KR20160097779A - Apparatus for producing fake flame - Google Patents

Abstract

The present invention relates to an apparatus for producing fake flame. According to the present invention, the apparatus for producing fake flame includes: a storing part; a control part for generating a fake flame control signal by using pattern information stored in the storing part; and an optical signal generating part for transmitting an optical signal corresponding to the fake flame control signal generated in the control part toward an external fire detector.

Description

{APPARATUS FOR PRODUCING FAKE FLAME}

The present invention relates to an apparatus for generating a virtual flame, and more particularly, to a device for generating a virtual flame for checking a normal operation state of a fire detector by causing a fire detector to be mistaken for a fire.

In recent years, fire detection sites have been widely used for detecting an occurrence of a fire and generating an alarm or informing an external manager or the like.

In other words, fire suppression is the most important factor, and if failure of primary pressure fails, it can cause damage to property and human life. Therefore, fire detectors are installed in cultural properties as well as homes, buildings, It is. An example of such a fire detector is shown in FIG.

That is, a sensor 2 for detecting a flame signal is provided outside the fire sensor 1, and a sensing signal of the sensor 2 is analyzed by a control device (not shown) Detects a fire, sounds a siren when a fire occurs, or transmits a fire occurrence signal through a predetermined communication module.

However, there is a problem that once installed, the fire detector can not easily confirm whether the fire detector operates normally until a fire occurs.

In other words, it is not desirable for a fire detector installer to ignite a bell or other flammable substance to test the normal operation of the fire detector, because it is likely to spread to an actual big fire.

However, if the fire detector is expected to operate normally and it is not periodically tested, it can not be confirmed even if a circuit fault occurs in the fire detector. As a result, when the fire occurs, the fire detector may not operate normally.

Particularly, problems such as wiring can be measured by using a circuit tester or the like, but a means for confirming in advance when an abnormality occurs in a sensor unit for detecting a flame at the time of a fire has not been proposed.

Patent Registration No. 10-1014319

SUMMARY OF THE INVENTION It is an object of the present invention to provide a virtual flame generating apparatus capable of checking whether a fire detector operates normally without actually emitting a fire.

According to an aspect of the present invention, there is provided a virtual spark generating apparatus comprising: a storage unit; A control unit for generating a virtual flame control signal using pattern information stored in the storage unit; And an optical signal generator for emitting an optical signal corresponding to the virtual spark control signal generated by the controller toward an external fire detector.

As described above, according to the present invention, it is possible to confirm whether the fire detector is operating normally without directly turning on the fire.

In particular, since each pattern is stored and the user selects one of the patterns corresponding to the cycle and the ON time of the optical signal (in particular, the IR signal) through the input unit, It is possible to test whether or not the fire detector of FIG.

1 is an example of a conventional fire detector,
2 is a functional block diagram of a virtual flame generating apparatus according to an embodiment of the present invention,
FIG. 3 is an external view of the virtual flame generating apparatus of FIG. 2,
4 is an example of a pattern of IR signals transmitted by the virtual spark generating device of FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, embodiments of the present invention will be described in order to facilitate understanding of the present invention, and the present invention is not limited to these embodiments. In particular, the present invention can be configured by combining at least any one of individual configurations and individual functions included in each embodiment.

A functional block of the virtual flame generating apparatus 100 according to an embodiment of the present invention is shown in FIG. 2, and an example of the appearance of such a virtual flame generating apparatus 100 is shown in FIG. The virtual flame generating apparatus 100 according to the present invention generates a virtual flame signal that the fire detector determines is a fire occurrence, and may be a kind of test apparatus for inspecting normal operation of the fire detector.

2, a virtual flame generating apparatus 100 according to an exemplary embodiment of the present invention includes a storage unit 110, a control unit 120, an optical signal generating unit 130, a first input unit 140, A second input unit 150, and a third input unit 160. [

The storage unit 110 stores pattern information, which is basic information for generating a virtual flame signal. For example, the pattern information stored in the storage unit 110 may correspond to a predetermined algorithm (that is, data constituting the algorithm), and may further include predetermined integer groups.

Also, at least one periodic pattern information related to the period and at least one on-time pattern information related to the on-time may be stored in the storage unit 110. The detailed description of the process using the information stored in the storage unit 110 Will be described later.

The IR (Infra-Red) generator generates the IR signal corresponding to the virtual flame control signal generated by the controller 120, to the external fire detector, as described later. The optical signal generating unit 130 may include an IR generating module 131 for generating infrared rays, that is, an infrared ray, and a UV generating module 132 for generating ultraviolet rays, that is, ultraviolet rays .

In this embodiment, the optical signal generator 130 corresponds to an IR laser module that emits infrared rays having a wavelength of, for example, 350 nm to 650 nm.

In FIG. 3, an IR laser transmission unit 116 is shown as an example of the optical signal generating unit 130.

The first input unit 140 is configured to allow a user to select a periodic pattern. The second input unit 150 is configured to allow a user to select an on-time pattern. And the second input unit 150 may be configured to sense the operation of the second input button 113 of FIG.

That is, the user can select a periodic pattern and an on-time pattern of the IR signal transmitted through the optical signal generator 130 through the operation of the first input unit 140 and the second input unit 150, A more detailed description of the processing results will be given later.

The user's selection through the first input unit may be displayed through the first display unit 114 and the user's selection through the second input unit may be displayed through the second display unit 115. [ Here, the first display unit 114 and the second display unit 115 may correspond to a 7-segment LED (Light Emitting Diode) in which a number corresponding to a pattern selected by the user is displayed.

The third input unit 160 is configured to allow the user to cause the control unit 120 to generate a virtual spark control signal and transmit the IR signal through the optical signal generation unit 130 as described later. And a third input button (111).

The control unit 120 generates a virtual flame control signal using the pattern information stored in the storage unit 110 and controls the optical signal generating unit 130 to transmit the IR signal corresponding to the generated flame control signal through the optical signal generating unit 130 . At this time, the control unit 120 may control the IR signal to be transmitted only while the user presses the third input button 111. [

In particular, the on-signal generated by the control unit 120 is an ON-OFF signal of the IR signal transmitted from the optical signal generating unit 130, (I.e., the IR signal transmission time) is 10 ms to 175 ms.

If the on-time of the IR signal is less than 10 ms, it is highly likely that the fire detector will consider it as noise and ignore it. If the on-time of the IR signal is greater than 175 ms, the fire detector will consider it as a no- , And the ON time of the IR signal transmitted by the optical signal generating unit 130 is preferably 10 ms to 175 ms.

As described above, when the storage unit 110 corresponds to the stored pattern information based on the set algorithm, the controller 120 repeatedly generates integers of a predetermined range in a random manner, and sequentially generates the generated integers It is possible to generate the applied virtual flame control signal.

For example, when the algorithm stored in the storage unit 110 is on time ms = (n-1) × 15 + 75 (Equation 1), the control unit 120 randomly selects natural numbers 4, 3, 6, and 2 are sequentially generated and substituted into the n value in Equation 1 in the order of generation, thereby generating 120 ms, 105 ms, 75 ms, 135 ms, 150 ms, and 90 ms, respectively, as the ON time.

Accordingly, the on-time of the IR signal transmitted through the optical signal generating unit 130 can be sequentially 120 ms, 105 ms, 75 ms, 135 ms, 150 ms, and 90 ms.

That is, the optical signal generating unit 130 transmits the first IR signal for 120 ms, the second IR signal for 105 ms, the third IR signal for 75 ms, the fourth IR signal for 135 ms , The fifth IR signal is transmitted for 150 ms, and the sixth IR signal is transmitted for 90 ms. At this time, the interval between the IR signals, that is, the Off time, may be changed according to the same or predetermined algorithm.

An example of an IR signal (laser signal) transmission pattern output by the optical signal generator 130 is shown in FIG. That is, referring to FIG. 4, it can be seen that the optical signal generator 130 transmits each IR signal for 120 ms, 105 ms, 75 ms, 135 ms, 150 ms, and 90 ms.

As another example, when a preset algorithm and a predetermined integer group are stored as the pattern information of the storage unit 110, the controller 120 may control the virtual flame control If all the integers included in the integer group are used, the order of the integers included in the integer group is changed to at least one of a random method and a preset method, and the sequence is sequentially To generate a virtual flame control signal.

For example, when {4, 3, 1, 5, 6, 2} is already stored in the storage unit 110, the control unit 120 applies the equation Time sequence corresponding to the flame control signal of the integer group is generated, and after all of them are applied, the integer arrangement order of the integer group is changed to {5, 1, 4, 6, 2, 3} , The virtual flame control signal can be generated by applying the equation (1) in the changed order.

The process of assigning such integer relocations and algorithms can be repeated for a predetermined time.

In addition, when at least one periodic pattern information related to the period and at least one on-time pattern information related to the on-time are stored in the storage unit 110, the control unit 120 controls the operation of the user through the first input unit 140 The virtual flame control signal may be generated based on the periodic pattern information corresponding to the selection and the on-time pattern information corresponding to the user's selection through the second input unit 150. [

For example, if the cyclic pattern information of 200 ms, 250 ms, and 300 ms is stored in the storage unit 110 and the ON-time pattern information of 120 ms, 75 ms, 135 ms, and 90 ms is stored, The controller 120 selects the first periodic pattern information of 200 ms through the second input unit 150 and selects 135 ms which is the third on-time pattern information through the second input unit 150. The control unit 120 determines that the on time is 135 ms and the off time is 65 ms ≪ RTI ID = 0.0 > IR < / RTI > signal.

This example is a case in which each pattern information is a single time information, and as another example, each pattern information may include a series of variations.

For example, the first on-time pattern information of the on-time pattern information may be 120ms, 105ms, 75ms, 135ms, 150ms, and 90ms, and the second on-time pattern information may be 110ms, 80ms, 115ms, 145ms, 150ms, The third on-time pattern information may be 75 ms, 110 ms, 135 ms, 95 ms, 140 ms, 100 ms. If the user selects the second on-time pattern information, The change in the time taken is 110 ms, 80 ms, 115 ms, 145 ms, 150 ms, and 85 ms to generate a virtual flame control signal for generating an IR signal.

Of course, each cycle pattern information selected by the user through the first input unit 140 may also include a series of cycles.

The present invention is not limited to the above-described specific embodiments, and various modifications and changes may be made without departing from the gist of the present invention.

Particularly, in the embodiment described above, the infrared ray is transmitted, but it is also possible to transmit ultraviolet rays instead of infrared rays, and to transmit infrared rays and ultraviolet rays at the same time.

It is to be understood that such variations and modifications are intended to be included in the scope of the appended claims.

100: a virtual flame generating apparatus 110:
120: control unit 130: IR generating unit
140: first input unit 150: second input unit
160: Third input section

Claims (5)

A storage unit;
A control unit for generating a virtual flame control signal using pattern information stored in the storage unit;
And an optical signal generator for emitting an optical signal corresponding to the virtual spark control signal generated by the controller toward an external fire detector. The method according to claim 1,
The virtual spark control signal generated by the controller is an on / off signal,
Wherein the ON signal generated by the controller is a signal for controlling the ON time of the optical signal transmitted from the optical signal generator to be 10 ms to 175 ms. The method according to claim 1,
The pattern information stored in the storage unit corresponds to a predetermined algorithm,
Wherein the control unit repeatedly generates an integer in a predetermined range in a random manner and generates a virtual spark control signal in which the generated integer is sequentially applied to the algorithm stored in the storage unit. The method according to claim 1,
The pattern information stored in the storage unit corresponds to a preset algorithm and a predetermined integer group,
Wherein the control unit generates a virtual flame control signal in which integers included in the integer group are sequentially applied to the algorithm stored in the storage unit, and when all the integers included in the integer group are used, Wherein the virtual flame control signal generating unit generates a virtual flame control signal that is sequentially applied to the stored algorithm in a changed order after changing the order of the flame control signal to at least one of a random method and a predetermined method. The method according to claim 1,
Further comprising a first input for selecting a periodic pattern and a second input for selecting an on-time pattern,
Wherein the storage unit stores at least one periodic pattern information related to the period and at least one on-time pattern information related to the on-time,
Wherein the control unit generates the virtual flame control signal on the basis of the cyclic pattern information corresponding to the user's selection through the first input unit and the on-time pattern information corresponding to the user's selection through the second input unit A device for generating a virtual flame.

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