JP4539314B2 - Alarm unit - Google Patents

Description

  The present invention relates to an alarm unit attached to a dosimeter for measuring a radiation dose.

  The dosimeter measures the radiation dose (hereinafter referred to as “dose”) exposed to radiation workers during work, and measures and displays the radiation dose exposed during the work in real time. Is used to prevent overexposure of radiation workers. Such a dosimeter is always carried by a radiation worker when working in a radiation control area, and is often used by being stored in a pocket of protective clothing worn during the work.

The radiation control area where such a dosimeter is used is, for example, in the noise environment such as the sound of the equipment, in addition to the exhaust sound of the air and the supply air sound. Voice alone was not always enough.
In view of such a situation, the prior art about a dosimeter provided with a vibrator that transmits a warning to a radiation worker by vibration even in a noisy environment is disclosed in, for example, Patent Document 1 (Title: Vibratory Pocket Dose Device). Yes.

Japanese Patent Laid-Open No. 11-84008 (paragraph numbers 0007, 0008, FIGS. 1 and 2)

In the prior art disclosed in FIG. 1 of Patent Document 1, a vibrating part is arranged inside a dosimeter. However, a general dosimeter has a shielding effect and increases noise resistance. For example, magnesium (Mg)) having a high electromagnetic shielding effect may be used, and in order to vibrate a case having such a heavy structure, for example, a large motor is used and a relatively heavy eccentricity is used. Rotating the cam at high speed to generate strong vibrations, design restrictions due to the increase in the size of the motor used, eccentric cam, etc., and the increase in power required to drive the eccentric cam Cause problems.
Even if the case is reduced in weight, the dosimeters share the same power supply, so if the battery is consumed during normal dosimetry work, the motor used will not be able to rotate a predetermined amount and vibrate at the time of alarm. There was also a risk that the part would not vibrate sufficiently.

Moreover, in the prior art disclosed in FIG. 2 of Patent Document 1, the dosimeter and the vibration unit are configured separately, and the dosimeter is configured to receive and vibrate sound. There was a possibility that the sound was not received reliably, and there was a possibility that it would not vibrate at the time of alarm.
In addition, when the dosimeter and the vibration part are arranged apart from each other or when the arrangement position is wrong, there is a problem that it is difficult to receive sound.

  Therefore, the present invention has been made in view of the above-mentioned problems, and its purpose is to eliminate the situation where the dosimeter does not operate, and to obtain a sufficiently strong vibration with limited power so that radiation can be obtained. The object is to provide an alarm unit that reliably prevents excessive exposure of workers.

In order to solve the above-described problem, an alarm unit according to the first aspect of the present invention provides:
An alarm unit connected to a dosimeter that detects radiation and calculates radiation dose,
A main body mechanically coupled to one outer end of the dosimeter and communicatively connected to the dosimeter;
One end is supported by the main body, and the end of the dosimeter extends to the vicinity of the other end of the dosimeter .
A vibrating portion that is disposed on the other end of the one or more cantilever beams and vibrates according to one or more vibrating elements that vibrate according to a drive signal;
Alarm unit drive control unit connected to communicate with one or more vibration elements of the dosimeter and the vibration unit , and outputs a drive signal to one or more vibration elements of the vibration unit according to a control signal output from the dosimeter When,
A power supply unit disposed in the body and electrically connected to the alarm unit drive control unit;
Equipped with a,
The main body includes a connection pin, and the dosimeter includes a connection receiving portion. The connection pin is fitted into the connection receiving portion to mechanically connect the main body and the dosimeter. a connecting pin electrically connected to the to Rukoto wherein possible communication with the alarm unit drive control unit and the dosimeter.

Moreover, the alarm unit of the invention according to claim 2 of the present invention is:
An alarm unit connected to a dosimeter that detects radiation and calculates radiation dose,
A main body mechanically coupled to one outer end of the dosimeter and communicatively connected to the dosimeter;
One end is supported by the main body, and the end of the dosimeter extends to the vicinity of the other end of the dosimeter.
A vibrating portion that is disposed on the other end of the one or more cantilever beams and vibrates according to one or more vibrating elements that vibrate according to a drive signal;
A display unit provided on the main body;
The dosimeter is connected to communicate with one or more vibrating elements and the display portion of the vibrating section, it outputs a drive signal to one or more of the vibrating element and the display portion of the vibrating portion in response to the control signal output from the dosimeter An alarm unit drive controller to
A power supply unit disposed in the body and electrically connected to the alarm unit drive control unit;
Equipped with a,
The main body includes a connection pin, and the dosimeter includes a connection receiving portion. The connection pin is fitted into the connection receiving portion to mechanically connect the main body and the dosimeter. a connecting pin electrically connected to the to Rukoto wherein possible communication with the alarm unit drive control unit and the dosimeter.

Moreover, the alarm unit of the invention according to claim 3 of the present invention is:
The alarm unit according to claim 2,
Wherein the display unit is arranged on either side of the dosimeter, it is arranged Haritai and vibration portion between these both sides of the display unit, characterized in Rukoto.

Moreover, the alarm unit of the invention according to claim 4 of the present invention is:
In alarm unit according to any one of claims 1 to 3,
The connection socket portion forming the connecting pin and pair and said pairs comprises Rukoto.

Moreover, the alarm unit of the invention according to claim 5 of the present invention is:
The alarm unit according to claim 4 ,
The part of the connection pin connecting the socket part, characterized in Rukoto that Yusuke only mechanical connection functions.

Moreover, the alarm unit of the invention according to claim 6 of the present invention is:
In the alarm unit according to any one of claims 1 to 5 ,
It characterized that you supported by the main by the elastic support portions the beam body.

Moreover, the alarm unit of the invention according to claim 7 of the present invention is:
The alarm unit according to claim 6,
It said elastic body and said grommet der Rukoto.

Moreover, the alarm unit of the invention according to claim 8 of the present invention is:
The alarm unit according to claim 6 ,
It said elastic body and said elastic body der Rukoto planar.

Moreover, the alarm unit of the invention according to claim 9 of the present invention is:
In the alarm unit according to any one of claims 1 to 8,
A chamfered portion is formed at an end portion of the main body of the alarm unit to facilitate storage in a pocket or other bag body.

Moreover, the alarm unit of the invention according to claim 10 of the present invention is:
In the alarm unit according to any one of claims 1 to 9,
An instructing unit is provided for informing a user of an arrangement position of the alarm unit.

Moreover, the alarm unit of the invention according to claim 11 of the present invention is:
In the alarm unit according to any one of claims 1 to 10,
The dosimeter is
A radiation detection unit that transmits a detection signal in response to detection of radiation;
An output unit for audio output and / or display;
A dosimeter drive control unit that performs calculation processing based on the detection signal of the radiation detection unit, calculates radiation dose data, and transmits an output signal that causes the output unit to output sound and / or display based on the radiation dose data When,
The dosimeter drive control unit outputs an output signal to the output unit, and also outputs a control signal to the alarm unit drive control unit of the alarm unit.

  According to the present invention as described above, it is possible to eliminate the situation in which the dosimeter does not operate, and to obtain a sufficiently strong vibration with limited power so as to surely prevent excessive exposure of radiation workers. Alarm unit can be provided.

Next, the best mode for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a perspective external view of a dosimeter 1 with an alarm function. The dosimeter 1 with an alarm function includes the alarm unit 100 and the dosimeter 200 of this embodiment. The alarm unit 100 will be described. 2A and 2B are four views of the alarm unit 100 according to the present embodiment. FIG. 2A is a plan view, FIG. 2B is a front view, FIG. 2C is a right side view, and FIG. FIG.
As shown in FIG. 2, the alarm unit 100 includes a main body 101, a beam body 102, a vibration unit 103, a connection pin 104, a communication line 105, and a detection switch 106.

The main body 101 is formed in a substantially L shape when viewed from the right side, and includes a lid portion 101a and a battery lid 101b. As will be described in detail later, the main body 101 is mechanically coupled to the dosimeter 200 and is connected to the dosimeter 200 so as to be communicable.
The beam body 102 is a cantilever whose one end is supported by a fixed end inside the main body 101.
The vibration part 103 is arrange | positioned at the other end side (free end side) of a beam body, and is made to vibrate according to a drive signal.

The connection pin 104 is inserted into the connection opening 205 (see FIG. 6), and the dosimeter 200 is attached to the alarm unit 100. In this embodiment, four connection pins 104 are provided.
The communication line 105 is wired between the main body 101 and the vibration unit 103. A certain amount of play is given to prevent disconnection even during vibration.
The detection switch 106 protrudes from the dosimeter mounting surface 101c of the main body 101, and when the dosimeter 200 is attached to the alarm unit 100, the detection switch 106 is pressed down to the alarm unit drive control unit 109 described later. A detection signal is output. Thus, it is possible to detect whether or not the dosimeter 200 is placed, and when the dosimeter 200 is not placed, the alarm unit 100 is not operated to prevent waste of power.

Next, the internal structure of the alarm unit 100 will be described. FIG. 3 is an internal structural view of the alarm unit of this embodiment, FIG. 3 (a) is a plan view, FIG. 3 (b) is a sectional view with the side wall removed, and FIG. 3 (c) is a cover portion / battery cover. FIG. 3D is a central cross-sectional view, and FIG. 3E is a bottom view with the battery lid removed.
The main body 101 further includes a lid portion 101a, a battery lid 101b, a dosimeter placement surface 101c, a housing portion 101d, a stepped support portion 101e, and a chamfered portion 101f. When the lid 101a and the battery lid 101b of the main body 101 are removed, the control board 107 and the power source 108 are accommodated in the accommodating portion 101d. The control board 107 is a normal printed circuit board, and is firmly fixed to the three stepped support portions 101e arranged at the vertices of an equilateral triangle. Due to this fixing, even if vibration occurs, the control board 107 does not loosen. The power source 108 is, for example, one commercially available AA battery.

  A chamfered portion 101 f is formed at the end of the main body 101 of the alarm unit 100. In this embodiment, a large R portion is formed on the front side. As a result, it is possible to facilitate the storage without being caught at the end when the radiation worker is stored in the pocket or other bag. Although not shown, if the front and back surfaces of the end portion of the main body 101 of the alarm unit 100 are formed with chamfered portions by the R portion, it is possible to more easily store them in a pocket or other bag body. In this case, the main body 101 is semicircular or elliptical when viewed from the side. In addition, it is also possible to employ | adopt C part as a chamfering part.

  The beam body 102 further includes an elastic support portion 102a. The elastic support portion 102a is, for example, a normal grommet, and specifically has one outer peripheral groove formed on the outer periphery of the ring body. The outer peripheral groove of the grommet is fitted into the hole formed in the beam body 102, and the elastic support portion 102 a is fixed to the beam body 102. Such an elastic support portion 102a is fitted into the upper shaft of the stepped support portion 101e, and is further pressed and attached by the lid portion 101a. The beam body 102 having such a configuration is supported so as to be able to vibrate even at the fixed end due to the elasticity of the elastic support portion 102a.

The vibration unit 103 further includes a vibration element 103a and a lid 103b.
Specifically, the vibration part 103 is formed by embedding a vibration element 103a in a hole for embedding formed in the beam body 102 and fixing the vibration element 103a with a lid part 103b. Various types of the vibration element 103a such as a motor with an eccentric cam generally used in a normal mobile phone can be considered. In this embodiment, a piezoelectric element that vibrates when a voltage is applied is employed. By using this piezoelectric element, vibration (for example, ultrasonic vibration) can be generated from an electric signal, and vibration in the direction of arrow A in FIG. 7 is possible. In this embodiment, the beam body 102 and the vibrating portion 103 are integrated, but a configuration in which a separately configured vibrating portion and a plate-like beam body are fixed with screws may be employed. It is only necessary that the vibration part is finally fixed to the beam body.
The connection part pin 104 further includes a pin support part 104a. The pin support portion 104a is fixed to the main body 101 in the accommodating portion 101d, and the connection pin 104 is fixed.

The communication line 105 is a lead wire for connecting the control board 107 and the vibration element 103a. Specifically, the alarm unit drive control unit 109 (see FIG. 4) mounted on the control board 107 and the vibration element 103a of the vibration unit 103 are wired.
The main body of the detection switch 106 is arranged in the housing part 101d, and only the movable part protrudes to the dosimeter mounting surface 101c.

  In such an alarm unit 100, the main body 101 is attached to one end of the dosimeter 200 (the lower end of the dosimeter 200 in FIGS. 1 to 3), and the tip of the vibration unit 103 is near the other end of the dosimeter 200 (FIG. 1 to FIG. 1). In FIG. 3, it extends to the vicinity of the upper end of the dosimeter 200). With such a configuration, the beam body 102 is made sufficiently long, and the vibration of the vibration element 103a can be converted into a larger vibration.

Subsequently, a circuit of the alarm unit 100 will be described. FIG. 4 is a circuit block diagram of the alarm unit 100 of the present embodiment.
Inside the alarm unit 100, for example, an alarm unit drive control unit 109 such as a CPU / MPU is mounted on the control board 107 (see FIG. 3). The alarm unit drive control unit 109 is supplied with electric power from a power source 108 (see FIGS. 3 and 4), and also includes a dosimeter drive control unit 201 of the dosimeter 200, a vibration element 103a of the vibration unit 103, and a detection switch 106. It is connected so that it can communicate. The signal processing of the alarm unit 100 will be described later.

Next, the circuit block of the dosimeter 200 will be described with reference to the drawings. FIG. 5 is a circuit block diagram of the dosimeter 200, which includes a dosimeter drive control unit 201, a radiation detection unit 202, an alarm unit 203, a display unit 204, and a connection receiving unit 205. Although not shown, a power supply is also provided. The signal processing of the dosimeter 200 will also be described later.
The radiation detection unit 202 transmits a detection signal in response to detection of radiation.
The alarm unit 203 is a specific example of the output unit of the present invention, and is a buzzer that emits a warning sound or a speaker that outputs sound.
The display unit 204 is a specific example of the output unit of the present invention, and although not shown, the dose is expressed numerically and displayed.
In addition, although demonstrated as what is provided with the display part 204 and the alarm part 203, it is good also as an output part only for a sound other than that or only a display.

Subsequently, functions, signal processing, and mechanical operations of each component when the alarm unit 100 and the dosimeter 200 are functioned as the dosimeter 1 with an alarm function will be described collectively.
First, the connection of the dosimeter 200 to the alarm unit 100 will be described. FIG. 6 is an explanatory diagram for explaining the connection of the dosimeter 200 to the alarm unit 100. In a state where the connection pin 104 of the alarm unit 100 is inserted into the connection opening 205 of the dosimeter 200, the dosimeter 200 is pushed into the dosimeter mounting surface 101c, and as shown in FIG. Connect a total of 200. The connection receiving part 205 has a depth of 5 times or more with respect to the diameter of the connection pin 104, so that the connection pin 104 is fitted into the connection receiving part 205 to connect the main body 101 and the dosimeter 200 to the machine. Are firmly connected. Further, the connection receiving portion 205 and the connection pin 104 are electrically connected, and as shown in FIGS. 4 and 5, the alarm unit drive control unit 109 of the alarm unit 100 and the dosimeter drive of the dosimeter 200 are driven. The control unit 201 is communicably connected. Then, an operation unit (not shown) of the dosimeter 200 is operated to start the operation of the dosimeter 1 with an alarm function.

  In this embodiment, the four connection pins 104 and the four connection receiving portions 205 are used for mechanical connection / electrical connection. For example, instead of the six connection pins 104 and 6, The four connection pairs are used for both mechanical connection and electrical connection, but the remaining two pairs of connection pins 104 and the connection reception part 205 have only a mechanical connection function. Anyway. Thus, the alarm unit can be more firmly connected and strong against vibration.

Next, the alarm operation will be described.
As shown in FIG. 5, the dosimeter drive control unit 201 calculates radiation dose data by a calculation process based on the detection signal of the radiation detection unit 202, and the dose that has been exposed based on the radiation dose data is a preset dose. When it is determined that the value exceeds the threshold, an output signal for causing the display unit 204 to perform display and / or an output signal for causing the alarm unit 203 to perform an audio output such as an alarm or sound is transmitted. At the same time, a control signal is output to the alarm unit drive control unit 109 of the alarm unit 100. This control signal is transmitted to the alarm unit drive control unit 109 via the connection receiving unit 205 and the connection pin 104.

The alarm unit drive control unit 109 is in a state where it can receive the control signal because the detection signal from the detection switch 106 is input. The alarm unit drive control unit 109 receives the control signal output from the dosimeter drive control unit 201 of the dosimeter 200. If the control signal is an alarm command signal, the alarm unit drive control unit 109 sends a drive signal to the vibration element 103a of the vibration unit 103. Output. Then, the vibration element 103a vibrates in the direction of arrow A as shown in the explanatory view of vibration in FIG. At this time, the elastic support portion 102a vibrates in the arrow B direction even at the base of the beam body 102. These vibrations are combined, and the vibration unit 103 vibrates greatly in the direction of arrow C. The beam body 102 and the vibration unit 103 vibrate greatly without changing the dosimeter 200, and the vibration unit 103 transmits the vibration to the radiation service worker, so that the radiation service worker recognizes the informed alarm and performs radiation management. You will leave the area. At this time, since the elastic support portion 102a also acts so as not to transmit the vibration to the main body 101, a situation in which the control board 107 breaks down due to the vibration is avoided, and the reliability of the alarm unit is improved. ing.
Further, according to FIG. 3, the width of the opening of the main body 101 through which the beam body 102 is inserted is substantially the same as the thickness of the beam body 102. In other words, the beam body 102 vibrates with the opening as a fulcrum. Therefore, although not shown, an elastic support portion may be provided in the vicinity of the opening so as to be reliably supported as a fulcrum. In addition, when the width of the opening of the main body 101 is larger than the thickness of the beam body 102, the beam body 102 may collide with the peripheral edge of the opening during vibration. Therefore, an elastic protection part is provided near the opening. It is also possible to avoid collision, or to provide an elastic support portion and avoid the collision using the opening as a fulcrum. These configurations are selected according to circumstances.

  In this embodiment, the beam body 102 is made sufficiently long to convert the vibration caused by the vibration element 103 a into a large vibration of the beam body 102. Further, the support portion of the beam body 102 is an elastic support portion 102a, which is easy to vibrate. Also in this respect, a large vibration is generated. Combined with these actions, a large vibration can be generated with a small configuration.

Next, another embodiment of the present invention will be described with reference to the drawings.
FIG. 8 is a perspective external view of another type of alarm unit 300, and FIG. 9 is a circuit block diagram of another type of alarm unit 300. As shown in FIGS. 8 and 9, the alarm unit 300 of this embodiment includes a main body 301, display units 302 and 303, a detection switch 304, a power source 305, and an alarm unit drive control unit 306. A dosimeter 200 is connected to the alarm unit 300 for use. The alarm unit drive control unit 306 is supplied with power from a power source 305. The alarm unit 300 is mechanically coupled by a connection pin / connection socket (not shown) (same form as the connection pin 104 / connection slot 205 in FIG. 6), and at the same time is electrically connected to enable communication. . Then, an operation unit (not shown) of the dosimeter 200 is operated to start the operation of the alarm function-equipped dosimeter.

  As shown in FIG. 5, the dosimeter drive control unit 201 calculates radiation dose data by calculation processing based on the detection signal of the radiation detection unit 202, and the dose that has been exposed based on the radiation dose data is a preset dose. When it is determined that the value exceeds the threshold, an output signal for causing the display unit 204 to perform display and / or an output signal for causing the alarm unit 203 to perform an audio output such as an alarm or sound is transmitted. At the same time, a control signal is output to the alarm unit drive control unit 306 of the alarm unit 300. This control signal is transmitted to the alarm unit drive control unit 306 via a connection port / connection pin (not shown).

  Since the alarm unit drive control unit 306 receives the detection signal from the detection switch 304, the alarm unit drive control unit 306 can receive the control signal. The alarm unit drive control unit 306 receives the control signal output from the dosimeter drive control unit 201 of the dosimeter 200, and outputs the drive signal to the display units 302 and 303 if the control signal is an alarm command signal. . Then, the display units 302 and 303 are both lit, flashing at the same time, or flashing alternately. To emit. Such light emission allows a radiation worker to recognize an abnormality.

Next, another embodiment of the present invention will be described with reference to the drawings.
FIG. 10 is a perspective external view of an alarm unit 400 according to another embodiment, and FIG. 11 is a circuit block diagram of the alarm unit 400 according to another embodiment. As shown in FIGS. 10 and 11, the alarm unit 400 of this embodiment includes a main body 401, display units 402 and 403, a vibration unit 404, a detection switch 405, a power source 406, an alarm unit drive control unit 407, and the like. It has. The dosimeter 200 is connected to the alarm unit 400 for use. The alarm unit drive control unit 407 is supplied with power from a power source 406. Although not shown in the figure, the alarm unit 400 is mechanically coupled by a connection pin / connection port (the same form as the connection pin 104 / connection port 205 in FIG. 6) and at the same time is electrically connected to enable communication. Yes. Then, an operation unit (not shown) of the dosimeter 200 is operated to start the operation of the dosimeter with an alarm function.

  As shown in FIG. 5, the dosimeter drive control unit 201 calculates radiation dose data by calculation processing based on the detection signal of the radiation detection unit 202, and the dose that has been exposed based on the radiation dose data is a preset dose. When it is determined that the value exceeds the threshold, an output signal for causing the display unit 204 to perform display and / or an output signal for causing the alarm unit 203 to perform an audio output such as an alarm or sound is transmitted. At the same time, a control signal is output to the alarm unit drive control unit 407 of the alarm unit 400. This control signal reaches the alarm unit drive control unit 407 via the connection port / connection pin.

  Since the alarm unit drive control unit 407 receives the detection signal from the detection switch 405, the alarm unit drive control unit 407 can receive the control signal. The alarm unit drive control unit 407 receives the control signal output from the dosimeter drive control unit 201 of the dosimeter 200, and outputs the drive signal to the display units 402 and 403 if the control signal is an alarm command signal. . At the same time, a drive signal is output to the vibration element 404 a of the vibration unit 404. Then, the display units 402 and 403 are both lit, blinking at the same time, or blinking alternately, and issue a light alarm in a form that can easily attract the attention of a radiation worker. At the same time, the vibration unit 404 vibrates and issues a warning due to vibration to a radiation worker. A radiation worker can perceive such a light emission / vibration at the same time, thereby recognizing that the alarm is surely notified even in a noisy environment.

  In these alarm units 100 to 400, various modifications can be employed. Such a modification will be described. 12 and 13 are explanatory diagrams of an alarm unit 500 according to a modified embodiment. For example, instead of the AA battery described above as a power source, a button battery 501 may be employed and the battery lid 502 may be detachable as shown in FIG. Since the battery lid 502 can be opened and closed by a coin 503, the configuration can be simpler than the battery lid shown in FIGS. 2 and 3, which contributes to downsizing. Such a configuration can be adopted in the alarm units 100 to 400.

  In addition, as shown in FIG. 12 (b), if an instruction unit 504 that informs the user of the position of the alarm unit is provided, the radiation work that has seen the instruction "Please make this surface touch the body." In order for the worker to make sure that the vibration part is in contact with the body, it is possible to reduce the possibility of occurrence of a situation in which the alarm cannot be recognized without the vibration reaching. Such a configuration can be adopted in the alarm units 100 to 400.

  Further, instead of the elastic support portion 102a by the grommet as shown in FIG. 3, an elastic support portion 505 that adheres to and supports the beam body 506 with a large area as shown in FIG. Such a configuration can be adopted in the alarm units 100 to 400. As described above, the elastic support is not limited to the grommet, and various forms can be adopted. However, as shown in FIG. 3, the smaller the elastic support such as the grommet, the larger the beam is shaken. Since vibration is obtained, it is preferable.

  Further, as shown in FIGS. 13A and 13B, a plurality of beam bodies each having a plurality of cantilever beams protruding may be formed. The alarm unit 600 includes a main body 601, a first vibrating portion 602, a second vibrating portion 603, a first beam body 604, a second beam body 605, connection pieces 606 and 607, and connection holes 608 and 609. The first beam body 604 and the second beam body 605 are respectively provided with a first vibration part 602 and a second vibration part 603 on the upper side, and connection holes 608 and 609 on the lower side. The first beam body 604 and the second beam body 605 are inserted into the connection pieces 606 and 607 of the main body 601, respectively, and as shown in FIG. 13A, the vibration parts fixed to the two cantilever beams are arranged. . Thereby, since vibration generate | occur | produces in many places, there exists an advantage that the alarm by vibration is easy to recognize.

  The alarm unit of the present invention has been described above. The alarm unit according to the present invention is configured by separating the power supply of the dosimeter and the power supply of the alarm unit, so that the situation where the alarm unit does not operate due to insufficient power is eliminated, and the fixed end is elastically supported. Adopting a configuration that can be converted into sufficiently strong vibration with limited power while configuring, it is possible to transmit a warning by vibration to radiation workers working with thick protective clothing in the radiation control area, Ensure that radiation workers are not overexposed.

It is a perspective external view of a dosimeter with an alarm function. FIG. 2A is a four-side view of an alarm unit of the best mode for carrying out the present invention, FIG. 2A is a plan view, FIG. 2B is a front view, FIG. 2C is a right side view, and FIG. d) is a rear view. It is an internal structure figure of the alarm unit of the best form for implementing this invention, Fig.3 (a) is a top view, FIG.3 (b) is sectional drawing which removed the side wall, FIG.3 (c) is a cover part. FIG. 3D is a central sectional view, and FIG. 3E is a bottom view with the battery cover removed. It is a circuit block diagram of the alarm unit of the best form for implementing this invention. It is a circuit block diagram of a dosimeter. It is explanatory drawing explaining the connection of the dosimeter to an alarm unit. It is explanatory drawing of a vibration. It is a perspective external view of the alarm unit of another form. It is a circuit block diagram of the alarm unit of other forms. It is a perspective external view of the alarm unit of another form. It is a circuit block diagram of the alarm unit of other forms. It is explanatory drawing of the alarm unit by a modification. It is explanatory drawing of the alarm unit by a modification.

Explanation of symbols

1: Dosimeter with alarm function 100: Alarm unit 101: Main body 101a: Lid 101b: Battery lid 101c: Dosimeter placement surface 101d: Housing 101e: Stepped support 101f: Chamfer 102: Beam 102a: Elasticity Supporting part 103: Vibration part 103a: Vibration element 103b: Cover part 104: Connection pin 104a: Pin support part 105: Communication line 106: Detection switch 107: Control board 108: Power supply 109: Alarm unit drive control part 200: Dosimeter 201 : Dosimeter drive control unit 202: Radiation detection unit 203: Alarm unit 204: Display unit 205: Connection port unit 300: Alarm unit 301: Body 302: Display unit 303: Display unit 304: Detection switch 305: Power supply 306: Alarm Unit drive control unit 400: alarm unit 401: main body 402: display unit 403: display unit 404: vibration unit 04a: Vibration element 405: Detection switch 406: Power supply 407: Alarm unit drive control unit 500: Alarm unit 501: Button battery 502: Battery cover 503: Coin 504: Instruction unit 505: Elastic support unit 506: Beam body 600: Alarm unit 601: Main body 602: First vibrating portion 603: Second vibrating portion 604: First beam body 605: Second beam body 606: Connection piece 607: Connection piece 608: Connection hole 609: Connection hole

Claims (11)

An alarm unit connected to a dosimeter that detects radiation and calculates radiation dose,
A main body mechanically coupled to one outer end of the dosimeter and communicatively connected to the dosimeter;
One end is supported by the main body, and the end of the dosimeter extends to the vicinity of the other end of the dosimeter .
A vibrating portion that is disposed on the other end of the one or more cantilever beams and vibrates according to one or more vibrating elements that vibrate according to a drive signal;
Alarm unit drive control unit connected to communicate with one or more vibration elements of the dosimeter and the vibration unit , and outputs a drive signal to one or more vibration elements of the vibration unit according to a control signal output from the dosimeter When,
A power supply unit disposed in the body and electrically connected to the alarm unit drive control unit;
Equipped with a,
The main body includes a connection pin, and the dosimeter includes a connection receiving portion. The connection pin is fitted into the connection receiving portion to mechanically connect the main body and the dosimeter. alarm unit, wherein to Rukoto can communicate with the alarm unit drive control unit and the connection pins electrically connected to the dosimeter. An alarm unit connected to a dosimeter that detects radiation and calculates radiation dose,
A main body mechanically coupled to one outer end of the dosimeter and communicatively connected to the dosimeter;
One end is supported by the main body, and the end of the dosimeter extends to the vicinity of the other end of the dosimeter.
A vibrating portion that is disposed on the other end of the one or more cantilever beams and vibrates according to one or more vibrating elements that vibrate according to a drive signal;
A display unit provided on the main body;
The dosimeter is connected to communicate with one or more vibrating elements and the display portion of the vibrating section, it outputs a drive signal to one or more of the vibrating element and the display portion of the vibrating portion in response to the control signal output from the dosimeter An alarm unit drive controller to
A power supply unit disposed in the body and electrically connected to the alarm unit drive control unit;
Equipped with a,
The main body includes a connection pin, and the dosimeter includes a connection receiving portion. The connection pin is fitted into the connection receiving portion to mechanically connect the main body and the dosimeter. alarm unit, wherein to Rukoto can communicate with the alarm unit drive control unit and the connection pins electrically connected to the dosimeter. The alarm unit according to claim 2,
Alarm unit wherein the display unit which are arranged on both sides of the dosimeter, is arranged Haritai and vibration portion between these both sides of the display unit, characterized in Rukoto. In alarm unit according to any one of claims 1 to 3,
Alarm unit, wherein a plurality of pairs comprising Rukoto connecting socket portion forming the connecting pin and pair. The alarm unit according to claim 4 ,
Alarm unit which is a part of the connection pin connecting the socket part, characterized in Rukoto that Yusuke only mechanical connection functions. In the alarm unit according to any one of claims 1 to 5 ,
Alarm unit characterized that you supported by the main by the elastic support portions the beam member. The alarm unit according to claim 6,
Alarm unit wherein the elastic body, wherein the grommet der Rukoto. The alarm unit according to claim 6 ,
Alarm unit wherein the elastic body, wherein an elastic body der Rukoto planar. In the alarm unit according to any one of claims 1 to 8,
The alarm unit is characterized in that a chamfered portion is formed at an end portion of the main body of the alarm unit to facilitate storage in a pocket or other bag body. In the alarm unit according to any one of claims 1 to 9,
An alarm unit, comprising: an instruction unit that informs a user of an arrangement position of the alarm unit. In the alarm unit according to any one of claims 1 to 10,
The dosimeter is
A radiation detection unit that transmits a detection signal in response to detection of radiation;
An output unit for audio output and / or display;
A dosimeter drive control unit that performs calculation processing based on the detection signal of the radiation detection unit, calculates radiation dose data, and transmits an output signal that causes the output unit to output sound and / or display based on the radiation dose data When,
An alarm unit characterized in that the dosimeter drive control unit outputs an output signal to the output unit and also outputs a control signal to the alarm unit drive control unit of the alarm unit.

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