JP4847902B2 - Temperature detection system - Google Patents

Description

  The present invention relates to a temperature detection system that detects an increase in temperature of a device housed in a device housing box having a predetermined volume and having a predetermined volume.

In various equipment such as mechanical equipment, electrical equipment such as switchboards, and computer systems such as servers, the equipment may generate heat due to an increase in load, contact failure, short circuit, electric leakage, etc., leading to failure or fire. In order to prevent such a situation, various techniques for detecting heat generation have been proposed.
For example, Patent Document 1, which is cited below, describes an invention of a heat-reactive odor generator and a temperature detection system. This odor generating tool contains an odor generating material in a container in which an opening is formed. The opening is sealed with a sealing material that melts at a predetermined temperature. When this odor generating tool is attached to a device that detects heat generation, the sealing material melts as the temperature of the device rises, and the odor generating material volatilized in the installation atmosphere of the odor generating tool diffuses. The temperature detection system detects an increase in the temperature of the device by detecting the volatilized odor generating material using a gas detection element. Specifically, an increase in the temperature of the device is detected when it is detected that the odor generating material has a concentration exceeding a predetermined threshold value.

JP 2003-35609 A (see paragraphs 8-21, FIGS. 1-3, etc.)

  By the way, a semiconductor-type gas detection element as described in Patent Document 1 is usually incorporated in a bridge circuit, and outputs a voltage value that varies depending on a resistance value that varies depending on gas as a gas detection output. The reference voltage when no gas is detected is set in an atmosphere having a predetermined gas concentration. Therefore, an error occurs in the gas detection output indicating the gas concentration accompanying the volatilization of the odor generating material due to the difference in gas concentration in the atmosphere where the gas detection element is actually installed.

  That is, when the atmosphere in which the gas detection element is actually installed is worse than the atmosphere in which the reference voltage is set, the predetermined threshold is exceeded by a small amount of gas. Therefore, even if the odor generating tool does not emit gas (a volatilized odor generating material), it may be determined that the temperature of the device has increased due to the intrusion of homogeneous gas from the outside. Conversely, if the atmosphere in which the gas detection element is actually installed is better than the atmosphere when setting the reference voltage, a large amount of gas is required to exceed the predetermined threshold. Therefore, there is a possibility that the time until the temperature rise of the device is detected becomes long, or the temperature rise cannot be detected depending on the capacity of the odor generating material accommodated in the odor generating tool. Therefore, the temperature detection system described in Patent Document 1 has room for improvement in order to further improve the stability of the detection.

  The present invention was devised in view of the above problems, and is not dependent on the quality of the atmosphere when detecting an increase in temperature by detecting a gas released when a predetermined temperature is reached. An object of the present invention is to realize a temperature detection system capable of detecting a temperature rise with stability.

In order to achieve the above object, a temperature detection system according to the present invention for detecting a temperature rise of a device housed in a fixed volume box having a predetermined ventilation has the following characteristic configuration. Its feature configuration is
A gas generating material that generates gas by vaporizing due to a temperature rise of the device is accommodated in a container in which a gas discharge hole is formed, and the gas discharge hole is sealed with a sealing material that melts at a predetermined temperature. And a temperature detecting element installed in the device housed in the box,
A gas detection element installed in the box for detecting the concentration of the gas in the atmosphere in the box;
Based on the output of the gas detection element, an increase degree calculation unit that calculates an increase degree indicating the degree of increase in the gas per unit time;
A determination unit that determines whether or not the degree of increase is a predetermined threshold value or more ,
The increase degree calculation unit, as the increase degree,
When the gas increases, the first increase degree in which the gas increases during the first unit time is calculated, and when the gas decreases, the first increase degree is calculated as zero.
The second increment that increases during the second unit time set to n times the first unit time, where n is a natural number, is the first increment that is repeatedly calculated within the second unit time. Calculate by moving and accumulating over the course of one unit time,
The determination unit, as the predetermined threshold,
A first threshold for the first degree of increase;
The determination is made using a second threshold value for the second increase degree set to a value larger than the first threshold value .

  According to the inventor's research and development, when a certain volume of gas is generated in a certain volume of space with a ventilation volume over a certain period of time, the rate of increase in the gas concentration in the space at the beginning of generation does not depend on the ventilation volume I understood it. As described above, according to this feature configuration, the increase degree calculation unit is provided, and the increase degree indicating the degree of increase in the gas per unit time is calculated. This degree of increase shows the same tendency in the early stage of gas generation regardless of the ventilation amount and the state of the atmosphere in the box. Therefore, by determining the degree of increase based on a predetermined threshold value, a temperature detection system having high stability can be realized without depending on the quality of the atmosphere.

As described above, the temperature detection system according to the present invention, prior Symbol increased degree calculation unit, as the increasing degree, and the first increase of the second increased degree calculating, the determining unit, the predetermined tooth The threshold value is determined using a first threshold value for the first increase degree and a second threshold value for the second increase degree.
Here, the first increase degree is a degree that the gas increases during the first unit time. The increase degree calculation unit calculates the first increase degree by calculating the increase when the gas increases, and assuming that the increase is zero when the gas decreases.
The second increase degree is a degree that increases during a second unit time set to n times the first unit time, where n is a natural number. The increase calculation unit calculates the second increase by moving and integrating the first increase calculated repeatedly within the second unit time as the first unit time elapses.
The second threshold value is set to a value larger than the first threshold value.

According to this feature, the temperature rise of the apparatus is determined based on the degree of increase with respect to two unit times, that is, the first unit time and the second unit time set longer than the first unit time. Considering convection and the like, there is a possibility that the first increase degree with respect to a short unit time, for example, the first unit time may increase or decrease. However, it is possible to determine whether the trend is increasing or decreasing, based on the second increase degree with respect to the second unit time having a span longer than the first unit time. Accordingly, accurate determination can be made. In addition, when the first increase degree is decreasing, it is not necessary to determine the temperature increase in the first unit time. If a negative number is not calculated by setting the degree of increase to zero, the calculation load can be suppressed. Also, when calculating the second increase degree, it is not necessary to perform addition including a negative number, so that the calculation load can be suppressed.
The first threshold value and the second threshold value can be arbitrarily set independently. It is also possible to make a determination using only the second increase degree by setting one of the threshold values, for example, the first threshold value to zero.

  Here, it is preferable that the second threshold value is set to a value larger than a value obtained by multiplying the first threshold value by n.

  Since the n first increments are included in the second unit time, if all of the first increments included in one second unit time are equal to or greater than the first threshold, the second unit time In the meantime, it increases by n times the first threshold value. Therefore, if the second threshold value is larger than the value obtained by multiplying the first threshold value by n, it is determined that the average increase in the second unit time is equal to or greater than the first threshold value. More accurate determination is possible.

  Further, in the temperature detection system according to the present invention, the determination unit determines whether or not the gas is emitted from the temperature detection element in the box based on the degree of increase. And

  As the device stored in the box generates heat, a gas having the same component as the temperature detection element may be generated from the device. Further, since the box in which the apparatus is housed has a predetermined ventilation rate, it is possible that gas having the same components as the temperature detection element may enter from the outside of the box. However, the increase in concentration due to the gas generated from the apparatus and the gas entering from the outside is more gradual than in the case where rapidly vaporized gas is released in the box. Therefore, an accurate determination can be made by determining whether or not the detected gas is emitted from the temperature detection element based on the degree of increase.

Further, the temperature detection system according to the present invention is characterized in that the gas detection element is further arranged outside the box and is configured as follows.
The increase degree calculation unit calculates the increase degree based on the output of the gas detection element arranged in the box and the increase degree based on the output of the gas detection element arranged outside the box, respectively. To do.
The determination unit calculates a time difference between times when the gas starts to increase based on the calculated increase degree, and the gas enters the inside of the box from the outside of the box based on the time difference. It is determined whether it has been released or has been emitted from the temperature detection element in the box.

When gas enters from the outside of the box, the gas is present outside the box first. Therefore, the gas detection device installed outside the box can detect the gas before the gas detection element installed inside the box. On the contrary, when the gas is released from the temperature detection element, the gas detection element inside the box detects the gas first. According to this feature, gas detection elements are arranged inside and outside the box. Therefore, it is possible to more accurately determine whether the gas is released from the inside or from the outside based on the time difference between the times when the gas starts to increase.
As one aspect, a temperature detection system according to the present invention includes:
A temperature detection system for detecting a temperature rise of a device housed in a constant volume box having a predetermined ventilation amount,
A gas generating material that generates gas by vaporizing due to a temperature rise of the device is accommodated in a container in which a gas discharge hole is formed, and the gas discharge hole is sealed with a sealing material that melts at a predetermined temperature. And a temperature detecting element installed in the device housed in the box,
A gas detection element installed in the box for detecting the concentration of the gas in the atmosphere in the box;
Based on the output of the gas detection element, an increase degree calculation unit that calculates an increase degree indicating the degree of increase in the gas per unit time;
A determination unit that determines whether the increase degree is equal to or greater than a predetermined threshold;
With
The gas detection element is further arranged outside the box,
The increase degree calculation unit calculates the increase degree based on the output of the gas detection element arranged in the box and the increase degree based on the output of the gas detection element arranged outside the box, respectively. And
The determination unit calculates a time difference between times when the gas starts to increase based on the calculated increase degree, and the gas enters the inside of the box from the outside of the box based on the time difference. It is preferable to determine whether it has been released or has been released from the temperature detection element in the box.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram schematically showing an overview of a monitoring system 200 to which the temperature detection system 100 of the present invention is applied. The monitoring system 200 is a system for monitoring excessive heat generation of monitored equipment such as mechanical equipment, electrical equipment such as a switchboard, and a computer such as a server. In the example illustrated in FIG. 1, the monitored facility is the electrical facility 11. The electrical equipment 11 is accommodated in the cubicle 10. The cubicle 10 is a box including a ventilation fan 12 and an armor window 13 and a space having a predetermined volume with a predetermined ventilation amount. When natural ventilation is sufficient, the ventilation fan 12 may not be provided and only the armor window 13 may be provided. The electrical equipment 11 may generate heat due to an increase in load, contact failure, short circuit, electric leakage, or the like, resulting in failure or fire. In order to prevent such a situation, the electrical equipment 11 is provided with a temperature detection element 4 for detecting heat generation.

  FIG. 2 is a perspective view showing the structure of the temperature detecting element 4. The temperature detecting element 4 contains an odorous substance (gas generating substance) 42 in a can-like sealed container 41. The odorous substance 42 is, for example, isopropanol, ethanol (boiling point: about 78 ° C.), etc., and is vaporized by the temperature rise of monitored equipment such as the electrical equipment 11 to generate odorous gas. The sealed container 41 is formed with a gas discharge hole 43 for discharging the vaporized gas. The gas discharge hole 43 is sealed as shown in FIG. 2A by a sealing material 44 that melts at a predetermined temperature. A low melting point alloy such as a low melting point solder having a melting point of about 60 to 96 ° C. is used for the sealing material 44. As the composition of other low melting point alloys, indium-tin alloy, tin-bismuth alloy, indium-bismuth alloy, indium-tin-bismuth alloy and the like are suitable. A desired melting point can be set by appropriately changing the ratio of the alloy. An adhesive tape 45 is provided on one surface of the temperature detection element 4, and the temperature detection element 4 can be attached to the monitored facility by using this.

  In addition, since the place where the temperature detection element 4 is affixed is not always a flat surface with good adhesiveness, the temperature detection element 4 can be installed by various methods other than using the adhesive tape 45. For example, it is installed using a metal attachment on the heads of bolts of the switchboard. In addition, for example, a wire-like adapter is used for an electric cable having a small outer diameter and a curvature of 30 mm or less.

  When the electrical equipment 11 generates heat and the temperature detection element 4 is heated, the odor substance 42 starts to vaporize. On the other hand, the sealing material 44 is melted due to overheating of the temperature detection element 4, and vaporized gas is released from the gas discharge holes 43. The released gas diffuses into the cubicle 10.

  The temperature detection system 100 according to the present embodiment includes a temperature detection element 4 and a gas detection device 1. As shown in FIG. 1, a gas detection device 1 that detects the concentration of gas in the atmosphere in the cubicle 10 is attached to the cubicle 10. When the temperature detection element 4 releases the gas into the cubicle 10 and the gas detection device 1 determines that the gas concentration is equal to or higher than the predetermined value, the determination result is transmitted to the monitoring control unit 20 via the transmission means 30. . The transmission means 30 may use a wired cable or the like, or may use wireless communication. Other cubicles 10A, 10B, and 10C shown in FIG. 1 are also provided with a similar temperature detection system 100, and the monitoring system 200 can monitor a plurality of cubicles.

  FIG. 3 is a block diagram schematically showing the configuration of the gas detection device 1. FIG. 4 is a perspective view showing the structure of the gas detection element 5. The gas detection device 1 includes a gas detection unit 2 and a control unit 3. The gas detection element 5 is a heat-wire type formed by applying and firing a sensitive layer 52 mainly composed of a metal oxide semiconductor such as tin oxide on a noble metal wire coil 51 such as platinum, palladium, or platinum-palladium alloy. It is a semiconductor gas sensor. The hot-wire semiconductor gas sensor has a different resistance value depending on the gas concentration of the gas to be detected. As shown in FIG. 3, the gas detection element 5 is incorporated in a bridge circuit, and a voltage that changes according to a change in the resistance value of the gas detection element 5 is measured by the measurement unit 8. The gas detection element 5 is not limited to the hot-wire semiconductor gas sensor, but may be a gas sensor of another type such as a contact type or a gas thermoelectric type.

  A voltage value indicating the gas concentration measured by the measurement unit 8 is input to the control unit 3. The control unit 3 includes an increase degree calculation unit 6 and a determination unit 7. Based on the output of the gas detection element 5, the increase degree calculation unit 6 calculates an increase degree indicating the degree to which the gas to be detected increases per unit time. The determination unit 7 determines whether the calculated increase degree is equal to or greater than a predetermined threshold value. The determination result is sent to the monitoring control unit 20 as shown in FIG. Details of the increase degree calculation unit 6 and the determination unit 7 will be described later.

  FIG. 5 is a graph showing an example of a change in the concentration of gas emitted from the temperature detecting element 4 installed in the cubicle 10 having a certain volume with ventilation. As shown in the figure, the gas concentration in the cubicle 10 rapidly increases at the initial stage of gas generation, and gradually decreases after reaching the peak Cp. The temperature at which the odorant 42 vaporizes (first temperature; for example, 78 ° C.) and the melting point (second temperature; for example, 60 to 96 ° C.) of the sealing material 44 are set to be close to each other. Gas continues to be generated until all of the odorous substance 42 is vaporized, and the vaporized gas is discharged from the gas discharge hole 43 into the cubicle 10. When the temperature at which the odor substance 42 vaporizes is lower than the melting point of the sealing material 44, the gas is filled in the sealed container 41 before the gas discharge hole 43 is opened. In this case, since the gas is released at the same time as the gas discharge hole 43 is opened, the gas concentration in the cubicle 10 increases more rapidly.

Here, a case where a gas generation source (for example, the temperature detection element 4) is present in a space (for example, the cubicle 10) in which the volume U and the ventilation amount (for example, the number of ventilations N per hour) are determined is considered. It is assumed that the gas generation source generates a gas with a constant generation amount Et within a limited time T ₀ . That is, the average gas generation rate M is expressed by the following equation (1). At this time, the time dependency C (t) of the gas concentration in the space is expressed by the following equations 2 and 3.

Equation 2 is an expression showing a period during which the gas concentration increases from the start of gas discharge to the time after the lapse of T ₀ seconds. The gas concentration reaches a peak Cp at time T _{0 as} shown in FIG. As is clear from Equations 1 and 2, the peak Cp is a function of the volume U, the ventilation amount (the number of ventilations) N, the generation amount Et, and the time T ₀ . Equation 3 shows that the gas concentration in the space gradually decreases due to ventilation from the peak Cp.

If the gas detection apparatus 1 uses a determination method based on the conventional gas concentration value, the threshold concentration AL, the arrival time T _AL , and the delay time Td are related to gas detection. That is, after the start of gas discharge, the gas concentration in the space exceeds the threshold concentration AL after the arrival time T _AL , and the gas is detected after a predetermined delay time Td has elapsed. The delay time Td is a standby time for confirming that the gas concentration has surely exceeded the threshold concentration AL in order to prevent erroneous determination. FIG. 5 illustrates a case where the threshold concentration AL is 30 ppm.

By the way, the change in the concentration of the gas in the cubicle 10 varies depending on the number of ventilations N. FIG. 6 is a graph showing changes in gas concentration for each ventilation frequency N. FIG. FIG. 6 shows changes in gas concentration when the volume U, the generated amount Et, and the time T ₀ are constant, for each of the cases where the ventilation frequency N per hour is 1, 5, 10, 50, and 100. Is. As is clear from FIG. 6, the value of the gas concentration peak Cp decreases as the ventilation frequency N increases. For example, if the ventilation frequency N is large, there is a possibility that the threshold concentration will not be exceeded depending on the atmospheric conditions in the cubicle 10.

When the generation amount Et, the time T ₀ , and the delay time Td are determined and the relationship between the volume U and the ventilation frequency N is shown, an area where gas can be detected can be displayed. FIG. 7 is a graph showing the relationship between the volume U of the cubicle 10 and the ventilation frequency N for each threshold concentration AL. The lower region of each characteristic curve indicates a region where gas can be detected, and the upper region indicates a region where gas cannot be detected. For each threshold concentration AL, the maximum volume U _max at which gas can be detected is when the ventilation frequency N = 0. As shown in FIG. 7, in principle, when the ventilation frequency N increases, the volume U in which gas can be detected decreases. That is, when the number of ventilations N is large, it is difficult to detect gas unless the volume of the cubicle 10 is small. Of course, the lower the threshold concentration AL, the wider the area where gas can be detected. That is, in order to deal with the cubicle 10 having a large ventilation function N and a large capacity, it is necessary to lower the threshold concentration AL, but as described above, it is easily affected by a change in the state of the atmosphere.

  Thus, in the conventional gas detection method using the threshold concentration AL, the volume U of the cubicle 10 is determined, and when the threshold concentration AL is set, the maximum ventilation frequency N that can detect gas is also determined. However, since the steady heat generation amount of the devices accommodated in the cubicle 10 has been increasing in recent years, there is a desire to increase the ventilation frequency N also in terms of cooling. Therefore, an increase in the allowable ventilation frequency N is desired.

  Therefore, in the gas detection device 1 of the present invention, the determination is performed using the degree of increase in the cubicle 10 instead of using the threshold value AL as a determination criterion using the concentration value itself. Here, the degree of increase indicates the degree to which the gas increases per unit time. A change in gas concentration per unit time is expressed by differentiating the equations 2 and 3 in principle. The differential C ′ (t) with respect to the time t of the time dependency C (t) of the gas concentration in the space is expressed by the following equations 4 and 5.

As is clear from Equation 4, the differential value is the maximum value of C ′ (t) = M / U at the time t = 0 when the gas is generated, and then gradually decreases until time T ₀ . After time T ₀ , it becomes a negative value and gradually increases thereafter. What should be noted here is the initial value of C ′ (t). As shown in the following formula 6, it depends only on the gas generation amount Et, the time T ₀ , and the volume U, and is independent of the ventilation frequency N. Further, the influence of the ventilation frequency N is smaller as the time t equivalent to the time from gas generation is smaller, that is, the earlier the gas is generated.

FIG. 8 is an explanatory diagram showing the relationship between the increase degree and the increase degree threshold value. In FIG. 8, a waveform P1 schematically shows a waveform when gas is released from the temperature detecting element 4. Further, the waveform P2 schematically shows the waveform when the atmosphere in the cubicle 10 is fluctuated by the gas generated from the electrical equipment 11 or the gas entering from outside the cubicle 10, regardless of the temperature detecting element 4. Yes. As described above, since the gas built in the temperature detection element 4 is released within a short time through the gas discharge hole 43, the waveform P1 rises rapidly with an increase Z1. On the other hand, the gas concentration due to a factor different from that of the temperature detecting element 4 rises slowly at an increase degree Z2 as shown by the waveform P2. Therefore, it is possible to satisfactorily detect the gas derived from the gas discharge of the temperature detection element 4 with the increase degree Z _TH between the increase degree Z1 and the increase degree Z2 as a predetermined threshold value (threshold increase degree). it can. Details will be described later using specific numerical examples.

FIG. 9 is an explanatory diagram for comparing a conventional gas detection method using a concentration value with a gas detection method using the degree of increase of the present invention. 9A shows a case where the atmosphere of the cubicle 10 is standard, FIG. 9B shows a case where the atmosphere is good, and FIG. 9C shows a case where the atmosphere is bad. Similarly to FIG. 8, the waveform P <b> 1 indicates a waveform when gas is released from the temperature detection element 4, and the waveform P <b> 2 indicates a waveform due to gas not related to the temperature detection element 4. The vertical axis in FIG. 9 indicates the voltage value of the sensor output from the gas detector 2. V _TH is a threshold voltage with respect to the voltage value of the sensor output corresponding to the threshold concentration AL. Moreover, the code | symbol dt in a figure is unit time.

In FIG. 9A, the sensor output voltage with respect to the gas concentration in the atmosphere is substantially zero (Vref). Therefore, the gas derived from the temperature detecting element 4 shown as the waveform P1 is detected beyond the threshold voltage V _TH with respect to the sensor output even in the conventional gas detection method using the concentration value. Naturally, the increase degree Z1 also exceeds the threshold increase degree _ZTH , so that gas is detected even when the increase degree is used. On the other hand, the gas not related to the temperature detection element 4 shown as the waveform P2 is detected because it does not exceed the respective threshold value in both the gas detection method using the concentration value and the gas detection method using the degree of increase. Never happen.

In FIG. 9B, the sensor output voltage with respect to the gas concentration in the atmosphere is lower than zero (Vref). Accordingly, the gas derived from the temperature detection element 4 shown as the waveform P1 does not exceed the threshold voltage V _TH for the sensor output in the conventional gas detection method using the concentration value, and no gas is detected. However, since the increase degree Z1 exceeds the threshold increase degree _ZTH , gas is detected when the increase degree is used. On the other hand, the gas not related to the temperature detection element 4 shown as the waveform P2 does not exceed the respective threshold value in both the gas detection method using the concentration value and the gas detection method using the degree of increase. It will never be done.

In FIG. 9C, the sensor output voltage with respect to the gas concentration in the atmosphere exceeds zero (Vref). Therefore, the gas derived from the temperature detecting element 4 shown as the waveform P1 is detected beyond the threshold voltage V _TH with respect to the sensor output even in the conventional gas detection method using the concentration value. Naturally, the increase degree Z1 also exceeds the threshold increase degree _ZTH , so that gas is detected even when the increase degree is used. On the other hand, the gas not related to the temperature detection element 4 shown as the waveform P2 exceeds the threshold value V _TH in the gas detection method using the concentration value and is detected. However, in the gas detection method using the degree of increase, the degree of increase Z2 is not detected because it does not exceed the threshold degree of increase _ZTH .

  In this way, by using the degree of increase, it is possible to realize the temperature detection system 100 that can detect a temperature rise with high stability without depending on the quality of the atmosphere. Hereinafter, the gas detection procedure using the degree of increase will be described in detail using specific numerical values.

  FIG. 10 is an explanatory diagram illustrating an example of a procedure for calculating the degree of increase. FIG. 10A is an enlarged waveform at the time when the gas concentration starts to increase as shown in region A of FIG. Here, the vertical axis indicates not the density value but the voltage value of the sensor output. The sensor output from the gas detection unit 2 shown in FIG. 3 is input to the increase degree calculation unit 6 of the control unit 3. The increase degree calculation unit 6 receives the sensor output digitally converted at a predetermined sampling interval. Sampling and digital conversion may be performed by the increase degree calculation unit 6, but may be performed by the control unit 3 and other functional units (including functional units not shown). For example, with respect to sampling, a sensor output may be obtained by controlling the power supply 9 from the control unit 3 and switching the energization interval. The measurement unit 8 may have an A / D conversion function, and the measurement unit 8 may perform digital conversion.

  FIG. 10A shows sensor outputs at times t0 to t10 corresponding to each sampling timing t (i). FIG. 10B shows the voltage value V of the sensor output at each sampling timing, and the increasing degrees dV and DV calculated from these voltage values. In this example, the case where the first increase degree dV and the second increase degree DV are used as the increase degrees is shown. Further, a first unit time and a second unit time are set as unit times corresponding to the first increase degree dV and the second increase degree DV.

  The first increase degree dV indicates the degree to which the gas increases during the first unit time. In this example, the sampling interval is the first unit time dt. The second increase degree DV indicates the degree to which the gas increases during the second unit time. The second unit time is a time (= dt × n) set to n times the first unit time, where n is a natural number. In this example, a case where n = 3 (second unit time = 3 dt) will be described as an example. The first unit time can also be m times the sampling interval, where m is a natural number. In this example, m = 1.

  As shown in FIG. 10B, an increase dV (i) between the voltage value V (i) acquired at each sampling timing and the voltage value V (i-1) acquired at the previous sampling timing. ) Is calculated. That is, the first increase degree dV (i) in which the gas increases during the first unit time (dt = t (i) −t (i−1)) is calculated. Here, when the gas increases, the increase (V (i) −V (i−1)) is set as the first increase dV (i) (the increase includes zero). If the gas decreases, the increase is considered zero.

  As shown in FIG. 10B, the first increase dV (1) is calculated to be 0.004 at time t1. At time t2 and time t3, the voltage value V of the sensor output decreases compared to the previous time t1 and time t2. As described above, in this example, when the gas decreases, the increase is regarded as zero, so the first increase degrees dV (2) and dV (3) are calculated to be zero.

  As shown in FIG. 10B, the first increase dV repeatedly calculated within the second unit time corresponding to each sampling timing is moved and integrated as the first unit time dt elapses. The degree of increase DV is calculated. The movement accumulation corresponds to a multiple n of the second unit time with respect to the first unit time dt, and n first increments dV are accumulated. That is, when the first increase degree dV (i) is calculated, the three first increase degrees dV (i), dV (i-1), and dV (i-2) are integrated to obtain the second increase degree. DV (i) is calculated. Thus, since the three first increase degrees dV are required for the calculation of the second increase degree DV, the second increase degree DV is calculated after time t3 in this example shown in FIG. 10B. .

  When the increase degree calculation unit 6 calculates the first increase degree dV and the second increase degree DV, the determination unit 7 performs the determination based on these increase degrees. The determination unit 7 performs determination based on the first threshold value and the second threshold value set for the first increase degree dV and the second increase degree DV, respectively. The first threshold value and the second threshold value can be arbitrarily set independently. By setting one of the threshold values, for example, the first threshold value to zero, the determination can be made using only the second increase degree DV. When the determination is made using both threshold values, since the second increase degree DV is obtained by integrating n first increase degrees dV, the second threshold value is at least n times the first threshold value. This is preferable. In this example, the first threshold value is set to 0.03V, the second threshold value is set to 0.1V, and values larger than n times are set.

  As shown in FIG. 10A, the gas concentration rises at time t6. Accordingly, as shown in FIG. 10B, the first increase dV (7) calculated at time t7 is 0.035V, which is equal to or higher than the first threshold value (= 0.03V). The second increase degree DV (7) calculated at time t7 is larger than the second increase degrees DV (3) to DV (6) until then, but the second threshold value (= 0. 1V) or more.

  Since the gas concentration has increased since time t6, as shown in FIG. 10 (b), the first increase dV (7) to dV (10) calculated from time t7 to time t10 is the first. Above the threshold. At time t9, the second increase degree DV (9) obtained by moving and integrating the first increase degrees dV (7) to dV (9) becomes 0.110V, which is equal to or higher than the second threshold value. The second increase degree DV (10) (= 0.105V) calculated at time t10 is also equal to or higher than the second threshold value.

  The determination unit 7 determines that the first increase dV (7) is greater than or equal to the first threshold at time t7, and the second increase DV (9) n times after that (after the first unit time × n). Is determined to be greater than or equal to the second threshold value, it is determined that gas has been released from the temperature detecting element 4. Then, the determination result is transmitted to the monitoring control unit 20. If the first increase dV (i) does not exceed the first threshold value, it is not necessary to determine the second increase DV (i). Therefore, in FIG. DV (3) to DV (6) are shown in parentheses. As another embodiment, it may be determined that gas has been released from the temperature detection element 4 when the first increase dV continuously reaches the first threshold value n times or more. In this case, the first increase degree dV of the group corresponds to the second increase degree DV, and the number of consecutive times n corresponds to the second threshold value.

Thus, since the determination part 7 determines based on the 1st increase degree dV and the 2nd increase degree DV, stable and accurate determination is attained. For example, it is assumed that the gas concentration in the cubicle 10 has changed as shown in FIG. Here, the threshold concentration AL is 30 ppm. When the determination unit 7 determines based on the voltage value V (i) of the sensor output, the threshold voltage V _{TH obtained} by converting the threshold concentration AL into a voltage value is used.

  The gas concentration increases on the left side of FIG. At this time, the first increase dV may be equal to or higher than the first threshold value (indicated by a circle in the figure). However, as indicated by a cross in the figure, if the second degree of increase DV is not equal to or greater than the second threshold value, the degree of increase here is determined as the degree of increase Z2 due to a factor other than the temperature detecting element 4. Is done. Further, the gas concentration also increases at the central portion of FIG. At this time, since both the first increase degree dV and the second increase degree DV do not exceed the threshold value, it is similarly determined that the increase degree Z2 is due to a factor different from the temperature detection element 4. On the right side of FIG. 11A, both the first increase degree and the second increase degree are equal to or greater than the threshold value. Therefore, it is determined that the degree of increase Z1 is due to gas emission by the temperature detecting element 4.

FIG.11 (b) is the elements on larger scale of Fig.11 (a). As shown in FIG. 11B, the gas concentration does not always increase monotonously. There is a possibility that it increases with a temporary decrease due to the relationship between the discharge from the temperature detection element 4 and ventilation or convection. Accordingly, if both the first increase degree dV is equal to or higher than the first threshold value and the second increase degree DV is equal to or higher than the second threshold value are determined as the determination conditions, Depending on the set value, there is a possibility that the degree of increase Z1 due to gas emission by the temperature detecting element 4 is not determined. As described above, the degree of increase dV when the gas concentration decreases is calculated as zero, and the first threshold value and the second threshold value can be set independently of each other. Therefore, if the first threshold value dV _TH is set to zero as shown in FIG. 11B, the determination result for the first increase dV can always be equal to or greater than the first threshold value. In this case, it is apparently determined using only the second increase degree DV.

In addition, if a plurality of threshold values Z _TH for the degree of increase are set, it is possible to determine an increase in gas concentration due to a plurality of factors. As described above, the increase in gas concentration when the temperature detecting element 4 releases gas is steep. On the other hand, the increase in gas concentration due to the gas not related to the temperature detection element 4 is slower than that. Therefore, it is possible to determine whether or not the gas is released from the temperature detecting element 4 in the cubicle 10 based on the degree of increase.

As described in detail with reference to FIGS. 5 to 11, the determination is based on the degree of increase in the gas concentration, not based on the absolute value (level value) of the gas concentration. Can be realized. Further, as shown in FIG. 5, an arrival time _TAL occurs until the gas concentration reaches the threshold concentration AL. In the determination based on the concentration value, the delay time Td is required even after the gas concentration reaches the threshold concentration AL. However, since the determination based on the degree of increase according to the present invention is performed at an early stage when the concentration starts to increase as shown by a region A in FIG. 6, the gas is released at a timing much earlier than the arrival time _TAL. Can be determined. Further, since it is not the determination of the density value, the delay time Td is not necessary, and the determination can be performed in a short time.

Further, as described with reference to FIG. 7, in the determination method based on the absolute value (level value) of the gas concentration, only the region below the characteristic curve between the volume U of the cubicle 10 and the ventilation frequency N is effectively gas. Cannot be detected. FIG. 12 shows a characteristic curve L1 of the volume U and the ventilation frequency N when the threshold concentration AL is 30 ppm, and a gas detectable region as a representative. In the determination method based on the absolute value of the gas concentration, the gas can be detected effectively only in the region a shown in FIG. However, if the determination method based on the degree of increase is used, the characteristic curve L1 can be moved to the characteristic curve L2 on the region c side where determination is impossible. As a result, the area b can be added to the area a to enlarge the effective area. For example, when the volume U of the cubicle 10 is 3 m ³ , the upper limit of the ventilation frequency N is N1 according to the conventional characteristic curve L1. However, according to the extended characteristic curve L2, the upper limit of the ventilation frequency N is N2, which is a value larger than N1.

[Other Embodiments]
FIG. 13 is a block diagram schematically showing an outline of another embodiment of the monitoring system 200. In the present embodiment, the gas detection devices 1 are installed at two locations inside and outside the cubicle 10. An internal gas detection device 1A (1) is installed inside the cubicle 10, and an external gas detection device 1B (1) is installed outside. Other configurations of the monitoring system 200 are the same as those shown in FIG. 1, and are denoted by the same reference numerals. The internal configurations of the internal gas detection device 1A and the external gas detection device 1B are the same as those shown in FIG.

  In the present embodiment, the internal gas detection device 1A and the external gas detection device 1B each detect gas and calculate the degree of increase. The increase degree calculation unit 6 of the internal gas detection device 1A calculates the increase degree based on the output of the gas detection element 5 arranged in the cubicle 10. The increase degree calculation unit 6 of the external gas detection device 1B calculates the increase degree based on the output of the gas detection element 5 arranged outside the cubicle 10. The degree of increase calculated by the external gas detection device 1B is input to the internal gas detection device 1A. The determination unit 7 of the internal gas detection device 1A calculates a time difference between the times when the gas concentration starts to increase based on the degree of increase calculated by the internal gas detection device 1A and the external gas detection device 1B. Based on this time difference, the determination unit 7 determines whether the gas has entered from the outside of the cubicle 10 or has been released from the temperature detection element 4 in the cubicle 10.

  FIG. 14 is a graph showing a change in the concentration of gas that rises due to the same factor and is detected by two gas detection devices. In this example, a case where gas enters from outside the cubicle 10 is shown. The gas existing outside the cubicle 10 is first detected by the external gas detection device 1B, and the degree of increase is calculated at the rising start time Ta. Next, when the gas enters the cubicle 10, it is detected by the internal gas detection device 1A, and the degree of increase is calculated at the rising start time Tb. Then, a difference Tb-Ta between the two rising start times is calculated. In this example, since the detection time by the external gas detection device 1 is earlier, it is determined that the gas is not emitted from the temperature detection device 4 but comes from outside the cubicle 10. The determination result is transmitted to the monitoring control unit 20.

  In the above description, the degree of increase calculated by the external gas detection device 1B is input to the internal gas detection device 1A, and the determination unit 7 of the internal gas detection device 1A calculates the time difference. However, the present invention is not limited to this, and the degree of increase calculated by the internal gas detection device 1A may be input to the external gas detection device 1B, and the determination unit 7 of the external gas detection device 1B may calculate the time difference. Further, the increase degree calculated by the internal gas detection device 1A and the external gas detection device 1B and the determination result based on the increase degree may be transmitted to the monitoring control unit 20, and the monitoring control unit 20 may calculate the time difference.

  As described above, according to the present invention, it is possible to realize a temperature detection system capable of detecting a temperature rise with high stability without depending on whether the atmosphere is good or bad.

The block diagram which shows typically the outline | summary of the monitoring system to which the temperature detection system of this invention is applied Perspective perspective view showing structure of temperature detecting element Block diagram schematically showing the configuration of the gas detector Perspective perspective view showing structure of gas detection element The graph which shows an example of the density | concentration change of the gas discharge | released from the temperature detection element installed in the equipment in the fixed volume cubicle Graph showing gas concentration change for each ventilation rate Graph showing the relationship between cubicle volume and ventilation rate for each threshold concentration Explanatory diagram showing the relationship between the degree of increase and the threshold of increase Explanatory drawing which compares the gas detection method using the conventional concentration value with the gas detection method using the increase degree of this invention Explanatory drawing which shows an example of the procedure which calculates the increase degree Explanatory drawing which shows the effect of the gas detection method using the 1st increase degree and the 2nd increase degree Explanatory drawing which shows that the area | region which can detect the gas defined based on the relationship between a volume and a ventilation volume is expanded. The block diagram which shows typically the outline | summary of other embodiment of the monitoring system Graph showing the change in concentration of gas that rises due to the same factor and is detected by two gas detectors

Explanation of symbols

4: Temperature detection element 41: Sealed container (container)
42: Odorous substance (gas generating substance)
43: Gas discharge hole 44: Sealing material 5: Gas detection element 6: Increase degree calculation unit 7: Determination unit 10: Cubicle (a box having a constant volume)
11: Electrical equipment (accommodated equipment)
100: Temperature detection system Z1, Z2: Increase degree dV: First increase degree DV: Second increase degree dV _TH : First threshold dt: Unit time, first unit time N: Ventilation frequency (ventilation volume)

Claims (5)

A temperature detection system for detecting a temperature rise of a device housed in a constant volume box having a predetermined ventilation amount,
A gas generating material that generates gas by vaporizing due to a temperature rise of the device is accommodated in a container in which a gas discharge hole is formed, and the gas discharge hole is sealed with a sealing material that melts at a predetermined temperature. And a temperature detecting element installed in the device housed in the box,
A gas detection element installed in the box for detecting the concentration of the gas in the atmosphere in the box;
Based on the output of the gas detection element, an increase degree calculation unit that calculates an increase degree indicating the degree of increase in the gas per unit time;
A determination unit that determines whether the increase degree is equal to or greater than a predetermined threshold;
Equipped with a,
The increase degree calculation unit, as the increase degree,
When the gas increases, the first increase degree in which the gas increases during the first unit time is calculated, and when the gas decreases, the first increase degree is calculated as zero.
The second increment that increases during the second unit time set to n times the first unit time, where n is a natural number, is the first increment that is repeatedly calculated within the second unit time. Calculate by moving and accumulating over the course of one unit time,
The determination unit, as the predetermined threshold,
A first threshold for the first degree of increase;
A second threshold for the second degree of increase set to a value greater than the first threshold;
Judge using
Temperature detection system. The temperature detection system according to claim 1 , wherein the second threshold value is set to a value larger than a value obtained by multiplying the first threshold value by n. The temperature detection system according to claim 1 or 2 , wherein the determination unit determines whether the gas is released from the temperature detection element in the box based on the degree of increase. The gas detection element is further arranged outside the box,
The increase degree calculation unit calculates the increase degree based on the output of the gas detection element arranged in the box and the increase degree based on the output of the gas detection element arranged outside the box, respectively. And
The determination unit calculates a time difference between times when the gas starts to increase based on the calculated increase degree, and the gas enters the inside of the box from the outside of the box based on the time difference. The temperature detection system according to any one of claims 1 to 3 , wherein it is determined whether or not the temperature detection element is discharged from the temperature detection element in the box. A temperature detection system for detecting a temperature rise of a device housed in a constant volume box having a predetermined ventilation amount,
A gas generating material that generates gas by vaporizing due to a temperature rise of the device is accommodated in a container in which a gas discharge hole is formed, and the gas discharge hole is sealed with a sealing material that melts at a predetermined temperature. And a temperature detecting element installed in the device housed in the box,
A gas detection element installed in the box for detecting the concentration of the gas in the atmosphere in the box;
Based on the output of the gas detection element, an increase degree calculation unit that calculates an increase degree indicating the degree of increase in the gas per unit time;
A determination unit that determines whether the increase degree is equal to or greater than a predetermined threshold;
With
The gas detection element is further arranged outside the box,
The increase degree calculation unit calculates the increase degree based on the output of the gas detection element arranged in the box and the increase degree based on the output of the gas detection element arranged outside the box, respectively. And
The determination unit calculates a time difference between times when the gas starts to increase based on the calculated increase degree, and the gas enters the inside of the box from the outside of the box based on the time difference. and whether those were the temperature detection systems that determine those emitted from the temperature detection element in the box.

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