KR102638213B1 - Warning apparatus and method - Google Patents

Abstract

The present invention is a warning device for detecting and warning an abnormal condition in which operation of a generator is stopped, comprising: a power generation unit for generating power using vibration generated from the generator when the generator is operated; a power storage unit for receiving and storing the power generated by the power generation unit; A detection unit for detecting the operating state of the generator; And when the detection unit detects that the operation of the generator is stopped, a warning unit for generating a warning signal by operating with the power stored in the power storage unit; If the generator does not operate due to a problem, This can be quickly warned.

Description

Warning device and warning method{WARNING APPARATUS AND METHOD}

The present invention relates to a warning device and a warning method, and more specifically, to a warning device and a warning method that can quickly warn when a generator has a problem and does not operate.

Generators are generally installed in power plants or military equipment to generate power. The power generated from the generator is used to operate other devices mounted on power plants or military equipment.

At this time, a problem may occur while operating the generator and power may not be properly supplied to other devices. Therefore, detectors and warning devices are installed in power plants or military equipment to detect the status of the generator and warn when an abnormal condition occurs in the generator. Accordingly, operators of power plants or military equipment can respond to abnormal conditions of the generator and maintain the generator to stably supply power to other equipment.

However, if the operation of the generator is completely stopped due to an accident, etc., the power generated by the generator cannot be used. Accordingly, power supply may be interrupted to the detector that detects the status of the generator and the warning device that warns of an abnormal condition of the generator. Therefore, a problem may arise in which the generator cannot be detected and warned when its operation has stopped.

KR 10-1040735 B

The present invention provides a warning device and warning method that can generate a warning even in situations where power from a generator cannot be used.

The present invention provides a warning device and warning method that can quickly warn when a generator has a problem and does not operate.

The present invention is a warning device for detecting and warning an abnormal condition in which operation of a generator is stopped, comprising: a power generation unit for generating power using vibration generated from the generator when the generator is operated; a power storage unit for receiving and storing the power generated by the power generation unit; A detection unit for detecting the operating state of the generator; And when the detection unit detects that the operation of the generator is stopped, a warning unit for generating a warning signal by operating with the power stored in the power storage unit.

The power storage unit may include a battery that stores power supplied by the power generation unit and is connected to the warning unit to selectively supply power to the warning unit. and a control member for controlling the battery to supply power to the warning unit according to the detection result of the detection unit.

The power storage unit further includes a transforming member for adjusting the voltage of the power supplied by the power generation unit to the battery in accordance with the voltage of the battery.

The sensing unit includes a light emitting member connected to the power generating unit and configured to generate light using power supplied by the power generating unit; a light receiving member for checking whether the light emitting member emits light; and a judgment member for determining an operating state of the generator as being in operation or stopped depending on whether or not the light emitting member emits light confirmed by the light receiving member.

The power generation unit includes a first piezoelectric member connected to the power storage unit to supply power to be stored in the power storage unit; and a second piezoelectric member connected to the light-emitting member to supply power for causing the light-emitting member to emit light.

A plurality of second piezoelectric members are provided and installed in different areas of the generator, and the light emitting member uses power generated by a second piezoelectric member installed in one area of the generator among the second piezoelectric members. A first light emitting element that generates light; And a second light-emitting element that generates light using power generated by a second piezoelectric member installed in another area of the generator among the second piezoelectric members, wherein the determination unit includes the first light-emitting element and the When light generated by at least one of the second light emitting elements is received by the light receiving member, the operating state of the generator is determined to be in operation.

The number of first piezoelectric members is greater than that of the second piezoelectric members so that more power is supplied to the power storage unit than the sensing unit.

The present invention is a warning method for detecting and warning of an abnormal condition in which operation of a generator is stopped, comprising: generating power using vibration generated from the generator when the generator operates and storing it in a power storage unit; A process of detecting the operating state of the generator; And when it is detected that the operation of the generator is stopped, a process of generating a warning signal by activating the warning unit with the power stored in the power storage unit.

The process of generating power and storing it in the power storage unit includes generating power through piezoelectric power generation using the vibration; And a process of charging the power storage unit with power generated by the piezoelectric power generation.

The process of detecting the operating state of the generator includes generating light with power generated using the vibration; A process of checking whether the light is generated; and a process of determining an operating state of the generator as operating or stopped depending on whether or not the light is generated.

The process of generating the warning signal includes: controlling the power storage unit to supply power to the warning unit when the operating state of the generator is determined to be out of operation; and a process of activating the warning unit to visually or audibly generate an alarm.

According to embodiments of the present invention, a warning can be generated by operating the warning unit even in situations where power from the generator cannot be used. Accordingly, if the operation of the generator is interrupted, this can be detected and a quick warning can be issued using the warning unit. Therefore, the status of the generator can be easily checked while stably operating the warning unit.

1 is a diagram showing the configuration of a warning device according to an embodiment of the present invention.
Figure 2 is a diagram showing the configuration of a light emitting member and a structure in which a light receiving element receives light according to an embodiment of the present invention.
Figure 3 is a flow chart showing a warning method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the attached drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. These embodiments only serve to ensure that the disclosure of the present invention is complete and to fully convey the scope of the invention to those skilled in the art. This is provided to inform you. The drawings may be exaggerated to explain the invention in detail, and like symbols refer to like elements in the drawings.

FIG. 1 is a diagram showing the configuration of a warning device according to an embodiment of the present invention, and FIG. 2 is a diagram showing the configuration of a light emitting member and a structure in which a light receiving element receives light according to an embodiment of the present invention. In the following, a warning device according to an embodiment of the present invention will be described.

The warning device according to an embodiment of the present invention is a warning device for detecting and warning an abnormal condition in which the operation of the generator is stopped. Referring to FIG. 1, the warning device 100 includes a power generation unit 110, a power storage unit 120, a detection unit 130, and a warning unit 140.

At this time, the generator 50 may be installed in a power plant or military equipment. Devices mounted on power plants or military equipment can operate with power generated by the generator 50. Therefore, in order to operate a power plant or military equipment, the generator 50 can be operated without interruption to continuously generate power with the generator 50. When the generator 50 is operated, vibration may occur from the generator 50 itself.

The power generation unit 110 is installed in the generator 50. Accordingly, when the generator 50 operates and generates vibration, the vibration may be transmitted to the power generation unit 110. Accordingly, the power generation unit 110 may generate power using vibration generated from the generator 50 when the generator 50 operates. At this time, the power generation unit 110 is connected in parallel with the power storage unit 120 and the detection unit 130 through a cable branching from one line to two lines, and the power storage unit 120 and the detection unit ( 130) can also supply power. Alternatively, in order to individually supply power to the power storage unit 120 and the detection unit 130, the power generation unit 110 includes a first piezoelectric member 111 connected to the power storage unit 120, and a detection unit. Each may be provided with a second piezoelectric member 112 connected to 130 .

The first piezoelectric member 111 is attached to the generator 50. One or more first piezoelectric members 111 are attached to a portion of the body of the generator 50 and can receive vibration generated by the generator 50. The first piezoelectric member 111 can generate power by vibration generated by the generator 50. For example, the first piezoelectric member 111 may be a piezoelectric plate, and may generate DC power by performing piezoelectric power generation through vibration. Additionally, the first piezoelectric member 111 may be electrically connected to the power storage unit 120 through a cable or the like. Accordingly, the power generated by the first piezoelectric member 111 can be supplied to the power storage unit 120.

The second piezoelectric member 112 is attached to the generator 50. The second piezoelectric member 112 is provided in one or more pieces and is attached to another part of the body of the generator 50 (or a part to which the first piezoelectric member 111 is not attached) and reduces vibration generated in the generator 50. It can be delivered. The second piezoelectric member 112 may generate power by vibration generated by the generator 50. For example, the second piezoelectric member 112 may be a piezoelectric plate, and may generate DC power by performing piezoelectric power generation through vibration. Additionally, the second piezoelectric member 112 may be electrically connected to the sensing unit 130 through a cable or the like. Accordingly, the power generated by the second piezoelectric member 112 may be supplied to the sensing unit 130.

At this time, when a plurality of first piezoelectric members 111 are provided, the number of first piezoelectric members 111 may be greater than that of the second piezoelectric members 112. Therefore, more power can be supplied to the power storage unit 120 than to the detection unit 130. Accordingly, by increasing the amount of power supplied to the power storage unit 120, power can be quickly charged to the power storage unit 120.

The power storage unit 120 may be electrically connected to the power generation unit 110. Accordingly, the power storage unit 120 can receive the power generated by the power generation unit 110 and store the supplied power as power for operating the warning unit 140. Therefore, since the warning unit 140 does not operate with the power generated by the generator 50 but operates using separately stored power, the warning unit 140 can operate even when the operation of the generator 50 is stopped. there is. The power storage unit 120 includes a battery 121 and a control member 122.

The battery 121 is arranged to be spaced apart from the generator 50 and may be electrically connected to the power generation unit 110 through a cable or the like. When the power generation unit 110 includes the first piezoelectric member 111 and the second piezoelectric member 112, the battery 121 may be electrically connected to the first piezoelectric member 111. Accordingly, a portion of the power generated by the power generation unit 110 (or the power generated by the first piezoelectric member 111) may be supplied to the battery 121. The battery 121 can store the supplied power. Additionally, the battery 121 may be electrically connected to the warning unit 140 through a cable or the like so that the stored power can be selectively supplied to the warning unit 140. If the battery 121 does not supply the stored power to the warning unit 140, the warning unit 140 may not operate, and if the battery 121 supplies the stored power to the warning unit 140, the warning unit 140 may operate and generate a warning signal.

One side of the control member 122 may be connected to the sensing unit 130 to receive detection results from the sensing unit 130, and the other side may be connected to the battery 121 to control the battery 121. Accordingly, the control member 122 can control the battery 121 to supply power to the warning unit 140 according to the detection result of the detection unit 130. For example, when the detection unit 130 detects that the operating state of the generator 50 is operating, the control member 122 controls the battery 121 not to supply power to the warning unit 140 and (140) can be prevented from generating a warning signal. When the detection unit 130 detects that the operating state of the generator 50 is not in operation, the control member 122 controls the battery 121 to supply power to the warning unit 140 so that the warning unit 140 It can cause a warning signal to be generated. Therefore, through the warning signal of the warning unit 140, operators of power plants or military equipment can quickly confirm that a problem has occurred in the generator 50 and operation has been stopped.

Meanwhile, the power storage unit 120 may further include a first transforming member 123. The first transforming member 123 may be electrically connected between the power generator 110 and the battery 121. That is, the power input part of the first transformation member 123 may be connected to the power generation unit 110, and the output part of the first transformation member 123 may be connected to the battery 121. Accordingly, the first transforming member 123 can adjust the voltage of power supplied from the power generation unit 110 to the battery 121. That is, because the voltage of the power generated by the power generation unit 110 may be lower than the voltage of the battery 121, the first transforming member 123 is supplied to the battery 121 according to the voltage of the battery 121. The power voltage can be adjusted to be high. Accordingly, the power generated by the power generation unit 110 can be stably supplied to the battery 121. At this time, when the power generating unit 110 is provided with the first piezoelectric member 111 and the second piezoelectric member 112, the power input unit of the first transforming member 123 may be connected to the first piezoelectric member 111. there is.

The detection unit 130 can detect the operating state of the generator 50. For example, the detection unit 130 is electrically connected to the power generation unit 110 so that it can receive power generated by the power generation unit 110, and uses the supplied power to operate the generator 50. The operating state can be detected. The sensing unit 130 includes a light emitting member 131, a light receiving member 132, and a judgment member 133.

The light emitting member 131 is arranged to be spaced apart from the generator 50 and may be electrically connected to the power generation unit 110 through a cable or the like. When the power generation unit 110 includes the first piezoelectric member 111 and the second piezoelectric member 112, the light emitting member 131 may be electrically connected to the second piezoelectric member 112. Accordingly, the other part of the power generated by the power generation unit 110 that is not supplied to the power storage unit 120 (or the power generated by the second piezoelectric member 112) may be supplied to the light emitting member 131. there is. That is, power generated using vibration caused by the operation of the generator 50 can be supplied to the light emitting member 131. The light emitting member 131 can generate light using supplied power. At this time, if the operation of the generator 50 is stopped and vibration does not occur, the power generation unit 110 cannot generate power, so power is not supplied to the light emitting member 131, and light generation may be stopped. Therefore, the operating state of the generator 50 can be detected by whether the light emitting member 131 emits light. The light-emitting member 131 may include a first light-emitting device 131a and a second light-emitting device 131b, as shown in FIG. 2 .

The first light emitting element 131a may be arranged to face the light receiving member 132. For example, the first light emitting device 131a may be an LED. When a plurality of second piezoelectric members 112 are provided and installed in different areas of the generator 50, the first light emitting element 131a is installed in one area of the generator 50 among the second piezoelectric members 112. It can be electrically connected to the second piezoelectric member 112 and receive power. Accordingly, the first light emitting device 131a can generate light using the supplied power.

The second light emitting device 131b may be arranged to be spaced apart from the first light emitting device 131a and face the light receiving member 132. For example, the second light emitting device 131b may be an LED. When a plurality of second piezoelectric members 112 are provided and installed in different areas of the generator 50, the second light emitting element 131b is located in another area (or , can be electrically connected to the second piezoelectric member 112 installed in one area of the generator 50 and another area spaced apart from the generator 50 to receive power. Accordingly, the second light emitting device 131b can generate light using the supplied power.

At this time, since the first light-emitting device 131a and the second light-emitting device 131b are connected to different second piezoelectric members 112, either the first light-emitting device 131a or the second light-emitting device 131b If a problem occurs and the generator 50 cannot generate light while operating, the other generator 50 can generate light. Accordingly, it is possible to prevent erroneous determination that the operation of the generator 50 has been stopped due to a failure of one of the second piezoelectric members 112 or one of the light emitting elements. In addition, the second piezoelectric member 112 to which the first light-emitting element 131a is connected may be attached to a different part of the generator 50 than the second piezoelectric member 112 to which the second light-emitting element 131b is connected. there is. Accordingly, there is a difference in the amount of vibration generated in each area of the generator 50, so that even if the amount of vibration in one area is insufficient and power to emit light from one light emitting element is not generated, the amount of vibration in another area causes the power to emit light to another light emitting element. can be created.

The light receiving member 132 is disposed to face the light emitting member 131 and can receive light generated by the light emitting member 131. In detail, the light emitting member 131 may be arranged to face both the first light emitting device 131a and the second light emitting device 131b. Accordingly, the light receiving member 132 can check whether the light emitting member 131 emits light. That is, when light is received by the light receiving member 132, the light emitting member 131 generates light, and when light is not received by the light receiving member 132 or the amount of light received decreases, the light emitting member 131 generates light. It may be in a state where no light is generated.

The judgment member 133 may be connected to receive a confirmation result of whether the light emitting unit 131 emits light from the light receiving member 132. The determination member 133 may determine the operating state of the generator 50 as being in operation or stopped depending on whether the light emitting member 131 emits light. For example, when the generator 50 is in operation, the second piezoelectric member 112 can generate power due to the vibration of the generator 50 and supply it to the light emitting member 131, so the light emitting member 131 Can generate light. Accordingly, when light is received by the light receiving member 132, the judging member 133 may determine that the generator 50 is in operation. When the generator 50 is in an inoperable state, the second piezoelectric member 112 cannot produce power to be supplied to the light emitting member 131 due to no vibration of the generator 50, so the light emitting member 131 emits light. It may not occur. Accordingly, if light is not received by the light receiving member 132, the judging member 133 may determine that the generator 50 is in an operational state. In detail, when light generated by at least one of the first light-emitting device 131a and the second light-emitting device 131b is received by the light receiving member 132, the judgment member 133 determines the operating status of the generator 50. is determined to be in operation, and if the light is not received by the light receiving member 132 because both the first light emitting device 131a and the second light emitting device 131b do not generate light, the determining member 133 is connected to the generator 50. The operating status of can be judged to be out of operation. Because it checks whether light emitting elements connected to different second piezoelectric members 112 emit light, the judgment member 133 can more accurately determine the operating state of the generator 50. The judgment member 133 may transmit the decision result of determining the operating state of the generator 50 to the control member 122.

At this time, the battery 121 may be electrically connected to the light receiving member 132 and the judgment member 133. Therefore, the light receiving member 132 and the judgment member 133 can be operated by supplying power stored in the battery 121. Accordingly, even if there is no power produced by the generator 50, the light receiving member 132 and the judging member 133 can operate with power supplied from the battery 50.

Meanwhile, the sensing unit 130 may further include a blackout member (not shown). The blackout member is formed in a case shape and has a space inside which the light emitting member 131 and the light receiving member 132 are accommodated, and can block external light from flowing into the inside. Accordingly, the light receiving member 132 inside the blackout member can only receive light generated by the light emitting member 131, and can prevent erroneous detection of external light as light from the light emitting member 131. Accordingly, the light receiving member 132 can more accurately detect whether light is emitted from the light emitting member 131 or whether no light is emitted.

Additionally, the sensing unit 130 may further include a second transforming member 134. The second transforming member 134 may be electrically connected between the power generating unit 110 and the light emitting member 131. That is, the power input part of the second transforming member 134 may be connected to the power generating unit 110, and the power output part of the second transforming member 134 may be connected to the light emitting member 131. Accordingly, the second transforming member 134 can adjust the voltage of power supplied from the power generation unit 110 to the light emitting member 131. That is, because the voltage of the power supplied by the power generation unit 110 may be lower than the voltage of the light-emitting member 131, the second transforming member 134 adjusts the power generation unit 110 to the voltage of the light-emitting member 131. ) can be adjusted to increase the voltage of the generated power. Accordingly, the power generated by the power generation unit 110 is stably supplied to the light-emitting member 131, so that the light-emitting member 131 can be operated stably. At this time, when the power generation unit 110 is provided with the first piezoelectric member 111 and the second piezoelectric member 112, the power input unit of the second transforming member 134 may be connected to the second piezoelectric member 112. there is.

The warning unit 140 may be electrically connected to the power storage unit 120. The warning unit 140 can be selectively operated by the power supplied by the power storage unit 120. Accordingly, when the detection unit 130 detects that the operation of the generator 50 is stopped, the warning unit 140 operates with the power stored in the power storage unit 120 to generate a warning signal. That is, the power storage unit 120 can selectively supply power to the warning unit 140 to operate the warning unit 140 according to the detection result of the detection unit 130. In detail, when the detection unit 130 determines that the operating state of the generator 50 is in operation, the power storage unit 120 does not supply power to the warning unit 140, so that the warning unit 140 generates a warning signal. You may not do it. When the detection unit 130 determines that the operating state of the generator 50 is not in operation, the power storage unit 120 supplies power to the warning unit 140 so that the warning unit 140 can generate a warning signal. For example, the warning unit 140 may be a siren, and when it generates a warning signal, it may generate an alarm in a visual or auditory manner to the operator of a power plant or military equipment. However, the method in which the warning unit 140 generates a warning is not limited to this and may vary.

In this way, when the generator 50 operates normally, the power generated using the vibration of the generator 50 is stored, and when an abnormal condition occurs in which the operation of the generator 50 is stopped, the stored power is stored in the warning unit 50. can be supplied to. Even in a situation where the power of the generator 50 cannot be used, the warning unit 140 can be activated to generate a warning indicating that the operation of the generator 50 is stopped. Therefore, when the operation of the generator 50 is interrupted, this can be detected and a quick warning can be issued using the warning unit 140. Accordingly, the status of the generator 50 can be easily checked while stably operating the warning unit 140.

Figure 3 is a flow chart showing a warning method according to an embodiment of the present invention. In the following, a warning device according to an embodiment of the present invention will be described.

The warning method according to an embodiment of the present invention is a warning method for detecting and warning an abnormal condition in which the operation of the generator is stopped. Referring to FIG. 3, the warning method includes a process of generating power using vibration generated from the generator when the generator operates and storing it in the power storage unit (S110), a process of detecting the operating state of the generator (S120), and When it is detected that the generator is in a state of interruption, a process (S130) of generating a warning signal by activating the warning unit with the power stored in the power storage unit is included.

At this time, the warning method can be performed by a warning device according to an embodiment of the present invention. Therefore, in the following, the process of performing the warning method using the warning device configured as shown in FIG. 1 will be described by way of example. However, the warning method according to the embodiment of the present invention is not limited to this and can be performed by warning devices of various configurations.

First, when the generator operates, power is generated using vibration generated from the generator and stored in the power storage unit (S110). In detail, power can be produced by using the vibration generated in the generator 50 when the generator 50 operates, by generating piezoelectric power in the power generation unit 110 installed in the generator 50. The power generation unit 110 may charge the battery 121 of the power storage unit 120 with power generated by piezoelectric power generation. At this time, when the power generation unit 110 includes the first piezoelectric member 111 and the second piezoelectric member 112, the power generated by the first piezoelectric member 111 is supplied to the power storage unit 120. It is stored, and the power storage unit 120 can adjust the voltage of the supplied power to match the voltage of the battery 121 and then store it in the battery 121.

Next, the operating status of the generator is detected (S120). To this end, when the generator 50 operates, the light emitting member 131 is operated with a portion of the power generated using the vibration generated by the generator 50 to generate light, and the occurrence of light can be checked using the light receiving member 132. . Depending on whether the light emitting member 131 generates light, the operating state of the generator 50 can be determined to be in operation or stopped. For example, when the generator 50 is in operation, the power generator 110 can generate power using the vibration generated by the generator 50, so power is supplied to the light emitting member 131. Can generate light. Accordingly, when light is received by the light receiving member 132, it can be determined that the generator 50 is in operation. When the generator 50 is in an inoperable state, there is no vibration caused by the operation of the generator 50, so the power generator 110 cannot generate power using the vibration of the generator 50, so the light emitting member 131 Since power is not supplied, light cannot be generated. Therefore, if light is not received by the light receiving member 132, it can be determined that the generator 50 is in an operational state. Since the light-emitting member 131 does not generate light in conjunction with whether or not vibration of the generator 50 occurs, the operating state of the generator 50 can be quickly determined through whether the light-emitting member 131 emits light. It can be detected. At this time, when the power generation unit 110 includes the first piezoelectric member 111 and the second piezoelectric member 112, the power generated by the second piezoelectric member 112 can be supplied to the light emitting member 131. .

Next, when it is detected that the generator is in a state of interruption, the warning unit is activated using the power stored in the power storage unit to generate a warning signal (S130). That is, when the operating state of the generator 50 is determined to be in operation, the power storage unit 120 may be controlled not to supply power to the warning unit 140, thereby preventing the warning unit 140 from generating a warning. Conversely, when the operating state of the generator 50 is determined to be inoperable, the power storage unit 120 may be controlled to supply power to the warning unit 140 to generate a warning signal to the warning unit 140. For example, the warning unit () may generate an alarm visually or audibly to inform the operator of a power plant or military equipment that a problem has occurred in the generator 50 and its operation has been stopped. Since the warning unit 140 does not operate with the power generated by the generator 50 but operates using power separately stored in the power storage unit 120, it operates even when the operation of the generator 50 is stopped and generates the generator ( 50) can warn you that the operation has stopped. Accordingly, operators of power plants or military equipment can easily confirm that the operation of the generator 50 has stopped through the alarm of the warning unit 140.

In this way, when the generator 50 operates normally, the power generated using the vibration of the generator 50 is stored, and when an abnormal condition occurs that stops the operation of the generator 50, the stored power is stored in the warning unit 50. can be supplied to. Even in a situation where the power of the generator 50 cannot be used, the warning unit 140 can be activated to generate a warning indicating that the operation of the generator 50 is stopped. Therefore, when the operation of the generator 50 is interrupted, this can be detected and a quick warning can be issued using the warning unit 140. Accordingly, the status of the generator 50 can be easily checked while stably operating the warning unit 140.

As such, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention, and various combinations between the embodiments are also possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the claims described below as well as equivalents to these claims.

50: Generator 100: Warning device
110: Power generation unit 111: First piezoelectric member
112: second piezoelectric member 120: power storage unit
121: Battery 122: Control member
130: sensing unit 131: light emitting member
132: light receiving member 133: judgment member
140: warning unit

Claims (11)

As a warning device to detect and warn of abnormal conditions that cause the generator to stop operating,
a power generator for generating power using vibration generated from the generator when the generator operates;
a power storage unit for receiving and storing power generated by the power generation unit;
A detection unit for detecting the operating state of the generator; and
When the detection unit detects that the operation of the generator is stopped, a warning unit operates with the power stored in the power storage unit to generate a warning signal,
The sensing unit,
A light emitting member for generating light with the power supplied by the power generation unit,
A light receiving member for checking whether the light emitting member emits light, and
It includes a judgment member for determining the operating state of the generator as operating or stopped depending on whether the light emitting member confirms the light emitting member by the light receiving member,
The power generator,
A first piezoelectric member connected to the power storage unit to supply power to be stored in the power storage unit, and
It includes a second piezoelectric member connected to the light-emitting member to supply power for causing the light-emitting member to emit light,
A warning device in which the number of first piezoelectric members is greater than that of the second piezoelectric members so that more power is supplied to the power storage unit than the detection unit. In claim 1,
The power storage unit,
a battery that stores power supplied by the power generation unit and is connected to selectively supply power to the warning unit; and
A warning device including a control member for controlling the battery to supply power to the warning unit according to the detection result of the detection unit. In claim 2,
The power storage unit,
A warning device further comprising a transformer for adjusting the voltage of the power supplied by the power generation unit to the battery in accordance with the voltage of the battery. delete delete In claim 1,
A plurality of second piezoelectric members are provided and installed in different areas of the generator,
The light emitting member is,
a first light emitting element that generates light using power generated by a second piezoelectric member installed in one area of the generator among the second piezoelectric members; and
It includes a second light-emitting element that generates light using power generated by a second piezoelectric member installed in another area of the generator among the second piezoelectric members,
The determination unit is a warning device that determines the operating state of the generator as operating when light generated by at least one of the first light emitting device and the second light emitting device is received by the light receiving member. delete As a warning method to detect and warn of an abnormal condition that stops the operation of the generator,
A process of storing the power generated by the first piezoelectric member using vibration generated from the generator when the generator operates in a power storage unit;
A process of detecting the operating state of the generator; and
When it is detected that the operation of the generator is stopped, a process of generating a warning signal by activating the warning unit with the power stored in the power storage unit,
The process of detecting the operating state of the generator is,
A process in which a second piezoelectric member generates light with power generated using the vibration,
A process of checking whether the light is generated, and
Including a process of determining the operating state of the generator as operating or stopped depending on whether the light is generated,
A warning method in which the number of first piezoelectric members is greater than that of the second piezoelectric members so that the power supplied to the power storage unit is greater than the power supplied to generate the light. In claim 8,
The process of generating the power and storing it in the power storage unit,
A process of generating power using piezoelectric power using the vibration; and
A warning method comprising: charging the power storage unit with power generated by the piezoelectric power generation. delete In claim 8,
The process of generating the warning signal is,
When the operating state of the generator is determined to be out of operation, controlling the power storage unit to supply power to the warning unit; and
A warning method comprising: activating the warning unit to visually or audibly generate an alarm.

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