler is stopped, the sample gas does not come into contact with the pretreatment section (Claim 5). Since it is possible to reliably prevent contact with the processing section, it is possible to prolong the service life of the pre-processing section, especially the catalyst, which shortens its service life due to contact with atmospheric components. The running cost can be reduced. For example, a boiler stop contact (boiler stop signal) outputted from the central control panel on the boiler side can be used for the stop state of the boiler. Alternatively, it is possible to use a signal for detecting no flame of the gas turbine, fire extinguishing of the boiler, and stop of the fan for pushing the combustion air into the boiler furnace.

  Using the measured value data of the sample gas by the gas analyzer, the measured value data of oxygen is compared with a predetermined threshold value. When the measured value of oxygen is larger than the threshold value, the three-way selector valve is turned on. When it is configured that the sample gas does not come into contact with the pretreatment section when the boiler is stopped by controlling the switching (Claim 6), it is found that the atmosphere is supplied as the sample gas. Since this can be bypassed so that the sample gas does not come into contact with the pretreatment section, it is possible to prevent the catalyst from being oxidized due to atmospheric suction when the boiler is stopped, and the catalyst efficiency from being lowered. In other words, by using the measurement result of the sample gas flowing through this gas sampling device to switch the three-way selector valve, it is possible to reliably prevent deterioration of the pretreatment unit due to the atmosphere without depending on any control signal input from the outside. Can do.

  FIG. 1 is a diagram showing a first embodiment of the present invention. In the following example, the gas sampling device samples exhaust gas from a boiler of a thermal power plant that performs oil burning or coal burning as a sample gas, The concentration of NOx contained in this sample gas is measured.

  In FIG. 1, 1 is a gas sampling device, 2 is a flue through which exhaust gas as a sample gas S to be measured flows, and 3 is a gas sampling probe (hereinafter simply referred to as a probe) attached to the flue 2. Reference numeral 4 denotes a sample gas passage through which the sample gas S flows, and a gas analyzer 5 for analyzing the wavelength of a specific component (NOx in this embodiment) in the sample gas is provided at the downstream end thereof. The sample gas flow path 4 is provided with the following members.

  That is, 6 is a first drain separator that dehumidifies the sampled sample gas S by cooling it to 15 ° C., for example, 7 is a mist catcher for removing mist contained in the sample gas S, and 8 is a pretreatment unit for the sample gas S NOx converter catalyst (hereinafter simply referred to as catalyst), 9 and 10 are three-way switching valves provided upstream and downstream of the catalyst 8, and 11 is two three-way switching valves so as to bypass the catalyst 8. It is a bypass flow path connecting between 9 and 10. 12 is a filter, 13 is a needle valve, 14 is a suction pump, 15 is a second drain separator that further cools and dehumidifies the sample gas S to 5 ° C., and 16 notifies the analysis result of the gas analyzer 5 to a monitoring center or the like. It is a telemeter. The three-way switching valves 9 and 10 are, for example, three-way solenoid valves that can be electrically controlled on / off.

17 is a relay comprising, for example, a relay contact (a contact) 17a and a relay coil 17b for controlling the energization of the power supply voltage Vcc to the three-way solenoid valves 9 and 10, O is a measured value data D of the gas analyzer 5 and warming up an output signal such as a signal S _1. Further, the warm-up signals S ₁ is a signal obtained by the contact output of the analyzer abnormal contacts in gas analyzer 5, which is input to the relay coil 17b.

  The flue 2 is a discharge passage for the exhaust gas S discharged from a boiler or the like, and the probe 3 samples the sample gas S by removing dust from the exhaust gas flowing through the flue 2 as much as possible. The drain separators 6 and 15 are for dehumidification by cooling the sample gas S using, for example, an electronic cooler. In this embodiment, for example, the two drain separators 6 and 15 are combined into one block. Formed inside. The first drain separator 6 cools the sample gas S to, for example, 15 ° C., thereby dehumidifying the sample gas S having a humidity of about 50 ° C. to about 15 ° C., and the second drain separator 15 Dehumidify S to 5 ° C saturation.

The mist catcher 7 removes, for example, SO ₃ mist contained in the sample gas S, and is configured to prevent condensation in the mist catcher 7 by being heated by a heater (not shown). ing. The three-way solenoid valves 9 and 10 are on / off controlled at the same timing and each have three ports.

The catalyst 8 is, for example, a reduction catalyst that converts NO ₂ contained in the sample gas S into NO. For example, activated carbon is impregnated with a chemical agent composed of a molybdenum compound, a manganese-potassium compound, phosphoric acid, and the like. . And the catalyst 8 is comprised so that the condensation in the catalyst 8 can be prevented by being heated by the heater outside a figure. The analyzer 5 can measure the total amount of NOx contained in the sample gas S by converting NO ₂ into NO by the catalyst 8.

  The filter 12 removes dust contained in the sample gas S, and the needle valve 13 enables the amount of suction by the suction pump 14 to be adjusted. The analyzer 5 analyzes the component concentration of the sample gas S that has been subjected to sufficient pretreatment. For example, the analyzer 5 measures the concentration of NO, particularly using an infrared gas analyzer, and outputs the measured value data D. . Further, for example, a warm-up operation is performed for 60 minutes immediately after the gas sampling device 1 starts energization, and an analyzer abnormal contact indicating that the warm-up operation is being performed is operated during this period.

The telemeter 16 is a device that receives the measurement result by the analyzer 5 as an output signal O such as a warm-up signal S ₁ obtained by the measurement value data D or the operation of the analyzer abnormal contact, and transfers the data to the monitoring center. . Since the measured value data D becomes an inaccurate value during the warming-up operation, the telemeter 16 does not transfer the measured value data D or outputs a zero concentration. Has been.

Relay 17 by closing the relay contacts 17a only while the warm-up signal S ₁ is output, but to switch simultaneously turned on the two three-way electromagnetic valve 9 and 10.

  On the other hand, the suction pump 14 operates when the power of the gas sampling device 1 is turned on, and continues to suck the sample gas S by a predetermined flow rate. The suction pump 14 energizes the drain separators 6 and 15, the mist catcher 7 and the catalyst 8. By starting energization of the heater provided in the heater, a warm-up operation is performed so that no dew condensation occurs in each part of the gas sampling device 1 including the mist catcher 7 and the catalyst 8.

In the gas sampling apparatus 1 having the above-described configuration, the relay 17 operates using the warm-up signal S ₁ output from the gas analyzer 5 immediately after the start of energization. That is, in this embodiment, since the three-way solenoid valves 9 and 10 are provided on the upstream side and the downstream side of the catalyst 8 as the pretreatment unit, respectively, the three-way solenoid valves 9 and 10 are turned on as the relay 17 operates. The total amount of the sample gas S flows to the bypass channel 11 side. At this time, since the three-way solenoid valve 9 blocks the upstream side of the catalyst 8 and the three-way solenoid valve 10 blocks the downstream side of the catalyst 8, the catalyst is sampled in the flow path closed by the three-way solenoid valves 9, 10. It is completely isolated from the gas S. That is, the sample gas S that cannot be sufficiently dehumidified during the warm-up operation can be reliably prevented from coming into contact with the catalyst 8 due to diffusion.

  Therefore, it is possible to reliably prevent the sample gas S having a high humidity during the warming-up operation from condensing in the catalyst 8, thereby effectively suppressing deterioration of the catalyst 8 and extending its life. The running cost for replacement can be drastically reduced. Further, when the gas sampling device 1 stops the power supply and performs the maintenance for a long time and then returns again, the gas sampling device 1 performs the warm-up operation again, so that it is possible to reliably prevent the sample gas S that cannot be dehumidified from coming into contact with the catalyst 8. . That is, the catalyst 8 does not deteriorate according to the number of times of starting the gas sampling device 1 of the present invention as in the conventional gas sampling device.

Since the sample gas S bypasses the catalyst 8 during the warm-up operation, the concentration indicated by the measured value data D output from the analyzer 5 is lower by the concentration of NO ₂ , but the warm-up signal Since S ₁ is a signal indicating that the accurate measurement value data D cannot be output, this does not cause any problem.

  In the above-described example, a configuration in which the catalyst 8 is bypassed as a pretreatment unit having a relatively expensive long-life filling is shown. However, the pretreatment unit uses a relatively expensive long-life member. All can be included. That is, in addition to the catalyst 8, a mist catcher 7, an ammonia scrubber, a chlorine scrubber, and the like may be disposed in the gas sampling flow path 4 between the three-way solenoid valves 9 and 10 that are bypassed by the bypass flow path 11. That is, it is possible to prevent the sample gas S having a high humidity from being condensed in the pretreatment unit such as the mist catcher 7 and to prevent the pretreatment unit such as the mist catcher 7 from deteriorating. Needless to say, the catalyst 8 may be variously modified such as an SOx converter catalyst.

In addition, since the length of time for flowing the sample gas S to the bypass flow path 11 side varies depending on the configuration of each part of the gas sampling device 1, the time for performing bypass of the flow path using the bypass flow path 11 is It is necessary to match the control sequence of the warm-up operation of the gas sampling device 1. Therefore, as in this embodiment, the warm-up signal S ₁ generally obtained from the analyzer abnormal contact output from the analyzer 5 is used to switch the flow path so as to bypass the catalyst 8. The flow path can be switched at a timing that is easily and reliably matched to the control sequence of the warm-up operation.

However, the present invention is not limited to directly using the warm-up signal S ₁ for switching the flow path of the three-way solenoid valves 9 and 10, and is the same as the time when the warm-up signal S ₁ is output immediately after the start of energization. The three-way solenoid valves 9 and 10 may be switched to the on state only for a somewhat shorter predetermined time.

  In the case of the present embodiment, as shown in FIG. 1, the three-way solenoid valve 9 and 10 are connected so that the sample gas S flows through the bypass passage 11 when the three-way solenoid valves 9 and 10 are turned on. , 10 are configured to communicate with each other so that the sample gas S flows through the gas sampling channel 4 when turned off. Therefore, in the normal measurement state in which the analyzer abnormal contact is not operating, the power supply voltage Vcc is not supplied to the three-way solenoid valves 9 and 10, and the power consumption due to this can be suppressed. However, the flow path switching using the three-way solenoid valves 9 and 10 may be reverse to that described above.

  Furthermore, in this embodiment, three-way solenoid valves 9 and 10 that can be electrically controlled on / off are shown as examples of the three-way switching valves provided on the upstream side and the downstream side of the pretreatment unit, respectively. However, the present invention is not limited to this point. That is, instead of the electrically controllable three-way solenoid valves 9 and 10, a three-way switching valve that can be switched by a fluid such as compressed air or a three-way switching valve that performs manual switching is arranged so that the flow path switching is performed manually. You may make it carry out. Also in this case, it is desirable that both the three-way switching valves can be operated simultaneously by interlocking.

In any case, the gas sampling apparatus 1 of the present invention can be obtained by adding a slight improvement such as adding two three-way switching valves 9 and 10 and a bypass flow path 11 to an existing gas sampling apparatus. Further, by providing a relay 17 for supplying the power supply voltage Vcc to the three-way solenoid valves 9 and 10 and inputting the existing warm-up signal S ₁ to the relay 17, the flow path switching can be automatically performed. Yes, and its manufacturing cost will hardly increase.

  FIG. 2 is a diagram showing a second embodiment of the present invention. In FIG. 2, the portions denoted by the same reference numerals as those in FIG. 1 are the same or equivalent portions, and thus detailed description thereof is omitted.

2, 20 is a central control panel for controlling the boiler, S ₂ is the boiler stop signal obtained by the operation of the boiler stops contact of the central control panel 20. 21 is a relay operated by the boiler stop signal S _2, the relay 21 is an electromagnetic relay comprising, for example, a relay contact (a contact) 21a, a relay coil 21b. Note that the present invention does not limit the type of the relay 21.

In this embodiment, the relay contact 21a is connected in parallel to the relay contact 17a. Therefore, by configuring as in the present embodiment, the power supply voltage Vcc is supplied to the three-way solenoid valves 9 and 10 when any one of the relay contacts 17a and 21a is turned on. Since the relay 21 is operated by the boiler stop signal S _2, in the state where the stop boiler, three-way electromagnetic valve 9, 10 are turned on, the total amount of the sample gas S is to flow into the bypass passage 11 side It is configured.

That is, depending on the user, even when the boiler is stopped, the suction pump 14 may be operated to continuously suck the sample gas S, but at this time, it is output from the central control panel 20 side. Using the boiler stop signal S ₂ , the sucked sample gas S (in this case, the atmosphere) is caused to flow to the bypass flow path 11 side to isolate the catalyst 8 as the pretreatment unit from the atmosphere, so that the catalyst 8 does not contact the atmosphere. It is configured as follows. This prevents the catalyst 8 such as the NOx converter catalyst from being rapidly oxidized by high-concentration oxygen contained in the atmosphere, thereby reducing its conversion efficiency and shortening its life.

Further, instead of (or in addition to) the boiler stop signal S ₂ , it is detected that there is no flame of the gas turbine output from the central control panel 20 side, the fire extinguishing of the boiler, and the stop of the fan for pushing the combustion air into the boiler furnace. It is also conceivable to operate the relay 21 using a signal.

Although not shown, the boiler stop signal S ₂ is also input to the analyzer 5, and the analyzer 5 generally detects NOx as measured value data D when detecting the boiler stop signal S ₂ . It is configured to output the density as 0. Thus, by bypassing the catalyst 8 in the state where the boiler stop signal S ₂ is output in this embodiment, the analyzer 5 is for detecting the concentration amount corresponding low concentration of NO ₂ than the actual NOx concentration, either Even so, since the value that the analyzer 5 uses as the measured value data D is 0, the influence of bypassing the catalyst 8 does not cause any problem.

  FIG. 3 is a diagram showing a third embodiment of the present invention using FIGS. In FIG. 3, since the part which attached | subjected the same code | symbol as FIG. 1, 2 is the same or equivalent part, the detailed description is abbreviate | omitted.

In FIG. 3, reference numeral 25 denotes a drain sensor as an example of a humidity detection sensor provided in the gas sampling flow path 4 further upstream than the three-way solenoid valve 9 upstream of the catalyst 8 as a pretreatment unit. For example, 25 detects the occurrence of condensation by capturing changes in resistance caused by the occurrence of condensation using a hot wire element and a constant current circuit. S ₃ is a condensation detection signal indicating that the occurrence of condensation has been detected. 26 is a relay operated by the dew condensation detection signal S _3, the relay 26 is an electromagnetic relay comprising, for example, a relay contact (a contact) 26a, a relay coil 26b. Note that the present invention does not limit the type of the relay 26.

According to the third embodiment, when dew condensation occurs on the upstream side of the catalyst 8, it is determined that the humidity exceeds the allowable threshold value, and the dew condensation detection signal S ₃ is output to the relay 26. As a result, the three-way solenoid valves 9 and 10 are switched to the ON state, and the flow of the sample gas S can be switched to the bypass flow path 11 side, thereby preventing the catalyst 8 from contacting the sample gas S with high humidity. be able to. Thereafter, by being purged with the sample gas drainage is dehumidified, the drain runs out gas sampling flow path 4, the longer is the output of the condensation detection signal S _3, three-way electromagnetic valve 9, 10 is returned to the OFF state Therefore, the sample gas S flows on the gas sampling flow path 4 side.

  In this embodiment, an example of the drain sensor 25 that detects the occurrence of condensation using a heat ray element is shown as an example of the humidity detection sensor. However, the present invention does not limit the type of the humidity detection sensor. The humidity detection sensor may be configured to be compared with a predetermined threshold value.

Further, by using a drain sensor (humidity sensor) 25 as shown in the third embodiment, even when the warm-up signal S ₁ is not output from the analyzer 5, the sample gas S having a high humidity during the warm-up operation. As a result, the catalyst 8 can be prevented from deteriorating due to condensation. In other words, by placing the relay 26 of the present embodiment the position of the relay 17 in FIGS. 1 and 2, in the case of using the analyzer 5 that can not be obtained warm-up signals S ₁ also warm-up immediately after the start of energization Deterioration of the catalyst 8 during operation can be prevented.

  In addition, also in the third embodiment, the pretreatment section is not limited to the catalyst 8 alone. That is, the mist catcher 7, the ammonia scrubber, the chlorine scrubber, and the like may be disposed in the gas sampling flow path 4 between the three-way solenoid valves 9 and 10 as a pretreatment section that is bypassed by the bypass flow path 11.

  FIG. 4 is a diagram showing a fourth embodiment of the gas sampling device 1 described with reference to FIGS. In FIG. 4, since the part which attached | subjected the same code | symbol as FIGS. 1-3 is the same or equivalent part, the detailed description is abbreviate | omitted.

In FIG. 4, S ₄ is an oxygen concentration alarm signal output by the operation of the concentration alarm contact in the analyzer 5, and more specifically, the oxygen concentration alarm signal S ₄ is the oxygen concentration of the sample gas S in the analyzer 5. Is a signal that is output when the volume ratio exceeds a threshold of 20.5%. 30 is a relay operated by the oxygen concentration alarm signal S _4, the relay 30 is an electromagnetic relay comprising, for example, a relay contact (a contact) 30a, a relay coil 30b. Note that the present invention does not limit the type of the relay 30.

According to the gas sampling apparatus 1 of the present embodiment, when the analyzer 5 detects oxygen with a volume ratio of about 21%, it is determined that the atmosphere is sucked in as the sample gas S by the oxygen concentration alarm signal S ₄ . Then, the relay 30 is operated by the oxygen concentration alarm signal S ₄ and the three-way solenoid valves 9 and 10 are turned on, so that the catalyst 8 is completely separated from the flow of the sample gas S, and a large amount of atmospheric catalyst 8 is obtained. Oxidation due to flow into the can be prevented.

That is, when the analyzer 5 as in this embodiment outputs an oxygen concentration alarm signal S ₄ is by placing the relay 30 of the present embodiment the position of the relay 21 in FIG. 2, central control panel 20 side flame without boiler stop signal S ₂ and the gas turbine from extinguishing the boiler, even when the it is impossible to obtain a signal for detecting a push fan stop of the combustion air into the boiler furnace, boiler stopped It is possible to prevent the catalyst 8 from being deteriorated due to atmospheric suction.

  Further, in each of the above-described examples, the three-way solenoid valves 9 and 10 are examples in which the flow path is switched so that the sample gas S flows through the bypass flow path 11 exclusively to prevent deterioration of the pretreatment section such as the catalyst 8. However, the deterioration state of the catalyst 8 can be confirmed by switching the three-way solenoid valves 9 and 10.

It is a figure showing roughly an example of composition of a gas sampling device of the present invention. It is a figure which shows 2nd Example of the said gas sampling apparatus. It is a figure which shows 3rd Example of the said gas sampling apparatus. It is a figure which shows 4th Example of the said gas sampling apparatus.

Explanation of symbols

1 Gas sampling device 4 Gas sampling flow path 5 Analyzer 8 Catalyst (Pretreatment section)
9,10 Three-way solenoid valve (three-way switching valve)
11 Bypass channel 25 Humidity detection sensor S Sample gas S ₁ Warming up signal S ₂ Boiler stop signal S ₃ Condensation detection signal S ₄ Oxygen concentration alarm signal

Claims (6)

  In a gas sampling apparatus having a pretreatment unit for pretreatment of a sample gas supplied to a gas analyzer, a three-way switching valve is provided on each of an upstream side and a downstream side of the pretreatment unit, and between these three-way switching valves The gas sampling device, wherein the pre-processing unit is bypassed.   The three-way switching valve is a three-way solenoid valve, and the sample gas flows through the pretreatment section when the three-way solenoid valve is off, and the sample gas flows through the bypass channel when the three-way switching valve is on. The gas sampling device according to claim 1.   3. The gas according to claim 1, wherein the sample gas immediately after the start of energization is configured not to contact the pretreatment section by controlling the three-way switching valve to be turned on for a predetermined time immediately after the start of energization. Sampling device.   A humidity detection sensor for detecting the humidity of the sample gas is provided. While the humidity detected by the humidity detection sensor is greater than the threshold value, the three-way switching valve is switched on to control the sample gas immediately after the start of energization. The gas sampling device according to any one of claims 1 to 3, wherein the gas sampling device is configured not to contact the pretreatment unit.   The gas sampling according to any one of claims 1 to 4, wherein the three-way switching valve is controlled to be turned on when the boiler is stopped, so that the sample gas does not contact the pretreatment section when the boiler is stopped. apparatus.   Using the measured value data of the sample gas from the gas analyzer, the measured value data of oxygen is compared with a predetermined threshold value. When the measured oxygen value is larger than the threshold value, the three-way selector valve is turned on. The gas sampling device according to any one of claims 1 to 5, wherein the gas sampling device is configured so that the sample gas does not come into contact with the pretreatment unit when the boiler is stopped by the control.

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