Patent Publication Number: US-2023154302-A1

Title: Address-type fire detection device and address-type fire detection system comprising same

Description:
CROSS-REFERENCE TO PRIOR APPLICATIONS 
     This application is a National Stage Patent Application of PCT International Patent Application No. PCT/KR2021/004040 (filed on Apr. 1, 2021) under 35 U.S.C. § 371, which claims priority to Korean Patent Application No. 10-2020-0050459 (filed on Apr. 27, 2020), which are all hereby incorporated by reference in their entirety. 
    
    
     BACKGROUND 
     The disclosure relates generally to an address-type fire detection device and an address-type fire detection system including the same and, more particularly, to an address-type fire detection device and an address-type fire detection system including the same, capable of determining a location where fire has occurred using a first frequency to which a different frequency value is given for each address value assigned to a location where fire is to be detected. 
     People continue to make efforts in present as well as in the past to protect their lives and properties from fires. 
     Recently, with the social development and improvements in living standards, there are many large buildings having complex internal structures and partitioned internal structures so that many people may use different facilities. 
     When fire occurs in a large building, it is difficult to determine a location where fire has occurred due to a complex internal structure, thus frequently causing huge losses of both life and property. 
     Thus, when fire occurs in a building or a facility used by many people, it is necessary to determine the exact location of the fire, and technical development is in progress for this purpose. 
     As the prior art related to technology for detecting the location of fire, Korean Patent KR 10-1100255 entitled “User-oriented addressable P-type automatic fire detection system”, Korean Patent KR 10-1655827 entitled “Addressable repeater and addressable manual call point based on location confirmation”, etc. have been proposed. The prior art provides a technology in which an address signal of a location where the fire is detected is transmitted through communication when the fire is detected, and then a location where the fire occurs is detected. The prior art is a technology for detecting a location where fire occurs through communication, and is problematic in that a new communication facility for transmitting an address signal of a location where fire is detected through communication should be established in addition to a power line for supplying power to a fire detector, thus incurring high construction costs. 
     SUMMARY 
     The present disclosure has been made keep in mind the above problems occurring in the prior art, and an objective of the present disclosure is to provide an address-type fire detection device and an address-type fire detection system including the same, capable of determining a location where fire has occurred only with a power line without the necessity of providing a separate communication line or communication facility. 
     In an aspect, an address-type fire detection device is disclosed. The address-type fire detection device includes a fire detection sensor provided at a location where fire is to be detected, so as to detect fire, an operation signal generating unit for generating, when fire is detected through the fire detection sensor, an operation signal including a first pulse that has a first frequency corresponding to an address value assigned to the location where fire is to be detected, and an electrical signal generating unit for generating an electrical signal, including the first frequency, according to the control of the operation signal. 
     The operation signal generated by the operation signal generating unit may include a second pulse having a second frequency. In this case, the first frequency may have a value greater than the second frequency. The second pulse may have a first section and a second section. The first pulse may be applied in a pulse-burst to the first section. The electrical signal generating unit may generate the electrical signal including the first frequency by the first pulse applied to the first section. 
     For example, the operation signal generating unit may include an address setting part setting the address value assigned to the location where fire is to be detected, a calculation determining part calculating the first frequency corresponding to the address value and determining whether the operation signal is generated, after receiving the address value set by the address setting part and the fire signal detected through the fire detection sensor, and a pulse-burst signal generator generating the operation signal according to the control of the calculation determining part. The pulse-burst signal generator may generate the first pulse having the first frequency and the second pulse having the second frequency, and may generate the operation signal by applying the first pulse to the first section of the second pulse in the pulse-burst. 
     For example, the electrical signal generating unit may include a current source providing a current, and a switch connected to the current source to turn on or off the supply of the current that is provided by the current source. In this case, the operation signal may be applied as a switching signal of the switch. The electrical signal including the first frequency, which is generated by the electrical signal generating unit, may be reflected in the form of a change in a current value of the current provided by the current source. 
     The address-type fire detection device may further include a power line supplying power required for operating the electrical signal generating unit. In this case, the electrical signal including the first frequency, generated by the electrical signal generating unit, may be provided to the power line. 
     In another aspect, an address-type fire detection system is disclosed. The address-type fire detection system includes a plurality of address-type fire detection devices which are distributed according to a location where fire is to be detected, and to which different address values are assigned by distributed location, a power line connected to the plurality of address-type fire detection devices to supply power required for operation, and a receiving part connected to the power line to determine whether fire has broken out at each location where fire is to be detected. 
     Each of the plurality of address-type fire detection devices includes a fire detection sensor provided at a location where fire is to be detected to detect fire, an operation signal generating unit generating an operation signal including a first pulse having a first frequency that is a frequency corresponding to the address value assigned to the location where fire is to be detected if fire is detected by the fire detection sensor, and an electrical signal generating unit generating an electrical signal including the first frequency according to the control of the operation signal. In this case, the first frequency has different frequency values if the address values are different from each other. The electrical signal including the first frequency, generated by the electrical signal generating unit, is provided through the power line. 
     The operation signal generated by the operation signal generating unit may include a second pulse having a second frequency. In this case, the first frequency may have a value greater than the second frequency. The second pulse may have a first section and a second section. The first pulse may be applied in a pulse-burst to the first section. The electrical signal generating unit may generate the electrical signal including the first frequency by the first pulse applied to the first section. 
     For example, the operation signal generating unit may include an address setting part setting the address value assigned to the location where fire is to be detected, a calculation determining part calculating the first frequency corresponding to the address value and determining whether the operation signal is generated, after receiving the address value set by the address setting part and the fire signal detected through the fire detection sensor, and a pulse-burst signal generator generating the operation signal according to the control of the calculation determining part. The pulse-burst signal generator may generate the first pulse having the first frequency and the second pulse having the second frequency, and may generate the operation signal by applying the first pulse to the first section of the second pulse in the pulse-burst. 
     Meanwhile, the second frequency may have different frequency values if the address values are different from each other Further, the electrical signal including the first frequency, generated by the electrical signal generating unit, may include a current provided to the power line. The electrical signal generating unit of each of the plurality of address-type fire detection devices may be electrically connected in parallel to the power line. 
     The receiving part may include a voltage conversion part connected to the power line to convert the current flowing through the power line to voltage, and a fire determination part analyzing the frequency of the voltage converted by the voltage conversion part and then determining whether fire occurs for each location where fire is to be detected from the analyzed frequency of the voltage. 
     For example, the electrical signal generating unit may include a current source connected to the power line to provide a current to the power line, and a switch connected to the current source to turn on or off the supply of the current that is provided by the current source. In this case, the operation signal may be applied as a switching signal of the switch. The electrical signal including the first frequency, which is generated by the electrical signal generating unit, may be reflected in the form of a change in a current value of the current provided to the power line by the current source. 
     The present disclosure is advantageous in that an electrical signal including a first frequency is generated by controlling an electrical signal generating unit through an operation signal that is generated by an operation signal generating unit and includes a first pulse having the first frequency that is a frequency corresponding to an address value, thus facilitating an operation only by a power line. 
     Further, the present disclosure is advantageous in that it is possible to check whether fire has occurred for each location where fire is to be detected only by analyzing a frequency at a receiving end using a first frequency having a different frequency value for each address value. 
     Further, the present disclosure is advantageous in that it is possible to check whether fire has occurred for each location where fire is to be detected only by analyzing a frequency even if fires have simultaneously occurred at a plurality of locations where fire is to be detected, through an operation signal including a second frequency having a different frequency value for each address value. 
     The foregoing provides only optional concepts in a simplified form for matters that are to be described in more detail later. It is not intended to limit key features or essential features of the claims, or to limit the scope of the claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG.  1    is a diagram illustrating an example of an address-type fire detection device according to an embodiment of the present disclosure. 
         FIG.  2    is a diagram illustrating another example of an address-type fire detection device according to an embodiment of the present disclosure. 
         FIG.  3    is a diagram illustrating a further example of an address-type fire detection device according to an embodiment of the present disclosure. 
         FIGS.  4  to  7    are diagrams illustrating various examples of operation signals generated by an operation signal generating unit according to the present disclosure. 
         FIGS.  8  to  10    are diagrams illustrating various examples of electrical signals generated by an electrical signal generating unit of the address-type fire detection device according to the present disclosure. 
         FIG.  11    is a diagram illustrating an example of an address-type fire detection system according to another embodiment of the present disclosure. 
         FIG.  12    is a diagram illustrating an example of a receiving end according to the present disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     Hereinafter, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. Unless otherwise specified in the text, like reference numbers in the drawings indicate like components. The exemplary embodiments described above in the detailed description, drawings, and claims are not for limitation, other embodiments may be used, and other changes are possible without departing from the spirit or scope of the technology disclosed herein. It is apparent to those skilled in the art that components of the present disclosure, i.e., components generally described and illustrated in the drawings are arranged, configured, coupled, and designed in various different configurations, and form a part of the present disclosure. In the drawings, in order to clearly express various layers (or films), areas and shapes, the width, length, thickness, or shape of the component may be exaggerated. 
     It will be understood that when a component is referred to as being “arranged” on another component, it can be directly arranged on the other component or intervening components may be present therebetween. 
     It will be understood that when a component is referred to as being “provided” on another component, it can be directly provided on the other component or intervening components may be present therebetween. 
     Structural or functional descriptions in the embodiments of the present disclosure are only for description of the embodiments of the present disclosure. The descriptions should not be construed as being limited to the embodiments described in the specification or application. The present disclosure may, however, be embodied in many different forms and should not be construed as being limited to only the embodiments set forth herein, but should be construed as covering modifications, equivalents or alternatives falling within ideas and technical scopes of the present disclosure. 
     The singular forms are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprise”, “include”, “have”, etc. when used in this specification, specify the presence of stated features, integers, steps, operations, elements, components, and/or combinations thereof but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or combinations thereof. 
     Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present disclosure belongs. It will be further understood that terms used herein should be interpreted as having a meaning that is consistent with their meaning in the context of this specification and the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein. 
       FIG.  1    is a diagram illustrating an example of an address-type fire detection device according to an embodiment of the present disclosure.  FIG.  2    is a diagram illustrating another example of an address-type fire detection device according to an embodiment of the present disclosure.  FIG.  3    is a diagram illustrating a further example of an address-type fire detection device according to an embodiment of the present disclosure. 
       FIGS.  4  to  7    are diagrams illustrating various examples of operation signals generated by an operation signal generating unit according to the present disclosure.  FIGS.  4  to  6    are diagrams illustrating a first pulse  11  applied in a pulse-burst to a first section  12   a  of a second pulse  12 . Further,  FIGS.  4  to  6    are diagrams illustrating first frequencies of the first pulses  11  having different frequency values according to address values assigned to fire detecting locations where a fire detection sensor of the address-type fire detection device is provided.  FIG.  4    is a diagram illustrating second pulses  12  in which frequency values of second frequencies are the same as each other regardless of the address values, and  FIG.  4    illustrates a case where the time intervals of the first sections  12   a  and the time intervals of the second sections  12   b  are the same as each other regardless of the address values.  FIG.  5    is a diagram illustrating second pulses  12  in which frequency values of second frequencies are different from each other according to the address values, and  FIG.  5    illustrates a case where the time intervals of the first sections  12   a  are the same as each other regardless of the address values.  FIG.  6    is a diagram illustrating second pulses  12  in which frequency values of second frequencies are different from each other according to the address values, and  FIG.  6    illustrates a case where the time intervals of the second sections  12   b  are the same as each other regardless of the address values.  FIG.  7 ( a )  is a diagram in which no startup section  12   c  is shown, and  FIG.  7 ( b )  is a diagram in which the startup section  12   c  is included in the first section  12   a.    
       FIGS.  8  to  10    are diagrams illustrating various examples of electrical signals generated by an electrical signal generating unit of the address-type fire detection device according to the present disclosure.  FIGS.  8  to  10    are diagrams illustrating the electrical signals including the first frequencies generated by the electrical signal generating unit according to the control of the operation signals of  FIGS.  4  to  6   , respectively. 
       FIG.  11    is a diagram illustrating an example of an address-type fire detection system according to another embodiment of the present disclosure.  FIG.  12    is a diagram illustrating an example of a receiving end according to the present disclosure. 
     Hereinafter, the address-type fire detection device and the address-type fire detection system including the device according to the present disclosure will be described with reference to the drawings. 
     Referring to  FIGS.  1  to  3   , the address-type fire detection device  100 ,  100   a , or  100   b  includes a fire detection sensor  110 , an operation signal generating unit  120 ,  120   a , or  120   b , and an electrical signal generating unit  130 . In some other embodiments, the address-type fire detection device  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n , or  100   a  may optionally include a power line  140 . The address-type fire detection device  100 ,  100   a , or  100   b  may include an LED that notifies a user that fire has occurred with light. The user may visually check whether fire has occurred at the location where fire is to be detected through the LED. In addition, the address-type fire detection device  100 ,  100   a , or  100   b  may include an alarm unit (not shown), and may acoustically notify the user that fire has occurred at the location where fire is to be detected through the alarm unit. 
     The fire detection sensor  110  is provided at the location where fire is to be detected to detect fire. As the fire detection sensor  110 , a temperature sensor, a thermal imaging camera, a gas sensor, etc. may be used. However, the type of the sensor is not limited thereto, as long as it may detect fire. 
     The operation signal generating unit  120 ,  120   a , or  120   b  generates an operation signal  10  including the first pulse  11  having the first frequency that is a frequency corresponding to the address value assigned to the location where fire is to be detected if fire is detected through the fire detection sensor  110 . The first frequency may have a different value if the address value is changed. Meanwhile,  FIGS.  4  to  6    illustrate examples of operation signals  10  generated by address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number) to correspond to different address values assigned to locations where fire is to be detected. The frequency value of the first frequency of the first pulse  11  included in the operation signal  10  may have a different value if the address value is changed.  FIGS.  4  to  6    illustrate examples of operation signals  10  having different frequency values  1 /T 11 ,  1 /T 12 ,  1 /T 13 , and  1 /T 1   n  according to different address values. T 11 , T 12 , T 13 , and T 1   n  shown in  FIGS.  4  to  6    are period values of the first pulses  11  generated by the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number), respectively. 
     The electrical signal generating unit  130  generates an electrical signal including the first frequency according to the control of the operation signal  10 . 
     For example, the operation signal  10  generated by the operation signal generating unit  120 ,  120   a , or  120   b  may include a second pulse  12  having a second frequency.  FIG.  4    illustrates as an example the second frequency  1 /T 2  generated in the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  (n is a natural number).  FIG.  4    illustrates as an example the second pulse  12  having the second frequency having the same frequency value regardless of the address value. T 2  shown in  FIG.  4    is a period value of the second pulse  12 . Meanwhile, the second frequency may have a different value if the address value is changed.  FIG.  5    illustrates as an example the operation signals  10  having second frequencies  1 /T 21 ,  1 /T 22 ,  1 /T 23 , and  1 /T 2   n  having different frequency values generated in the respective address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number) to correspond to different address values. T 21 , T 22 , T 23 , and T 2   n  shown in  FIG.  5    are period values of the second pulse  12  generated in the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number). Further,  FIG.  6    illustrates as an example the operation signals  10  having second frequencies  1 /T 21 ′,  1 /T 22 ′,  1 /T 23 ′, and  1 /T 2   n ′ having different frequency values generated in the respective address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number) to correspond to different address values. T 21 ′, T 22 ′, T 23 ′, and T 2   n ′ shown in  FIG.  6    are period values of the second pulse  12  generated in the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number). 
     In summary, the operation signal  10  generated by the operation signal generating unit  120 ,  120   a , or  120   b  may include a first pulse  11  and a second pulse  12 . In this case, the first frequency may have a greater value than the second frequency. The second pulse  12  may have a first section  12   a  and a second section  12   b . The first pulse  11  may be applied to the first section  12   a  in the pulse-burst. The electrical signal generating unit  130  may generate the electrical signal including the first frequency by the first pulse  11  applied to the first section  12   a.    
       FIGS.  4  to  6    show as an example a PWM (Pulse Width Modulation) signal having a preset duty for each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number) corresponding to different address values as the second pulse  12 . In this case, a section corresponding to a High state of the PWM signal may be the first section  12   a , while a section corresponding to a Low state may be the second section  12   b . The first section  12   a  may be an operation section of the electrical signal generating unit  130  in which the electrical signal generating unit  130  generates an electrical signal, and the second section  12   b  may be a rest section of the electrical signal generating unit  130  in which the electrical signal generating unit  130  generates no electrical signal. As illustrated in  FIGS.  4  to  6   , the first pulse  11  may be applied in the pulse-burst to the first section  12   a  that is a section corresponding to the High state of the PWM signal. By applying the first pulse  11  to the first section  12   a  of the second pulse  12  that is the operation section of the electrical signal generating unit  130  in the pulse-burst, the electrical signal generating unit  130  may generate the electrical signal including the first frequency according to the control of the first pulse  11  of the operation signal  10 . 
       FIG.  4    shows as an example a PWM signal having the same duty regardless of the address value as the second pulse  12 .  FIGS.  5  and  6    show as an example PWM signals having different duties according to the address value as the second pulse  12 . Meanwhile,  FIG.  5    shows as an example the PWM signal in which the time interval of the first section  12   a  is the same regardless of the address value.  FIG.  6    shows as an example a case in which the time interval of the second section  12   b  is the same regardless of the address value. The above example is an example for the purpose of understanding, and the form of the operation signal  10  is not limited as long as the electrical signal including the first frequency may be generated by controlling the electrical signal generating unit  130 . Meanwhile, as illustrated in  FIG.  6   , the number of waves of the first pulse  11  located in the first section  12   a  may be equally assigned to each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number). When the time interval of the second section  12   b  is the same regardless of the address value and a predetermined number of waveforms of the first pulse  11  enters the first section  12   a  for each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number), the duty of the second pulse  120  may be changed for each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  (n is a natural number). 
     As long as a voltage signal may be used as the operation signal  10  but the first frequency may be transmitted to the electrical signal generating unit  130  and the electrical signal generating unit  130  may generate the electrical signal including the first frequency, the operation signal  10  may be a different type of signal such as a current. 
     For instance, as illustrated in  FIG.  1   , the operation signal generating unit  120  may include an address setting part  121 , a turn on signal generator  122 , a first frequency generator  123 , a base operation signal generator  124 , and a logic and gate  125 . 
     The address setting part  121  may set the address value assigned to the location where fire is to be detected. Although the drawing illustrates the address value having 6-bit codes (ID_0 to ID_5), the present disclosure is not limited thereto. 
     If fire is detected through the fire detection sensor  110 , the turn on signal generator  122  may generate a turn on signal  20  that may operate the electrical signal generating unit  130  as illustrated in  FIG.  7   . 
     The first frequency generator  123  may assign the first frequency corresponding to the address value assigned to the location where fire is to be detected. 
     The base operation signal generator  124  may generate the first pulse  11  having the first frequency and the second pulse  12  having the second frequency, and may generate a base operation signal  10   a  by applying the first pulse  11  to the first section  12   a  of the second pulse  12  in the pulse-burst.  FIG.  7    illustrates the base operation signal  10   a  as an example. Meanwhile, the base operation signal  10   a  may be generated through the base operation signal generator  124  when fire is detected through the fire detection sensor  110  or when a turn on signal is generated, or may be continuously generated through the base operation signal generator  124  in a preset manner regardless of whether the fire is detected through the fire detection sensor  110 . 
     As illustrated in  FIG.  7   , the logic and gate  125  may combine the turn on signal  20  and the base operation signal  10   a  by and logic to generate the operation signal  10 . Since the logic and gate  125  combines the turn on signal  20  and the base operation signal  10   a  by and logic to generate the operation signal  10 , the electrical signal generating unit  130  may not generate the electrical signal before fire is sensed through the fire detection sensor  110 . When the fire is detected through the fire detection sensor  110 , the electrical signal generating unit  130  may generate the electrical signal including the first frequency according to the control of the first pulse  11 . 
     As another example, as illustrated in  FIG.  2   , the operation signal generating unit  120   a  may include an address setting part  121 , a turn on signal generator  122 , a first pulse generator, a second pulse generator, and a logic and gate  125 . 
     The address setting part  121  may set the address value assigned to the location where fire is to be detected. Although the drawing illustrates the address value having 6-bit codes (ID_0 to ID_5), the present disclosure is not limited thereto. 
     If fire is detected through the fire detection sensor  110 , the turn on signal generator  122  may generate a turn on signal  20  that may operate the electrical signal generating unit  130  as illustrated in  FIG.  7   . 
     The first pulse generator may generate a first pulse  11  including a first frequency corresponding to the address value assigned to the location where fire is to be detected. 
     The second pulse generator has a second frequency, and may generate a second pulse  12  having a first section  12   a  and a second section  12   b.    
     Meanwhile, the first pulse  11  and the second pulse  12  may be generated through the first pulse generator and the second pulse generator when fire is detected through the fire detection sensor  110  or the turn on signal is generated, and may be continuously generated through the first pulse generator and the second pulse generator in a preset manner regardless of whether the fire is detected through the fire detection sensor  110 . 
     The logic and gate  125  may combine the turn on signal  20 , the first pulse  11 , and the second pulse  12  by and logic to generate the operation signal  10 . Since the logic and gate  125  combines the turn on signal  20 , the first pulse  11 , and the second pulse  12  by and logic to generate the operation signal  10 , the electrical signal generating unit  130  may not generate the electrical signal before fire is sensed through the fire detection sensor  110 . When the fire is detected through the fire detection sensor  110 , the electrical signal generating unit  130  may generate the electrical signal including the first frequency according to the control of the first pulse  11 . 
     Meanwhile, as described above, the second pulse  12  may be a PWM (Pulse Width Modulation) signal having a preset duty. In this case, a section corresponding to the High state of the PWM signal may be the first section  12   a , while a section corresponding to the Low state may be the second section  12   b . The first section  12   a  may be an operation section of the electrical signal generating unit  130  in which the electrical signal generating unit  130  generates an electrical signal, and the second section  12   b  may be a rest section of the electrical signal generating unit  130  in which the electrical signal generating unit  130  generates no electrical signal. The first pulse  11  may be applied in the pulse-burst to the first section  12   a  that is a section corresponding to the High state of the PWM signal by combining the first pulse  11  and the second pulse  12  through and logic. By applying the first pulse  11  to the first section  12   a  of the second pulse  12  that is the operation section of the electrical signal generating unit  130  in the pulse-burst, the electrical signal generating unit  130  may generate the electrical signal including the first frequency according to the control of the first pulse  11  of the operation signal  10 . 
     As another example, as illustrated in  FIG.  3   , the operation signal generating unit  120   b  may include an address setting part  121 , a calculation determining part  126 , and a pulse-burst signal generator  127 . In some other embodiments, the operation signal generating unit  120   b  may optionally include an LED controller  128 . 
     The address setting part  121  may set an address value assigned to the location where fire is to be detected. Although the drawing illustrates the address value having 6-bit codes (ID_0 to ID_5), the present disclosure is not limited thereto. 
     The calculation determining part  126  may calculate the first frequency corresponding to the address value and determine whether the operation signal is generated, after receiving the address value set by the address setting part  121  and the fire signal detected through the fire detection sensor  110 .  FIG.  3    illustrates a calculation determining part  126  including an address-value sensing part  126   a , a fire-signal sensing part  126   b , and a controller  126   c . The address-value sensing part  126   a  may detect an address value that is set by the address setting part  121 , and the fire-signal sensing part  126   b  may receive a fire signal through the fire detection sensor  110 . The controller  126   c  may calculate the first frequency of the first pulse  11 , the second frequency of the second pulse  12 , and the duty of the second pulse  12  based on the address value received from the address-value sensing part  126   a  and the fire signal detected by the fire-signal sensing part  126   b . The controller  126   c  may control the pulse-burst signal generator  127  according to the calculated result. Further, the controller  126   c  may control the LED controller  128  according to the calculated result. 
     The pulse-burst signal generator  127  may generate the operation signal  10  according to the control of the calculation determining part  126 . The pulse-burst signal generator  127  may generate the first pulse  11  having the first frequency and the second pulse  12  having the second frequency, and may generate the operation signal  10  by applying the first pulse  11  to the first section  12   a  of the second pulse  12  in the pulse-burst. Since the operation signal  10  is provided such that the first pulse  11  having the first frequency is applied to the first section  12   a  of the second pulse  12  having the second frequency in the pulse-burst, the operation signal  10  may be referred to as a CFB (Coded Freq. Burst) Signal in the present disclosure. 
     Meanwhile, if fire is detected by the fire detection sensor  110 , the calculation determining part  126  may turn on/off a POWER FET, which is an example of a switch  132 , with the burst signal of a preset channel frequency corresponding to the address value of the address setting part  121 , that is, the first frequency of the first pulse  11  to control a constant current and operate an LED. The LED may remain in its state even when the address-type fire detection device  100   b  returns to its normal state. The reset of the LED may be cleared by turning the power off/on or with a reset button. That is, the LED causes an operator to visit a place where fire is detected and directly turn off the LED, thus causing the operator to directly check a location where fire is to be detected where the fire has occurred without relying on a system, and thereby forcing the operator to check whether the fire has actually occurred. Further, when the device and the system disclosed in the present disclosure malfunction, the LED may provide the function of allowing the operator to easily find the malfunctioning address-type fire detection device. 
     Further, as illustrated in  FIG.  7 ( b ) , the operation signal  10  generated by the operation signal generating unit  120  or  120   a  may include a startup section  12   c  for the stable operation or initial operation of the electrical signal generating unit  130 . 
     As illustrated in  FIGS.  1  to  3   , the electrical signal generating unit  130  may include a current source  131  that provides current, and a switch  132  that is connected to the current source  131  to turn on or off the supply of current that is provided by the current source  131 . In this case, the operation signal  10  including the first pulse  11  having the first frequency may be applied as the switching signal of the switch  132 . The electrical signal including the first frequency, which is generated by the electrical signal generating unit  130 , may be reflected in the form of a change in a current value of the current provided by the current source  131 . 
     A constant current source may be used as an example of the current source  131 , but the present disclosure is not limited thereto. A power FET or a power FET having the gate signal or the base signal as the operation signal  10  may be used as the switch  132 , but the present disclosure is not limited thereto. 
     Meanwhile, as illustrated in  FIGS.  1  to  3   , it is assumed that the current source  131  providing current and the switch  132  connected to the current source  131  and turning on and off the supply of the current provided by the current source  131  are utilized as the electrical signal generating unit  130 . 
     Each of the signals shown in  FIGS.  4  to  6    may be applied as the operation signal  10  to the electrical signal generating unit  130  of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n . In this case, the applied operation signal  10  may be a voltage signal that turns on or off the switch  132  of the electrical signal generating unit  130  as an example. If each of the signals shown in  FIGS.  4  to  6    may be applied as the operation signal  10  to the switch  132  of the electrical signal generating unit  130  of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n , the electrical signal generating unit  130  of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  may generate the current signal shown in  FIGS.  8  to  10    as the electrical signal. In  FIGS.  8  to  10   , Isb is a standby current flowing through the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  in a standby state where VCC power is supplied, and I 1 , I 2 , I 3 , and In denote currents flowing through the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n , respectively, when fire is detected in the event of fire. 
     That is, since the switch  132  is controlled according to the first frequency of the operation signal  10  if the operation signal  10  including the first pulse  11  having the first frequency is applied to the switching signal of the switch  132 , the current provided from the current source  131  is also controlled according to the first frequency of the operation signal  10 . The electrical signal including the first frequency, generated by the electrical signal generating unit  130 , may be reflected in the form of a change in the current value of the current provided by the current source  131 . Thereby, the electrical signal generating unit  130  may generate the electrical signal including the first frequency according to the control of the operation signal  10  including the first pulse  11  having the first frequency. 
     The power line  140  may supply power required for operating the electrical signal generating unit  130 . In this case, the electrical signal including the first frequency, generated by the electrical signal generating unit  130 , may be provided to the power line  140 . Thereby, the address-type fire detection device  100  according to the present disclosure controls the electrical signal generating unit  130  through the operation signal  10  that is generated by the operation signal generating unit  120  and includes the first pulse  11  having the first frequency that is a frequency corresponding to the address value, thus generating the electrical signal including the first frequency, and supplying the generated electrical signal through the power line  140  to the outside, and thereby detecting a location where fire has occurred only with the power line  140  without the necessity of providing a separate communication line or communication equipment. 
     The power required for operating the fire detection sensor  110  and the operation signal generating unit  120 ,  120   a , or  120   b  may also be supplied through the power line  140 . 
     Referring to  FIG.  11   , the address-type fire detection system  200  includes a plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n , a power line  140 , and a receiving part  210 . 
     The plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  are distributed and provided for the locations where fire is to be detected, respectively, and a different address value is assigned to each distributed location. 
     The power line  140  is connected to the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  to supply power required for the operation. That is, the power line  140  is connected to a plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n , especially, the electrical signal generating unit  130  to supply power required for the operation of the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n , especially the electrical signal generating unit  130 . 
     The receiving part  210  is connected to the power line  140  to determine whether fire occurs for each location where fire is to be detected. 
     Each of the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  includes a fire detection sensor  110  that is provided on the location where fire is to be detected, so as to detect fire, an operation signal generating unit  120 ,  120   a , or  120   b  that generates the operation signal  10  including the first pulse  11  having the first frequency that is the frequency corresponding to the address value assigned to the location where fire is to be detected if fire is detected by the fire detection sensor  110 , and an electrical signal generating unit  130  that generates an electrical signal including the first frequency according to the control of the operation signal  10 . In this case, the first frequency has different frequency values if the address values are different from each other, and the electrical signal including the first frequency, generated by the electrical signal generating unit  130 , is provided through the power line  140 . 
     Since the address-type fire detection devices  100 ,  100   a , and  100   b  described above with reference to  FIGS.  1  to  10    may be applied to the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  and are substantially equal to each other, a detailed description thereof will be omitted for the convenience of description. 
     That is, contents common to both the address-type fire detection system  200  and the above address-type fire detection devices  100 ,  100   a , and  100   b  will be omitted for the convenience of description in the detailed description of the address-type fire detection system. Hereinafter, the characteristic operation and configuration of the address-type fire detection system  200  will be mainly described. 
     For example, the electrical signal including the first frequency, generated by the electrical signal generating unit  130 , may include a current provided to the power line  140 . As illustrated in  FIG.  11   , the electrical signal generating unit  130  of each of the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may be electrically connected in parallel to the power line  140 . 
     In this case, the receiving part  210  may include a voltage conversion part  211  that is connected to the power line  140  to convert current flowing through the power line  140  to voltage, and a fire determination part  212  that analyzes the frequency of the voltage converted by the voltage conversion part  211  and then determines whether fire occurs for each location where fire is to be detected from the analyzed frequency of the voltage. 
       FIGS.  11  and  12    show an example of the receiving part  210 . Referring to  FIGS.  11  and  12   , the receiving part  210  may include a current sensing resistor as an example of the voltage conversion part  211 . Further, the receiving part  210  may include a first amplifier AMP 1 , a differential amplifier, a second amplifier AMP 2 , a level translator, and a micro control unit MCU as an example of the fire determination part  212 . Further, the receiving part  210  may include a display that shows the determination result of the fire determination part  212 . 
     Hereinafter, the operation of the address-type fire detection system  200  according to the present disclosure will be described with reference to  FIGS.  11  and  12   . 
     If fire is detected by the fire detection sensor  110  of any one of the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  provided in the locations where fire is to be detected, the operation signal generating unit  120 ,  120   a , or  120   b  of the address-type fire detection device detecting fire (hereinafter referred to as a fire-site detection device) generates the operation signal  10  including the first pulse  11  having the first frequency (hereinafter referred to as a fire-site first frequency) that is a frequency corresponding to the address value that is assigned to the location where fire is to be detected. The operation signal  10  generated by the operation signal generating unit  120 ,  120   a , or  120   b  of the fire-site detection device controls the electrical signal generating unit  130  of the fire-site detection device, generates current including the fire-site first frequency as the electrical signal, and then provides it through the power line  140 . 
     As illustrated in  FIG.  12   , the current including the fire-site first frequency, which is provided through the power line  140 , is provided to the current sensing resistor  211 , so that voltage is generated at both ends of the current sensing resistor  211 . At this time, since the voltage generated at both ends of the current sensing resistor  211  is attributable to the current including the fire-site first frequency, which is provided through the power line  140 , the voltage includes the fire-site first frequency. The voltage generated at both ends of the current sensing resistor  211  is amplified (Vx) by the first amplifier AMP 1  to be provided to the second amplifier AMP 2 . 
       FIG.  12    shows Vx in a standby state (STAND-BY) before fire occurs and Vx in a fire-on state (FIRE_ON). As described above, Vx in the fire-on state (FIRE_ON) includes the fire-site first frequency. 
     Vx obtained via the first amplifier AMP 1  is provided to the second amplifier AMP 2 . The second amplifier AMP 2  may include a voltage divider &amp; auto-biasing circuit, a voltage divider, and a comparator. Vx passing through the second amplifier AMP 2  is converted into Vy from which the effect of Isb (see  FIGS.  8  to  10   ) that is the current of the standby state is removed. Vy may be translated into a voltage level required by the micro control unit (MCU) through the level translator. The voltage level required by the micro control unit (MCU) may be the CFB (Coded Freq. Burst) signal that is the operation signal  10 . The micro control unit (MCU) may extract the first frequency from Vy passing through the level translator. The present disclosure proposes technology in which the address value may be found from the extracted first frequency, so that the fire occurrence may be checked for each location where fire is to be detected. 
     The foregoing is only one example. The electrical signal generating unit  130  of the plurality of address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may generate the voltage signal as the electrical signal including the first frequency, and the receiving part  210  may directly convert the voltage signal into the current signal, extract the first frequency, and check fire occurrence for each location where fire is to be detected. 
     Hereinafter, the operation of the address-type fire detection device  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n ,  100   a , or  100   b  and the address-type fire detection system  200  according to the present disclosure will be described in brief with reference to the drawing. 
     The address-type fire detection devices  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n ,  100   a , and  100   b  according to the present disclosure assign different address values to the locations where fire is to be detected, so as to detect fire. When fire is detected through the address-type fire detection devices  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n ,  100   a , and  100   b  to which different address values are given, the address-type fire detection device  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n ,  100   a , or  100   b  generates the electrical signal having the first frequency. In this case, the first frequency has different frequency values when the address values are different. The electrical signal including the first frequency, which is generated by the address-type fire detection device  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n ,  100   a , or  100   b , may be supplied through the power line  140  to the receiving part  210 . Thereby, the receiving part  210  may check whether fire occurs for each location where fire is to be detected by extracting and analyzing the first frequency of the electrical signal supplied by the address-type fire detection device  100 ,  100 - 1 ,  100 - 2 ,  100 - 3 ,  100 - n ,  100   a , or  100   b.    
     Meanwhile, fires may simultaneously occur in several places among the locations where fire is to be detected. In this case, as illustrated in  FIG.  8   , the electrical signal including the first frequency having a different frequency value supplied by the electrical signal generating unit  130  of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  detecting the fire may be supplied to the receiving part  210 . In this case, it is possible to check whether fire occurs for each location where fire is to be detected by extracting and analyzing the frequency value of the first frequency of the electrical signal supplied by the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  through frequency filtering. 
     Furthermore, as illustrated in  FIG.  5   , the second frequencies  1 /T 21 ,  1 /T 22 ,  1 /T 23 , and  1 /T 2   n  of the operation signal  10  of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may be provided to have different frequency values when the address values are different from each other. Fires may simultaneously occur in several places among the locations where fire is to be detected. In this case, as illustrated in  FIG.  9   , the electrical signal including the first frequency and the second frequency having different frequency values, supplied by the electrical signal generating unit  130  of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  detecting the fire, may be supplied to the receiving part  210 . In this case, as soon as the first frequency of the electrical signal supplied by the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  reaches the receiving part  210 , it may be immediately analyzed. Alternatively, when the first frequency of the electrical signal supplied by the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  reaches the receiving part  210 , it may not be immediately analyzed, but extraction and analysis may be performed after a predetermined period of time has elapsed. Thus, the electrical signals provided by the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may be separated from each other without frequency filtering, and then the first frequencies of the electrical signals may be extracted and analyzed, so that it is possible to check whether fire has occurred for each location where fire is to be detected. This is based on a reason that the frequency values of the second frequency are provided to have different values when the address values are different from each other. Specifically, when fires simultaneously occur in several places among the locations where fire is to be detected, the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  detecting the fires may supply the electrical signal through the power line  140  to the receiving part  210 . At first, all of the first pulses  11 ′ having the first frequency among the electrical signals arriving at the receiving part  210  may reach at the same time. However, since the frequency values of the second frequency of the electrical signals supplied by the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  are different from each other, the first pulses  11 ′ having the first frequency among the electrical signals supplied by the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  arrive at the receiving part  210  at different times as time passes. Thereby, it is possible to check whether fire has occurred for each location where fire is to be detected, by extracting and analyzing the first frequency of the electrical signal that is supplied by each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  without frequency filtering. 
     Further, as illustrated in  FIG.  6   , the second frequencies  1 /T 21 ′,  1 /T 22 ′,  1 /T 23 ′, and  1 /T 2   n ′ of the operation signal  10  of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may be provided to have different frequency values when the address values are different from each other. Fires may simultaneously occur in several places among the locations where fire is to be detected. In this case, as illustrated in  FIG.  10   , the electrical signal including the first frequency and the second frequency having different frequency values, supplied by the electrical signal generating unit  130  of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  detecting the fire, may be supplied to the receiving part  210 . In this case, as soon as the first frequency of the electrical signal supplied by the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  reaches the receiving part  210 , it may be immediately analyzed. Alternatively, when the first frequency of the electrical signal supplied by the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  reaches the receiving part  210 , it may not be immediately analyzed, but extraction and analysis may be performed after a predetermined period of time has elapsed. Thus, the electrical signals provided by the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may be separated from each other without frequency filtering, and then the first frequencies of the electrical signals may be extracted and analyzed, so that it is possible to check whether fire has occurred for each location where fire is to be detected. Since a detailed description thereof is the same as the detailed description of  FIGS.  5  and  9   , it will be omitted for the convenience of explanation. 
     As described above, the present disclosure is advantageous in that an electrical signal including a first frequency is generated by controlling an electrical signal generating unit through an operation signal that is generated by an operation signal generating unit and includes a first pulse having the first frequency that is a frequency corresponding to an address value, thus facilitating an operation only by a power line. 
     Further, the present disclosure is advantageous in that it is possible to check whether fire has occurred for each location where fire is to be detected only by analyzing a frequency at a receiving end using a first frequency having a different frequency value for each address value. 
     Further, the present disclosure is advantageous in that it is possible to check whether fire has occurred for each location where fire is to be detected only by analyzing a frequency even if fires have simultaneously occurred at a plurality of locations where fire is to be detected, through an operation signal including a second frequency having a different frequency value for each address value. 
     In other words, according to the present disclosure, the address is assigned with the frequency, i.e., the first frequency to each address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n , and the electrical signal generated by each address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n  is transmitted through the power line  140  to the receiving part  210 , so that a signal resistant to noise can be transmitted to the receiving part  210  and this can be easily detected by the receiving part  210 . Further, according to the present disclosure, the length of the first section  12   a  of the second pulse  12  is set to be shorter than that of the second section  12   b , and the signal of the first pulse  11  of a specific frequency, i.e., the first frequency is sent in the pulse-burst manner only for a very short time compared to a period, i.e. a period of the second frequency, thus providing characteristics that facilitate multi-channel detection. In addition, if the period of the second frequency is changed in conjunction with the first frequency of each address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , or  100 - n , the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  are simultaneously turned on, so that the first pulses  11 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  which reach the receiving part  210  at first may overlap each other. Even in this case, the first pulses  11 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  which reach the receiving part  210  are separated from each other after a certain cycle of the second frequency (within 2 to 3 cycles). Thereby, according to the present disclosure, even if fires occur simultaneously, the first pulses  11 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  can be easily detected by the receiving part  210 . 
     The period of the second pulse  12 ′ of the electrical signal of each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  provided to the receiving part  210  may be changed depending on the number of the first pulse  11 ′ of the electrical signal of each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  detected by the receiving part  210 . The period of the second pulse  12 ′ of the electrical signal of each of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  and the number of the first pulses  11 ′ may be adjusted by adjusting the period of the second pulse  12  of the operation signal  10  of each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  and the number of the first pulses  11 . 
     For instance, as shown in  FIGS.  6  and  10   , the first pulse  11  of the operation signal  10  of each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  and the first pulse  11 ′ of the electrical signal depending on the first pulse  11  of the operation signal  10  have a predetermined number of pulses. The drawing illustrates the first pulses  11  of ten operation signals  10  and the first pulse  11 ′ of the electrical signal. The second sections  12   b  of the second pulses  12 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  are set to be the same as each other, and the same number of the first pulses  11 ′ of the electrical signal is applied in the pulse-burst to the first sections  12   a  of the second pulses  12 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n , so that the periods of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  may become different from each other. 
     Meanwhile, the period of the second pulse  12 ′ of the electrical signal of each of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  detected by the receiving part  210  and the number of the first pulses  11 ′ have a trade-off relationship in determining the accuracy, detection time, and number of multiple detections of the address-type fire detection system  200  according to the present disclosure. That is, as the number of the first pulses  11 ′ of the electrical signal detected by the receiving part  210  increases, the accuracy of the address-type fire detection system  200  according to the present disclosure increases. On the other hand, when the second sections  12   b  of the second pulses  12 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  are set to be the same as each other, the period of the electrical signal of each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  becomes longer as the number of the first pulses  11 ′ of the electrical signal detected by the receiving part  210  increases. Thus, in the event of simultaneous fires, when the first pulses  11 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  which reach the receiving part  210  are separated from each other after a certain cycle of the second frequency of each of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  has passed, the separation time for separating the first pulses  11 ′ of the electrical signals of the address-type fire detection devices  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n , that is, the detection time becomes longer. Since the detection time increases as the number of multiple detections increases, the period of the second pulse  12 ′ of the electrical signal of each of the address-type fire detection device  100 - 1 ,  100 - 2 ,  100 - 3 , and  100 - n  detected by the receiving part  210  and the number of the first pulses  11 ′ need to be determined in consideration of the accuracy, detection time, and number of multiple detections of the address-type fire detection system  200 . 
     From the above, various embodiments of the present disclosure have been described for purposes of illustration, and it will be understood that various modifications are present without departing from the scope and spirit of the present disclosure. Furthermore, various embodiments are not intended to limit the spirit of the present disclosure, and the true spirit and scope will be presented from the following claims.