JPS6343713B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for detecting failures in ultraviolet discharge tubes, which improves reliability without being affected by shutter closing accuracy.

The flame detection device uses an ultraviolet discharge tube (hereinafter referred to as a detection bulb) as a sensor to detect ultraviolet rays emitted from a flame, and determines the presence or absence of a flame. Conventionally, among the self-check functions to check whether flame detection devices such as fuel burners are operating with normal function, in order to identify failures in this detection bulb, the functions shown in Figures 1 and 2 are as follows. The method shown is used.

That is, FIG. 1 shows a flame detection device applied to a conventional method for detecting failures in ultraviolet discharge tubes, and FIG.
Figures 1 through 2 each show a timing chart of a conventional method for detecting failures in ultraviolet discharge tubes. First, the flame detection device shown in FIG. 1 will be briefly described. In FIG. 1, 1 is a detection sphere and 2 is a flame. A shutter 3 is provided between the detection bulb 1 and the flame 2 to be detected, and is used to determine whether or not there is a failure in the discharge tube. configured to work.

In other words, by passing the excitation current 6 through the coil 4, the shutter 3 closes and cuts off the flame 2, and by cutting off the excitation current 6, the shutter 3 opens and the ultraviolet rays 7 generated from the flame 2 are transmitted to the detection bulb. The ultraviolet rays 7 are detected by being incident on the ultraviolet rays 7. By opening and closing the shutter 3 in this manner, a malfunction in the detection bulb 1 is detected. In other words, even though the shutter 3 is closed and the incidence of ultraviolet rays to the detection bulb 1 is blocked, the flame detection device still detects the flame as if there was a flame. If it emits a signal, this detection bulb is determined to be malfunctioning.

By the way, since the flame detection signal has a time delay of several seconds with respect to the actual flashing of the flame 2, the operation of the shutter based on the above-mentioned principle and the determination of the presence or absence of a failure of the detection bulb can be made as shown in A of Fig. 2. This is being carried out at the timing shown below. In other words, a in Fig. 2 (showing the timing of the shutter opening/closing operation)
Even if the shutter 3 closes and blocks the incident ultraviolet rays as shown in the dot, the flame detection signal does not become "non-detected" as shown in point b in Figure 2 (indicating the timing of flame detection). , delayed by a few seconds. For this reason, Figure 2 (showing the timing of presence or absence of failure)
As shown at point c, the determination is made while looking at the time when the flame detection signal definitely becomes "undetected."

Although the shutoff accuracy of the shutter 3 is not perfect and has become loose, the shutter 3 and the discharge tube are arranged so that under normal flame conditions, closing the shutter 3 prevents light from hitting the discharge tube. The position of the flame may change instantaneously, and this change sometimes causes light leaking from the shutter 3 or light that has gone around the shutter 3 to hit the discharge tube. When this happens, the discharge tube detects ultraviolet light and enters the "detect" state. For this reason, in the conventional fault extraction method, if this "detection" occurs within the time required to determine the presence or absence of a fault, an erroneous determination will result (B in FIG. 2).

The present invention was made in order to eliminate the above-mentioned drawbacks of the conventional art, and includes an ultraviolet discharge tube that discharges in response to ultraviolet rays generated by a flame, and a shutter that prevents the ultraviolet rays from entering the discharge tube. In a method of detecting a malfunction in the ultraviolet discharge tube of the detection device, the shutter is opened to discharge the ultraviolet discharge tube, and then the shutter is closed, and the ultraviolet rays are emitted within a certain period of time from the time the shutter is closed. By determining whether the discharge of the discharge tube has stopped or not, and determining that the ultraviolet discharge tube has failed when the discharge does not stop even once, the present invention is not affected by shutter cut-off accuracy. An ultraviolet discharge system that not only makes it possible to determine the failure of an ultraviolet discharge tube immediately, but also allows the determination of discharge tubes to be performed continuously over a longer period of time, significantly improving the reliability of identifying failures in discharge tubes. The purpose of the present invention is to provide a method for removing a failed tube.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Examples of the method for extracting failures in ultraviolet discharge tubes according to the present invention will be described below with reference to the drawings. FIG. 3 is a flowchart for explaining one embodiment. When explaining the embodiment of the present invention using this flowchart, the flame detection device applied to the present invention will be described as using the flame detection device shown in FIG. 1. In this FIG. 3, 11 indicates a timer, and 12 indicates an AND circuit. The timer 11 generates an output after a time T after the input condition is met, that is, when the output of the AND circuit 12 continues for a certain period of time T without being interrupted even once. be.

Now, while the current 6 is not flowing through the electromagnetic coil 4 shown in FIG. 1, the shutter 3 remains open, but when this current 6 is passed, the shutter 3 closes. Step _S1 in FIG. 3 shows this state. In this state of step _S1 , the shutter 3 is closed,
The light incident on the detection sphere 1 is blocked. In this state, an input is supplied to one input terminal of the AND circuit 12. In the state of step _S1 , the detection ball 1 is detecting the flame 2 (step _S2 )
Then, a signal is also introduced to the other input terminal of the AND circuit 12. As a result, a signal is output from the AND circuit 12, and this signal is input to the timer 11. When this signal is inputted to the timer 11 continuously without any interruption during the time T, the timer 11 outputs an output after the time T, and in step _S3 , a "detected ball failure" is determined.

In other words, even though the incident light to the detection bulb 1 is blocked after the time T, the flame is not "detected" even once. ” is determined.

FIG. 4 is a flowchart for explaining a second embodiment of the method for extracting failures in ultraviolet discharge tubes according to the present invention. In the case of this second embodiment as well, the flame detection device shown in FIG. 1 will be used, and the same parts as in FIG. 3 will be described with the same reference numerals. 1st
When the coil 4 of the electromagnet shown in the figure is energized, the shutter 3 is closed, and the incident light from the flame ₂ to the detection bulb 1 is blocked in step S1, a signal is introduced into one input terminal of the AND circuit 12. .

In the state of step _S1 , if the detection ball 1 does not detect the flame 2 even once,
The AND circuit 12 outputs and this output is sent to step S ₄
memorize it. In other words, it is stored in step _S4 that a state has occurred in which the detection bulb 1 has not detected any flame even when the shutter 3 is closed and the light incident on the detection bulb 1 is blocked.

Further, the signal input to the AND circuit 12 in step _S1 is also applied to the timer 11. timer 11
After a time T has elapsed since this signal is applied, it is determined in step _S5 whether or not the memory contents storing the output of the AND circuit 12 are actually stored in step _S4 . If the result of this judgment is stored, it is determined in step _S6 that the detected ball is normal; if it is not stored, it is determined that the detected ball is malfunctioning in step _S7 .
It is determined that

As is clear from the above, if the detection bulb 1 is normal, the ultraviolet discharge tube utilizes the characteristic that the discharge always stops by blocking the incident ultraviolet 7 from the flame 2 to the detection bulb 1. (1) Block the incident ultraviolet rays for a certain period of time, continuously monitor the output of the detection bulb 1 during this period, and (2) If the discharge of the detection bulb 1 stops even once while monitoring the incident ultraviolet rays, this The detection bulb 1 is operating normally, and if it does not stop, it is determined to be malfunctioning.The failure of the detection bulb is detected with high precision and reliability without being influenced by temporary disturbances. be able to. Therefore, the present invention can be applied to a device that self-checks for failures in the flame detection section (sensor) by blocking the flame and the flame detection section (sensor).

As described in detail above, according to the method for detecting failures in ultraviolet discharge tubes of the present invention, a shutter is used to prevent ultraviolet rays generated from the flame from entering the ultraviolet discharge tube that discharges in response to flame and ultraviolet rays. , in the method for extracting a malfunction in the ultraviolet discharge tube,
The failure is identified by opening the shutter and discharging the ultraviolet discharge tube, then closing the shutter, and determining whether or not the discharge of the ultraviolet discharge tube has stopped within a certain period of time from the time the shutter was closed. The main feature is that the UV discharge tube failure can be determined without being affected by the shutter shut-off accuracy, and the determination time can be extended, and the discharge tube can be continuously detected. This makes it possible to determine whether the discharge tube is faulty or not, thereby significantly improving the reliability of identifying faulty discharge tubes.

[Brief explanation of drawings]

FIG. 1 is a diagram showing a flame detection device applied to the conventional method and the method of detecting a fault in an ultraviolet discharge tube according to the present invention, and FIGS. FIG. 3 is a flow chart for explaining one embodiment of the ultraviolet discharge tube failure extraction device of the present invention, and FIG. 4 is a flow chart for explaining another embodiment of the present invention. It is a flowchart. 1...ultraviolet discharge tube, 2...flame, 3...shutter, 4...coil, 5...iron core, 11...timer, 12...and circuit.

Claims (1)

[Claims] 1. A method for detecting a malfunction in the ultraviolet discharge tube of a flame detection device having an ultraviolet discharge tube that discharges upon receiving ultraviolet light generated by a flame, and a shutter that prevents the ultraviolet light from entering the discharge tube. After opening the shutter and discharging the ultraviolet discharge tube, the shutter is closed, and it is determined whether or not the discharge of the ultraviolet discharge tube has stopped within a certain period of time from the time the shutter was closed, and if the discharge has never stopped. 1. A method for detecting a failure in an ultraviolet discharge tube for a flame detection device, characterized in that the ultraviolet discharge tube is determined to be in failure when the ultraviolet discharge tube is not present.