JP5581683B2 - Evaluation method for ventilation and gas generation in space - Google Patents

Description

  The present invention relates to a method for evaluating the amount of ventilation in a space and a method for evaluating the amount of gas generated, and in particular, a method for evaluating the amount of ventilation and gas in a space suitable for evaluating a large space such as a closed waste disposal site. It relates to a method for evaluating the amount of generation.

  Conventionally, when exhausting a large space such as a closed waste disposal site using an exhaust fan, when trying to evaluate the ventilation performance in the space, if there is stagnation or short circuit in the space, The actual ventilation performance is inferior to the value calculated from the ventilation airflow by the exhaust fan, and when the natural ventilation effect by buoyancy or external wind acts, the real ventilation performance is less than the value calculated from the ventilation airflow by the exhaust fan. The ventilation performance cannot be evaluated with high accuracy.

  For example, there are a step-down method and a step-up method as a ventilation performance evaluation method. As shown in FIG. 6, the step-down method includes a gas supply unit 22 for supplying tracer gas into the space 11, The gas concentration measuring unit 23 that measures the concentration of the tracer gas, the gas supply unit 22, the gas concentration measuring unit 23, the exhaust fan 24 that ventilates the space 11, and the like are controlled, and data from the gas concentration measuring unit 23 is also controlled. Is used to fill the space 11 with a uniform concentration of tracer gas, and the exhaust fan 24 is operated to start ventilation in the space 11. Fresh air is introduced into the interior, the change in concentration in the space 11 at this time is measured to obtain a concentration decay curve (see FIG. 7), and the space 11 is based on the concentration decay curve. By evaluating the amount of ventilation is a method for evaluating the ventilation performance.

  In the step-up method, the evaluation device 21 as described above is used, and the concentration of the tracer gas in the space 11 is set to 0 by the evaluation device 21. From this state, the tracer gas is introduced into the space 11 instead of fresh air. A method for evaluating the ventilation performance by introducing a concentration change curve in the space 11 at this time to obtain a concentration increase curve and evaluating the ventilation amount in the space 11 based on the concentration increase curve. It is.

In the step-down method and the step-up method as described above, assuming that the ventilation air volume Q (m ³ / h) and the capacity V (m ³ ) of the target space, the number of ventilations n = Q / V (times / h), the ventilation time since can be defined as tp = Q / V (h) , 8 or 9, the region _a 2, _{b 2} of the decay curve or area _a 1 obtained from the rise curve, _{b 1} and the same area of the determined concentration By calculating | requiring, the ventilation time tp of object space can be evaluated from following Formula, and ventilation performance can be evaluated.
Here, T _m : Measurement time C _P : Arithmetic average concentration of tracer gas at point P C ₀ : Initial concentration of tracer gas C _P (t ₂ ): Concentration of tracer gas at the end of measurement

  However, the above-described step-down method and step-up method have the following problems.

(1) Since the step-down method and step-up method require a large amount of tracer gas to be introduced into the space in order to maintain a constant concentration in the space, a large space such as a closed waste disposal site is required. It is difficult to apply to evaluation.

(2) It is necessary to use a gas such as SF6 (sulfur hexafluoride) that does not exist in a normal indoor space as a tracer gas, and a gas such as SF6 (sulfur hexafluoride) is a substance with a high global warming potential Therefore, there is a problem in using a large amount of gas such as SF6 as the tracer gas.

(3) In the step-down method, the space must be filled with a uniform concentration of tracer gas as an initial condition, but it is difficult to uniformly distribute the tracer gas in the space without ventilating the space. It is difficult to apply to the evaluation of large spaces such as closed waste disposal sites.

(4) Since it is necessary to obtain an integral value based on the decay curve or rise curve of the tracer gas concentration obtained by the step-down method or the step-up method, the amount of the tracer gas supplied into the space is expensive. It is necessary to precisely control using a controller, and to obtain a tracer gas concentration decay curve and rise curve with high accuracy, which requires time, cost and labor.

(5) The ventilation volume in the space and the concentration generation amount (gas generation amount) are in a relationship of both sides, and if the gas generation amount is not clear, the ventilation amount cannot be evaluated. If it is not clear, the amount of gas generated cannot be evaluated.

  The object of the present invention is to solve the above-described problems of the prior art.

In order to solve the above problems, the present invention employs the following means.
That is, the present invention is a method for evaluating ventilation in a space where gas is generated,
An exhaust means for ventilating the space and a concentration measuring means for measuring a gas concentration in the space are provided,
An evaluation line in which the temporal change of the gas concentration in the space after changing the operating conditions of the exhaust means is measured, and based on the measurement result, the vertical axis is logarithmic concentration and the horizontal axis is plotted as real time And the difference in ventilation volume in the space before and after the operating condition of the exhaust means is changed is obtained from the gradient of the evaluation line .

  According to the evaluation method of the ventilation amount in the space of the present invention, the temporal change of the gas concentration in the space is measured, and based on this measurement result, the vertical axis is logarithmic concentration and the horizontal axis is plotted as real time. Thus, an evaluation line can be obtained, and the ventilation amount of the space can be evaluated from the gradient of the evaluation line.

Furthermore, in the present invention , the operating condition of the exhaust means may be the number of exhaust means to be operated among the plurality of exhaust means .

Furthermore, this invention calculates | requires the average value of the difference of outside air and the unknown gas density | concentration in the said space, and evaluates this average value and the ventilation amount in the space in any one of Claims 1-3 It is characterized by evaluating the amount of gas generated in the space from the difference in ventilation amount obtained by the above.

According to the method for evaluating the amount of gas generated in the space of the present invention, the temporal change in the concentration of gas in the space is measured, and from this measurement result , the difference in the amount of ventilation in the space before and after the change in operating conditions is determined , and the difference between this ventilation, the average value of the difference between the gas concentration in the ambient air and space, it is possible to evaluate the amount of gas generated in the space.

  As described above, according to the evaluation method of the ventilation amount and the evaluation method of the gas generation amount in the space according to the present invention, the gas generated in the space can be used as the tracer gas. Etc. need not be introduced as tracer gas. In addition, since it is not necessary to use the integrated value of concentration change, even if the amount of gas generated is unknown, the ventilation rate can be evaluated by assuming a constant amount generated during the measurement time. There is no need to use an expensive device such as a controller. Furthermore, even if the amount of gas generated is unknown, the amount of gas generated can be determined after determining the amount of ventilation in the space. Therefore, it can be applied to the evaluation of ventilation volume and gas generation in a large space such as a closed waste disposal site, and useful information for operating the waste disposal site can be obtained. It becomes possible.

It is the schematic which showed one Embodiment of the evaluation method of the ventilation quantity in the space by this invention. 2 is an attenuation curve of a temporal change in gas concentration (average concentration) in a space obtained by the evaluation method of FIG. It is explanatory drawing which showed the time change of methane concentration. It is the schematic which showed the modification of the evaluation method of the ventilation quantity of FIG. It is explanatory drawing which showed other embodiment of the evaluation method of ventilation quantity. It is the schematic which showed an example of the conventional evaluation method of ventilation quantity. 8 is an attenuation curve of a temporal change in gas concentration in the space obtained by the evaluation method of FIG. It is explanatory drawing which showed an example of the evaluation method of the conventional ventilation amount. It is explanatory drawing which showed the other example of the conventional evaluation method of ventilation quantity.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows an embodiment of a method for evaluating a ventilation amount and a method for evaluating a gas generation amount in a space according to the present invention.

  The evaluation method of the ventilation amount in the space and the evaluation method of the gas generation amount in this embodiment are, for example, the evaluation of the ventilation amount in a large space such as a closed waste disposal site, and the gas generation amount (pollutants such as methane gas). This is effective for evaluating the amount of generated

  For example, as shown in FIG. 1, the closed-type waste disposal site includes a building 10 including a side wall that surrounds a landfill section for landfilling waste and a roof that closes an upper portion of the side wall. A large space (hereinafter referred to as “space 11”) is formed in a portion surrounded by the side wall and the roof.

  A plurality of air inlets 12 communicating with the inside and outside of the space 11 are provided on the side wall of the building 10, and a plurality of exhaust ports 13 communicating with the inside and outside of the space 11 are provided on the roof. An exhaust fan 2 is provided. By operating each exhaust fan 2, fresh air is introduced from the outside into the space 11 from each air supply port 12, the gas in the space 11 is exhausted to the outside from each exhaust port 13, and the inside of the space 11 is ventilated. .

  In the present embodiment, an exhaust fan control unit 3 that controls the operation of the exhaust fan 2, a concentration measuring device 4 provided at each exhaust port 13, and a concentration total that sums up the concentrations measured by the concentration measuring device 4. The evaluation device 1 including the unit 5 and the calculation unit 6 that evaluates the ventilation amount based on the concentration data collected by the concentration totalization unit 5 is used. By this evaluation device 1, the ventilation amount (ventilation air flow) in the space 11 and The amount of gas generated is evaluated.

(1) Evaluation method of ventilation volume (simple method)
First, the evaluation method (simple method) of the ventilation amount in the space 11 will be described.
When the number of operating exhaust fans 2 is changed by the exhaust fan control unit 3 of the evaluation apparatus 1 described above, when all the exhaust fans 2 are stopped from the operating state, all the exhaust fans 2 are started from the stopped state. After measuring the temporal change of the gas concentration (average concentration) in the space 11 after the operation state of the exhaust fan 2 is changed stepwise, the operation state is changed based on this temporal change. Evaluate ventilation volume.

That is, the change in the gas concentration in the space 11 is as shown in FIG. 2, and is expressed by the following equation (1) when expressed by an equation.
here,
V: Volume of space (m ³ )
C: Contaminant concentration in the space (gas concentration, g / m ³ )
t: Time (h)
Q ₀ : Ventilation rate (ventilation air volume, m ³ / h)
C ₀ : Contaminant concentration of outside air (gas concentration, g / m ³ )
M: Pollutant generation amount (gas generation amount, g / h)

The analytical solution of equation (1) is as follows.
here,
C _i : Contaminant concentration in the initial space (gas concentration, g / m ³ )
Here, assuming that there is no generation of pollutants (M = 0) or that this can be ignored for changes in ventilation,
When C ′ is the difference between the outside air and the concentration in the space, and C _i ′ is the difference between the outside air and the initial concentration (C ′ = C−C ₀ , C _i ′ = C _i −C ₀ ),
And taking the logarithm of both sides
It becomes. Therefore, as shown in FIG. 3, the change in concentration is plotted with the logarithmic concentration of pollutant on the vertical axis and the real time on the horizontal axis, and the difference Q ₀ between before and after changing the operating state by the slope of the straight line. Can be evaluated as / V.
In the equation (4), if it is considered that the outside air concentration C ₀ = 0, C ′ represents the internal concentration.

  FIG. 4 shows a modification of the evaluation method (simple method) of the ventilation amount in the space 11 according to the present embodiment. In this evaluation method, a laser type concentration measuring device 4 is installed at the edge of a landfill section in the space 11 of the building 10, and the concentration (average value) on the beam path of the laser type concentration measuring device 4 is measured. It is configured to measure the temporal change of the average value of the concentration in the space 11 from the concentration measured on the plurality of beam paths, and to evaluate the ventilation amount after changing the operation state based on the temporal change. The other configuration is the same as that shown in FIG.

(2) Evaluation method of ventilation volume (numerical analysis method)
Next, an evaluation method (numerical analysis method) of the ventilation amount in the space 11 will be described.
In this evaluation method, as shown in FIG. 5, attenuation curves (evaluation lines) of concentrations at various ventilation volumes are obtained by calculation based on the formula (1) in advance, and attenuation curves (evaluation lines) in which measured values coincide with each other. ) Is the method of obtaining the ventilation volume from. The above evaluation method can be performed using, for example, Expression (6) obtained by approximating Expression (1) by the forward Euler method.
n: Number of time steps, M: Amount of pollutant generated In FIG. 5, methane gas is targeted.

  Assuming several types of ventilation, compare the time-varying curve of the concentration numerically analyzed with Equation (1), which represents the concentration change in the space 11 described above, and the actual concentration measurement value. The ventilation volume is evaluated by determining which curve the measurement result approximates most. According to this method, the ventilation rate can be evaluated even when the pollutant generation amount M changes.

(3) Evaluation method of pollutant generation amount (gas generation amount) Next, an evaluation method of the pollutant generation amount (gas generation amount) in the above space will be described.
When the time t in the above equation (2) is infinite and M is constant, the following equation is obtained as a steady solution.
When C ′ is the difference between the outside air and the concentration in space (C ′ = C−C ₀ )
If the ventilation amount Q ₀ is known, the gas generation amount M can be obtained if the average C ′ in the space 11 can be measured.

  In the evaluation method for the ventilation amount and the gas generation amount in the space 11 of the present embodiment configured as described above, in the large space 11 such as a closed waste disposal site, a pollutant (methane gas or the like) Even if the amount of generated gas is unknown, it is not necessary to introduce a known gas such as SF6 because the unknown gas can be used as a tracer gas.

  In addition, since it is not necessary to use the integrated value of the gas concentration change in the space 11, even if the gas generation amount in the space 11 is unknown, the ventilation amount is assumed by assuming a constant generation amount during the measurement time. Therefore, it is not necessary to use an expensive device such as a mass flow controller, and the ventilation rate can be evaluated easily and without cost.

  Furthermore, even if the gas generation amount in the space 11 is unknown, the net ventilation amount in the space 11 can be evaluated. Therefore, after evaluating this net ventilation amount, the total gas generation amount in the space 11 can be obtained. It becomes possible, and by controlling the operation of the exhaust fan 2 based on the calculated total gas generation amount, the inside of the space 11 can be controlled to the optimum ventilation state.

  Furthermore, by periodically changing the operating status of the exhaust fan 2 and evaluating the ventilation rate, it is possible to evaluate the transition of the amount of gas generated over a relatively long period of time, so a large space such as a waste disposal site Useful information can be obtained.

  Furthermore, the time change of the gas concentration (average concentration) in the space 11 after changing the operation state of the exhaust fan 2 stepwise is measured, and the ventilation volume after the change of the operation state is measured based on this time change. Since it can be evaluated, a part of the plurality of exhaust fans 2 is operated during the operation of the exhaust fan 2 in the space 11 where toxic gas is generated like a waste disposal site, and the remaining exhaust By switching to various operation states such as stopping the operation of the fan 2, the ventilation amount and the gas generation amount can be evaluated.

  Further, by stopping the operation of some of the plurality of exhaust fans 2, the ventilation capacity of the remaining exhaust fans 2 during operation can be evaluated, so that the plurality of exhaust fans 2 can be grouped into a plurality of groups. The ventilation capacity by the exhaust fan 2 of each group when divided can be evaluated, and the ventilation capacity of the portion of the space 11 corresponding to the exhaust fan 2 of each group can also be individually evaluated.

  In the above explanation, it was applied to the evaluation of the amount of ventilation and gas generation in the waste disposal site, but the closure of facilities, equipment, etc. where many people gather such as atrium, stadium, shopping mall, underground station, airport, etc. The present invention may be applied to a space (not limited to a completely sealed space, including a space partially opened to the outside), and in this case, the same effect is obtained.

DESCRIPTION OF SYMBOLS 1,21 Evaluation apparatus 2,24 Exhaust fan 3 Exhaust fan control part 4 Concentration measuring device 5 Concentration totaling part 6 Arithmetic part 10 Building 11 Space 12 Supply port 13 Exhaust port 22 Gas supply part 23 Gas concentration measurement part 25 Control part

Claims (3)

A method for evaluating ventilation in a space where gas is generated,
An exhaust means for ventilating the space and a concentration measuring means for measuring a gas concentration in the space are provided,
An evaluation line in which the temporal change of the gas concentration in the space after changing the operating conditions of the exhaust means is measured, and based on the measurement result, the vertical axis is logarithmic concentration and the horizontal axis is plotted as real time And the difference between the ventilation amounts in the space before and after the operating condition of the exhaust means is changed is obtained from the gradient of the evaluation line . The method for evaluating a ventilation amount in a space according to claim 1, wherein the operating condition of the exhaust means is the number of exhaust means to be operated among the plurality of exhaust means . The average value of the difference between the outside air and the unknown gas concentration in the space, and a difference in the ventilation quantity obtained by the evaluation method of ventilation in the space according this average value to claim 1 or 2, space Contact Keru evaluation method of gas generation in the space, characterized in that to evaluate the gas generation amount in the inner.