JP2007109483A - Voltage indicator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a voltage indicator which can promptly grasp the condition of a power source in a state of the load being connected at measurement, by equipping an electrical source plug of a detector with a light emission means to emit light, according to the voltage of an input alternating power source. <P>SOLUTION: The voltage indicator 100 is provided with a power source input terminal 3 that connects to an alternating power source terminal; a resistor Ra for suppressing the alternating voltage inputted from the power source 3; a diode bridge (DB) for full-wave rectifying the alternating voltage inputted through the resistor Ra; a resistor Rb for suppressing a direct current generated by the DB; a Zener circuit group 5, which goes into a conducting state when the direct current generated by the DB exceeds a predetermined voltage value; an LED group 4 which emits light by the electrical conduction of the Zener circuit group 5 with the direct current voltage as a power source; a plug body 2 holding the power source input terminal 3, the DB, the Zener circuit group 5, and the LED group 4; and a power source cable 1. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a voltage indicator, and more particularly to a voltage indicator that can visually confirm whether or not the voltage value of an AC power supply is a specified voltage value.

At construction sites such as buildings and factories, construction work for structures and wiring work related to electricity are performed in parallel. In wiring work, it is necessary not only to inspect after completion of construction, but also to inspect the electrical operating state as appropriate during construction. In other words, for example, if a wiring mistake, leakage, or insufficient withstand voltage occurs after the completion of construction, in the worst case, the construction completion part of the structure must be broken and wiring must be performed again. This leads to an increase in construction costs. In order to prevent such a situation in advance, wiring inspection and completion inspection during construction with an inspection tool are indispensable.
By the way, since a motor or electric tool is used at the construction site, a temporary power source is prepared as a power source for that purpose, but unlike a regular commercial power source, the temporary power source has sufficient power capacity In addition, there is a possibility that the usage conditions may be further deteriorated when the cable is used by extending from one place with a leg wire. As a result, when the power supply of the inspection instrument is supplied from the temporary power supply, there is a problem that the inspection instrument malfunctions due to fluctuations in the power supply voltage and the reliability of the inspection is lowered. Although it is sufficient to check, no such device has been proposed so far.
In Patent Document 1, as a conventional technique, a power supply unit and a display unit are coupled by a DC output side connector and a display unit side connector, and the DC bus line of the display unit and the DC output bus line of the power supply unit can be connected with one touch. The DC bus line on the display unit side is provided with an output current detection resistor and a load is connected to the DC output terminal so that the output status of the output current, output voltage, etc. A power supply device that performs detection and display using a line is disclosed.
In Patent Document 2, in order to prevent the power plug in the live line from being accidentally pulled out, the plug is provided with an LED, and when the LED is lit, the operator is informed visually that the system is operating. The technology is disclosed.
JP 2004-159396 A JP-A-5-290932

As described above, since the power supply conditions of the conventional temporary power supply are not always good, the inspection device malfunctions at the time of wiring inspection or construction inspection by the inspection tool using the temporary power supply, and accurate data cannot be secured. There's a problem. In addition, in order to solve such problems, when measuring the voltage of the temporary power supply in advance with a tester or a measuring instrument, there is a problem that the measurement is troublesome and the measuring instrument must be carried around. is there.
In addition, the prior art disclosed in Patent Document 1 is provided for each power supply unit in order to check the margin of the power supply device when starting up or adding a power supply device including a plurality of power supply units. Connected to the display unit. However, the display units must be arranged for each power supply unit, which is expensive in cost and increases the size of the device.
Further, the conventional technique disclosed in Patent Document 2 requires a plug to be provided with a display LED, so that the plug becomes special, and extra wiring for lighting the LED from the system side is also necessary. There is a problem of lack of sex.
The present invention can immediately grasp the power state of the temporary power supply when power is supplied from the temporary power supply to the inspection instrument by providing a light-emitting means that emits light according to the voltage of the input AC power supply in the power supply plug of the inspection instrument. An object of the present invention is to provide a voltage indicator that can
Another object is to make it possible to use a general-purpose power plug by providing the adapter with an outlet for connecting a light emitting means that emits light according to the voltage of the input AC power supply and the power plug of the inspection instrument.
Another object is to protect the inspection instrument from the abnormal voltage by further providing the adapter with a relay that detects the abnormal voltage and disconnects the outlet circuit.

In order to solve the problem, the present invention provides a voltage indicator for displaying a level of an AC power source connected to the AC power source terminal, the power input terminal connected to the AC power source terminal, Rectifying means for rectifying an AC voltage input from the power input terminal, a Zener circuit that is energized when a DC voltage generated by the rectifying means exceeds a predetermined voltage value, and the DC voltage as a power source A light emitting means that emits light when the Zener circuit is energized, and a main body plug that holds the power input terminal, the rectifying means, the Zener circuit, and the light emitting means, and the Zener voltage of the Zener circuit is at the level of the AC voltage. Accordingly, the light emitting means is set to be turned on or off individually.
The plug of the present invention includes a light emitting means for display in the main body plug, and displays the voltage level by the light emitting means by inserting the plug into an AC power supply terminal. That is, the plug includes a power input terminal, a rectifying unit that rectifies alternating current to generate direct current, a light emitting unit that emits light using the generated direct current as a power source, and a Zener circuit in which a threshold is set to a predetermined alternating voltage. Has been. Therefore, for example, if the threshold is set to 100 V, the light emitting means emits light at 100 V or higher, and does not emit light at voltages lower than 100 V. Therefore, it can be visually confirmed that the voltage of the AC power supply terminal is 100 V or higher. .
According to a second aspect of the present invention, the light emitting means is formed of a light emitting diode, and is disposed at a position where the plug outer surface is visible.
Since the light emitting means is provided on the outer surface of the plug, it is preferable that the light emitting means is as small as possible and has high light emission efficiency. In that respect, light emitting diodes are optimal. The light emitting diode is disposed at a position where the plug is visible.
Claim 3 is a voltage indicator for displaying the level of the AC power supply connected to the AC power supply terminal, the power supply input terminal connected to the AC power supply terminal, and the AC voltage input from the power supply input terminal is rectified Rectifying means for conducting, a Zener circuit that is energized when the DC voltage generated by the rectifying means exceeds a predetermined voltage value, and light emitting means for emitting light when the Zener circuit is energized using the DC voltage as a power source And an outlet that outputs the AC voltage as it is, and a main body that holds the power input terminal, a rectifier, a Zener circuit, a light emitting unit, and an outlet, and the Zener voltage of the Zener circuit is a level of the AC voltage. The light emitting means is set to be turned on or off individually according to the above.
In the present invention, each component is provided in a main body (adapter) independent of a plug. In particular, the present invention is different from the first aspect in that an outlet is provided so that a plug can be inserted from the outside.

A voltage display for displaying the level of an AC power supply connected to the AC power supply terminal, the power input terminal connected to the AC power supply terminal, and the AC voltage input from the power supply input terminal is rectified Rectifying means for conducting, a Zener circuit that is energized when the DC voltage generated by the rectifying means exceeds a predetermined voltage value, and light emitting means for emitting light when the Zener circuit is energized using the DC voltage as a power source And a power source input terminal, a rectifying means, a Zener circuit, and a main body for holding the light emitting means, and the Zener voltage of the Zener circuit is turned on or off individually according to the level of the AC voltage. It is set to light.
In the present invention, the outlet is deleted from the main body (adapter) of claim 3. This is used for displaying in advance and confirming the state of the voltage of the AC power supply terminal to be used.
5. A voltage indicator for displaying a level of an AC power source connected to an AC power source terminal, wherein the AC power source input terminal is connected to the AC power source terminal, and an AC voltage input from the power source input terminal is rectified. Rectifying means, a Zener circuit that is energized when a DC voltage generated by the rectifying means exceeds a predetermined voltage value, and a light emitting means that emits light when the Zener circuit is energized using the DC voltage as a power source. An outlet that outputs the AC voltage as it is, a relay that connects or disconnects part or all of the outlet circuit, and a main body that holds the power input terminal, rectifier means, Zener circuit, light emitting means, outlet, and relay. And the Zener voltage of the Zener circuit is set so that the light emitting means is individually turned on or off according to the level of the input AC voltage. Together it is, an abnormal voltage exceeding significantly the predetermined voltage value is equal to or operating the relay when the event occurs.
The present invention prevents the tester from being damaged when the voltage indicator is erroneously inserted into a high voltage terminal of 200V or the like. In other words, a relay contact is inserted in series with the outlet circuit so that the relay does not operate when the voltage is normal, and the relay operates only when a high voltage is input, shutting off the outlet circuit. To do. Thereby, an inspection device can be protected from abnormal voltage.
According to a sixth aspect of the present invention, the light emitting means is formed of a light emitting diode and is disposed at a position where the main body portion is visible.
Since the light emitting means is provided in the plug, it is preferable that the light emitting means is as small as possible and has high light emission efficiency. In that respect, light emitting diodes are optimal. The light emitting diode is disposed at a visible position of the main body.

According to a seventh aspect of the present invention, a display unit that displays the voltage value of the AC voltage is provided in the vicinity of the light emitting unit.
Further, by displaying a voltage value in the vicinity of the light emitting means, it is possible to estimate how many volts the voltage at the AC input terminal is when the light emitting means emits light.
An eighth aspect of the present invention includes a display unit that displays a voltage level of the AC voltage in the vicinity of the light emitting unit.
Further, by displaying a voltage level (for example, high, medium, low, etc.) in the vicinity of the light emitting means, it is possible to estimate which level the voltage of the AC input terminal is when the light emitting means emits light.
According to a ninth aspect of the present invention, when a plurality of the light emitting means are provided, the low light emitting means for displaying the voltage value or voltage level of the light emitting means for emitting light is configured to emit light together with the light emitting means for emitting light. It is characterized by.
In order to reduce the circuit configuration, the circuit needs to be as simple as possible. Therefore, in the present invention, when there are a plurality of light emitting means, and there are light emitting means for displaying a voltage level lower than the voltage of the light emitting means that are lit, they are also turned on simultaneously. That is, when the light emitting means having the highest voltage is turned on, the light emitting means that is turned on at a lower voltage is also turned on at the same time.

According to the first aspect of the present invention, the main body plug is provided with the light emitting means for display, and the voltage level is displayed by the light emitting means by inserting the plug into the AC power supply terminal, so that a measuring instrument such as a tester is not required. The voltage status of the AC input power supply can be easily confirmed.
According to the second aspect of the present invention, since the light emitting means is formed of a light emitting diode and is disposed at a position where the plug can be visually recognized, the plug can be configured to be small and the display can be easily viewed.
According to the third aspect of the present invention, since each component is provided in the main body (adapter) independent from the plug, a general-purpose plug can be used as the plug of the inspector and the display can be easily seen.
According to the fourth aspect of the present invention, since the outlet is deleted from the main body (adapter), a more inexpensive voltage display can be configured.
Further, in claim 5, a relay contact is inserted in series in the outlet circuit so that the relay does not operate in the case of a normal voltage, and the relay operates only when a high voltage is input. Therefore, the tester can be protected from abnormal voltage.
According to the sixth aspect of the present invention, since the light emitting means is constituted by a light emitting diode and is disposed at a position where the main body portion can be visually recognized, the main body portion can be made compact and the display can be easily seen.
According to the seventh aspect of the present invention, since the display unit for displaying the voltage value of the AC voltage is provided in the vicinity of the light emitting means, it can be estimated how many volts the voltage of the AC input terminal is when the light emitting means emits light.
Further, since the display unit for displaying the voltage level of the AC voltage is provided in the vicinity of the light emitting means, it can be estimated which level the voltage of the AC input terminal is when the light emitting means emits light.
According to the ninth aspect of the present invention, when there are a plurality of light-emitting means, and there is a low-voltage light-emitting means that displays the voltage of the light-emitting means that is lit, the circuit configuration is such that these are also lit simultaneously. Is simplified and the cost is low.

Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings. However, the components, types, combinations, shapes, relative arrangements, and the like described in this embodiment are merely illustrative examples and not intended to limit the scope of the present invention only unless otherwise specified. .
FIG. 1 is an external configuration diagram of a voltage indicator according to a first embodiment of the present invention. The voltage display 100 includes a power input terminal 3 for connection to an AC power supply terminal (not shown), three LED groups (light emitting means) 4 that emit light based on the voltage of the AC power supply terminal, a main body plug 2, a power supply And a cable 1. Although not shown, the main body plug 2 includes a circuit that detects a voltage and emits light from the LED group 4 (details will be described later). In this way, the main body plug 2 is provided with the LED group 4 for display, and the voltage level is displayed by the LED group 4 by inserting the power input terminal 3 of the main body plug 2 into the AC power source terminal. In this example, three LEDs are provided as the LED group 4, the highest voltage is displayed as “H”, and then “M” the lowest voltage is displayed as “L”. The display level may be higher or lower than this. In addition, the display method may be displayed as a voltage value.
FIG. 2 is a diagram showing an internal circuit configuration of the voltage indicator according to the first embodiment of the present invention. The same components will be described with the same reference numerals as in FIG. The voltage display 100 includes a power supply input terminal 3 for connection to an AC power supply terminal, a resistor Ra for suppressing an AC current input from the power supply input terminal 3, and an AC voltage input via the resistor Ra. Diode bridge (DB) (rectifying means) for wave rectification, resistor Rb for suppressing DC current generated by DB, and circuit is energized when DC voltage generated by DB exceeds a predetermined voltage value Holding the Zener circuit group 5, the LED group (light emitting means) 4 that emits light when the Zener circuit group 5 is energized with a DC voltage as a power supply, and the power input terminal 3, DB, the Zener circuit group 5, and the LED group 4 A main body plug 2 and a power cable 1 are provided. In this example, the LED group 4 includes three LEDs H, M, and L, and the Zener circuit group 5 includes ZDh, ZDm, and ZDl corresponding to each LED.

Next, the schematic operation of this embodiment will be described. When the power input terminal 3 is inserted into the AC power supply terminal, the AC voltage is transmitted to the power cable 1 as it is. At the same time, the AC voltage is full-wave rectified by DB via the resistor Ra to become DC and is supplied to the LED group 4 via the resistor Rb. Here, as an example, it is assumed that ZDh is a Zener voltage that is energized at 100 V or more, ZDm is a Zener voltage that is energized at 95 V or more, and ZDl is a Zener voltage that is energized at 90 V or more. Assuming that the current AC voltage is 96 V, since ZDh is equal to or lower than the Zener voltage, no current flows through LED “H”, and therefore LED “H” does not emit light. However, since ZDm and ZDl are equal to or higher than the Zener voltage, the LEDs “M” and “L” emit light. Thereby, it can be confirmed that the voltage of the AC power supply terminal is at least 95 V or more.
FIG. 3A is an external configuration diagram of a voltage display according to the second embodiment of the present invention. FIG. 3B is a side view seen from the outlet side. The voltage indicator 110 includes a power input terminal 10 for connection to an AC power supply terminal (not shown), three LED groups (light emitting means) 11 that emit light based on the voltage of the AC power supply terminal, a main body 9, and an outlet. 8. In addition, although illustration is abbreviate | omitted, the circuit which detects a voltage in the main-body part 9 and light-emits LED group 11 is contained (it mentions later for details). In this way, the main body 9 is provided with the outlet 8 and the LED group 11 for display. By inserting the power input terminal 10 of the main body 9 into the AC power supply terminal, the LED group 11 displays the voltage level, and the outlet 8 The plug 6 of the inspection device is inserted into the insertion port 8a (see FIG. 3B). In this example, three LEDs are provided as the LED group 11, the highest voltage is displayed as “H”, and then “M” the lowest voltage is displayed as “L”. The display level may be higher or lower than this. For example, if one reference value is set, and whether the value is lower or higher than this reference value is displayed by one LED, the circuit configuration and device configuration can be simplified. In addition, the display method may be displayed as a voltage value.

FIG. 4 is a diagram showing an internal circuit configuration of a voltage indicator according to the second embodiment of the present invention. The same components will be described with the same reference numerals as in FIG. The voltage indicator 110 suppresses an AC current input from the power input terminal 10, a power input terminal 10 that is connected to the AC power terminal, an outlet 8 that directly outputs an AC voltage input from the power input terminal 10, and the power input terminal 10. A resistor Ra, a diode bridge (DB) (rectifying means) for full-wave rectification of an AC voltage input via the resistor Ra, a resistor Rb for suppressing a DC current generated by DB, and a DB A Zener circuit group 12 in which the circuit is energized when the DC voltage exceeds a predetermined voltage value, an LED group (light emitting means) 11 that emits light when the Zener circuit group 12 is energized using the DC voltage as a power source, A power source input terminal 10, a DB, a Zener circuit group 12, an LED group 11, and a main body plug 9 that holds the outlet 8 are configured. In this example, the LED group 11 includes three LEDs H, M, and L, and the Zener circuit group 12 includes ZDh, ZDm, and ZDl corresponding to each LED.
The schematic operation of this embodiment is the same as that of the first embodiment of FIG. The difference from the first embodiment of FIG. 2 is that an outlet 8 is provided instead of the power cable 1 and they are integrated into an adapter. Thereby, the voltage of the AC power supply terminal without load can be inspected by connecting to the AC power supply terminal without connecting the tester to the outlet 8, and the AC power supply with the tester connected to the outlet 8. By connecting to the terminal, the voltage of the AC power supply terminal under load can be inspected. In the present embodiment, the outlet 8 is provided and the tester can be connected. However, the outlet may not be provided and the voltage display may be provided with a function of only checking the voltage of the AC power supply terminal.

FIG. 5 is a diagram schematically showing the fluctuating voltage of the AC power supply terminal. The AC voltage is an alternating voltage 21 whose polarity varies with a predetermined period in the plus “+” direction and the minus “−” direction with respect to the reference line 22. If there is no voltage variation, the envelope 20 connecting the peak values of the alternating voltage 21 is constant, but if the voltage varies, the envelope 20 also varies as shown in FIG.
FIG. 6 is a diagram schematically showing a voltage obtained by full-wave rectifying the voltage of the AC power supply terminal of FIG. 5 with DB. In this figure, the fluctuation range is exaggerated for the sake of simplicity. Full-wave rectification converts all voltages in the plus “+” direction and the minus “−” direction of the alternating voltage into the plus “+” direction. As a result, as shown in FIG. 6, all the waves are in the plus “+” direction, that is, DC, and the envelope 25 is generated according to the fluctuation. For example, the voltage at point P in FIGS. 2 and 4 is the full-wave rectified voltage shown in FIG. Here, if the Zener voltages of the Zener diodes ZDh, ZDm, and ZDl are VH, VM, and VL, VH crosses the envelope 25 with C and D, VM crosses the envelope 25 with B and E, and VL is The envelope 25 is crossed by A, F, and G. As a result, the LED groups H, M, and L emit light at the “ON” timing in the figure.
FIG. 7 is a table showing the relationship between the LED group and the Zener voltage. A circle indicates lighting, and a cross indicates a light extinction. As can be seen from this figure, in the circuit configuration of this embodiment, when the Zener voltage is VH, the LED groups H, M, and L all emit light, and when the Zener voltage is VM, the LED group H is extinguished and M, L emits light, and when the Zener voltage is VL, the LED groups H and M are extinguished and L emits light. This state is apparent from the light emission timing in FIG. Note that the circuit configuration shown in the present embodiment is merely an example, and a circuit configuration in which only the LED corresponding to each voltage emits light may be used.

FIG. 8A is an external configuration diagram of a voltage indicator according to the third embodiment of the present invention. FIG. 8B is a side view seen from the outlet side. The voltage indicator 120 includes a power input terminal 31 for connection to an AC power supply terminal (not shown), four LED groups (light emitting means) 33 that emits light based on the voltage of the AC power supply terminal, a main body 30, and an outlet. 32. In addition, although illustration is abbreviate | omitted, the relay which connects / disconnects the circuit which detects the voltage in the main-body part 30, and light-emits the LED group 33, and the circuit of the outlet 32 is contained. Thus, the main body 30 includes the outlet 32, the LED group 33 for display, and a relay (not shown), and the LED group 33 displays the voltage level by inserting the power input terminal 31 of the main body 30 into the AC power supply terminal. At the same time, the plug 6 of the inspection device is inserted into the insertion port 32a (see FIG. 8B) of the outlet 32. In this example, the LED group 33 includes four LEDs, the highest voltage is displayed as “H”, the next “M” is the lowest voltage as “L”, and the abnormal voltage is displayed as “HH”. The display level may be higher or lower than this. In addition, the display method may be displayed as a voltage value.
FIG. 9 is a diagram showing an internal circuit configuration of a voltage indicator according to the third embodiment of the present invention. The same components will be described with the same reference numerals as in FIG. The voltage indicator 120 suppresses an AC current input from the power input terminal 31, a power input terminal 31 that connects to the AC power terminal, an outlet 32 that directly outputs an AC voltage input from the power input terminal 31, and the like. A resistor Ra, a diode bridge (DB) (rectifying means) for full-wave rectification of an AC voltage input via the resistor Ra, a resistor Rb for suppressing a DC current generated by DB, and a DB A Zener circuit group 34 in which the circuit is energized when the DC voltage exceeds a predetermined voltage value, an LED group (light emitting means) 33 that emits light when the Zener circuit group 34 is energized using the DC voltage as a power source, Relay RLHH for detecting abnormal voltage, power input terminal 31, DB, Zener circuit group 34, LED group 33, outlet 32, and relay RL And it is configured to include a body plug 30 for holding a H, a. In this example, the LED group 33 includes LEDs H, M, L, and HH, and the Zener circuit group 34 includes ZDh, ZDm, ZDl, and ZDhh corresponding to each LED. 4 differs from the second embodiment of FIG. 4 in that it includes a relay RLHH that detects an abnormal voltage, and in order to connect and disconnect a part of the circuit of the outlet 32, a contact hh of the relay RLHH is inserted in series with the circuit, It is that they are integrated into an adapter.

Next, the schematic operation of this embodiment will be described. When the power input terminal 31 is inserted into the AC power supply terminal, the AC voltage as it is is transmitted to the outlet 32. At the same time, the AC voltage is full-wave rectified by DB through the resistor Ra to become DC, and is supplied to the LED group 33 through the resistor Rb. Here, as an example, a Zener voltage that is energized when ZDh is 100 V or more, a Zener voltage that is energized when ZDm is 95 V or more, a Zener voltage that is energized when ZDl is 90 V or more, and a Zener voltage that is energized when ZDhh is 200 V or more. Suppose there is. Assuming that the current AC voltage is 96 V, since ZDh and ZDhh are below the Zener voltage, no current flows through the LEDs “H” and “HH”, so the LEDs “H” and “HH” do not emit light. . However, since ZDm and ZDl are equal to or higher than the Zener voltage, the LEDs “M” and “L” emit light. Thereby, it can be confirmed that the voltage of the AC power supply terminal is at least 95 V or more. In this state, since the relay RLHH is not operating, the contact hh remains connected. Here, if the operator accidentally inserts it into the 200V AC power supply terminal, ZDhh is equal to or higher than the Zener voltage, so that the LED “HH” emits light and the relay RLHH operates. As a result, the contact hh is opened, and the voltage supplied from the power input terminal 31 to the circuit of the outlet 32 is cut off. In this embodiment, the relay RLHH is set to 200 V, so that the other circuits have a withstand voltage that can withstand this voltage. In order to lower the withstand voltage, the operating voltage of the relay RLHH may be set near the withstand voltage of other circuits.
FIG. 10 is a diagram schematically showing a voltage envelope obtained by full-wave rectifying the voltage of the AC power supply terminal of FIG. 9 with DB. In this figure, the fluctuation range is exaggerated for the sake of simplicity. Here, if the Zener voltages of the Zener diodes ZDh, ZDm, ZDl, and ZDhh are VH, VM, VL, and VHH, respectively, VH crosses the tangent line 35 at B and C, and VM crosses the tangential line 35 at A and D. Crossing, VL crosses the envelope 35 at E and F, and VHH crosses the envelope 35 at G. As a result, the LED groups H, M, L, and HH emit light at the “ON” timing in the figure. Further, the relay RLHH operates simultaneously with the light emission of the LED group HH.

As described above, according to the present invention, the main body plug 2 includes the LED group 4 for display, and the voltage level is displayed by the LED group 4 by inserting the main body plug 2 into the AC power supply terminal. The voltage status of the AC input power supply can be easily confirmed without the need for a device.
Further, the LED group 4 is composed of light emitting diodes, and is disposed at a position where the main body plug 2 can be seen, so that the main body plug 2 can be made small and the display can be easily seen.
Moreover, since each component is provided in the main body part 9 independent of the main body plug 2, a general-purpose plug can be used as a plug for the inspector, and the display can be easily seen.
Moreover, since the outlet 8 is deleted from the main body 9, a more inexpensive voltage display can be configured.
In addition, a relay contact hh is inserted in series with the circuit of the outlet 32 so that the relay RLHH does not operate in the case of a normal voltage, and the relay RLHH operates only when a high voltage is input. Since the 32 circuits are cut off, the tester can be protected from abnormal voltage.
Moreover, since the LED groups 4, 11, and 33 are formed of light emitting diodes and are disposed at positions where the main body portions 2, 9, and 30 are visible, the main body portions 2, 9, and 30 can be configured in a small size, and The display can be configured to be easy to see.
Moreover, since the display part which displays the voltage value of an alternating voltage is provided in the vicinity of LED groups 4, 11, and 33, when LED groups 4, 11, and 33 light-emit, it is approximately what voltage the voltage of an alternating current input terminal is. I can guess.
Moreover, since the display part which displays the voltage level of an alternating voltage is provided in the vicinity of LED groups 4, 11, and 33, when LED groups 4, 11, and 33 light-emit, it is what level the voltage of an alternating current input terminal is. I can guess.
In addition, when a plurality of LEDs are arranged, if there is an LED having a voltage lower than the voltage of the LED that is lit, the circuit configuration is such that they are also lit at the same time, so the circuit is simplified and the cost is low. Become.

It is an external appearance block diagram of the voltage indicator which concerns on the 1st Embodiment of this invention. It is a figure which shows the internal circuit structure of the voltage indicator which concerns on the 1st Embodiment of this invention. It is an external appearance block diagram of the voltage indicator which concerns on the 2nd Embodiment of this invention. It is a figure which shows the internal circuit structure of the voltage indicator which concerns on the 2nd Embodiment of this invention. It is the figure which showed typically the voltage of the alternating current power supply terminal which fluctuates. It is the figure which showed typically the voltage which carried out the full wave rectification of the voltage of the alternating current power supply terminal of FIG. 5 by DB. It is the figure which tabulated the relationship between LED group and Zener voltage. It is an external appearance block diagram of the voltage indicator which concerns on the 3rd Embodiment of this invention. It is a figure which shows the internal circuit structure of the voltage indicator which concerns on the 3rd Embodiment of this invention. It is the figure which showed typically the envelope of the voltage which carried out the full wave rectification of the voltage of the alternating current power supply terminal of FIG. 9 by DB.

Explanation of symbols

  1 power cable, 2 body plug, 3 power input terminal, 4 LED group, 5 Zener circuit group, Ra, Rb resistor, DB diode bridge, 100 voltage indicator

Claims (9)

A voltage indicator that is connected to an AC power supply terminal and displays the level of the AC power supply,
A power supply input terminal connected to the AC power supply terminal, a rectifying means for rectifying the AC voltage input from the power supply input terminal, and an energized state when the DC voltage generated by the rectifying means exceeds a predetermined voltage value A Zener circuit, a light emitting means that emits light when the Zener circuit is energized with the DC voltage as a power supply, and a main body plug that holds the power input terminal, the rectifier means, the Zener circuit, and the light emitting means,
The voltage indicator, wherein the Zener voltage of the Zener circuit is set so that the light emitting means are individually turned on or off according to the level of the AC voltage.   2. The voltage display according to claim 1, wherein the light emitting means is formed of a light emitting diode and is disposed at a position where the outer surface of the plug is visible. A voltage indicator that is connected to an AC power supply terminal and displays the level of the AC power supply,
A power supply input terminal connected to the AC power supply terminal, a rectifying means for rectifying the AC voltage input from the power supply input terminal, and an energized state when the DC voltage generated by the rectifying means exceeds a predetermined voltage value A Zener circuit, a light emitting means that emits light when the Zener circuit is energized using the DC voltage as a power source, an outlet that outputs the AC voltage as it is, the power input terminal, a rectifier means, a Zener circuit, a light emitting means, A main body for holding the outlet,
The voltage indicator, wherein the Zener voltage of the Zener circuit is set so that the light emitting means are individually turned on or off according to the level of the AC voltage. A voltage indicator that is connected to an AC power supply terminal and displays the level of the AC power supply,
A power supply input terminal connected to the AC power supply terminal, a rectifying means for rectifying the AC voltage input from the power supply input terminal, and an energized state when the DC voltage generated by the rectifying means exceeds a predetermined voltage value A Zener circuit, a light emitting means that emits light when the Zener circuit is energized with the DC voltage as a power source, and a main body that holds the power input terminal, the rectifier means, the Zener circuit, and the light emitting means,
The voltage indicator, wherein the Zener voltage of the Zener circuit is set so that the light emitting means are individually turned on or off according to the level of the AC voltage. A voltage indicator that is connected to an AC power supply terminal and displays the level of the AC power supply,
A power input terminal connected to the AC power supply terminal, a rectifying means for rectifying the AC voltage input from the power input terminal, and an energized state when the DC voltage generated by the rectifying means exceeds a predetermined voltage value; A Zener circuit, a light emitting means that emits light when the Zener circuit is energized using the DC voltage as a power source, an outlet that outputs the AC voltage as it is, a relay that connects or disconnects part or all of the outlet circuit, A power input terminal, a rectifying means, a Zener circuit, a light emitting means, a main body for holding an outlet and a relay, and
The Zener voltage of the Zener circuit is set so that the light emitting means is individually turned on or off according to the level of the input AC voltage, and an abnormal voltage that greatly exceeds the predetermined voltage value is generated. A voltage indicator, wherein the relay is operated when the relay is operated.   The voltage indicator according to claim 3, 4 or 5, wherein the light emitting means is constituted by a light emitting diode, and is disposed at a position where the main body portion is visible.   The voltage indicator according to any one of claims 1 to 6, further comprising a display unit that displays a voltage value of the AC voltage in the vicinity of the light emitting means.   The voltage indicator according to any one of claims 1 to 6, further comprising a display unit that displays a voltage level of the AC voltage in the vicinity of the light emitting means.   When a plurality of the light emitting means are provided, the low light emitting means for displaying the voltage value or voltage level of the light emitting means for emitting light is configured to emit light together with the light emitting means for emitting light. Item 9. The voltage indicator according to any one of Items 1 to 8.

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