JP2013195154A - Ground line marker - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ground line marker capable of detecting static electricity discharged from a charged object in an assembly line, a manufacturing line, and the like and of displaying detection result for as long as required.SOLUTION: A ground line marker includes an input terminal 15 to be connected to a target object, an output terminal 17 to be connected to the ground side, and two display units 22 and 23 provided between the input terminal 15 and the output terminal 17. Each of the display units 22 and 23 includes: a front-face transparent electrode 24; a back-face electrode 25 provided on the back-face side facing the front-face transparent electrode 24 at a prescribed distance; and an electrophoretic material 26 which fills a space between the front-face transparent electrode 24 and the back-face electrode 25 and undergoes state inversion when current flows between the front-face transparent electrode 24 and the back-face electrode 25. The presence or absence of passage of static electricity through the ground line marker is recorded and displayed in the form of the state of the electrophoretic material 26, which is observed from the front-face transparent electrode 24 side.

Description

This invention is inserted in a ground wiring (earth wiring) for removing static electricity charged by an object, and detects whether or not the static electricity charged on the object is discharged to the ground via the ground wiring. It relates to the earth line marker for display.
The present invention also relates to an earth line marker that is inserted into an earth line for flowing a leakage current from the electrical equipment and detects and displays whether or not the leakage current flows.

For example, in an assembly line of a factory or the like, if static electricity is charged on an assembly target, it may lead to an explosion, a fire, a failure of an electronic device, a malfunction of the electronic device, or a discharge phenomenon that leads to destruction of the electronic device itself. The discharge of static electricity from a charged object is a transient event, and it is difficult to trace and reproduce the cause.
If it is possible to record the movement of charges that may cause the effect, it is possible to expect effects such as easier tracking and confirmation in an assembly process or an assembly operation in which static electricity occurs sporadically.

However, it has not yet been realized to record the causal movement of the electrostatic charge with a simple device.
Some electrical equipment can be connected to a so-called ground wire in order to allow leakage current to flow. However, even if the ground wire is connected, a leakage current is actually generated, and it cannot be confirmed whether or not it has flowed through the ground wire.

  On the other hand, a display device called “electronic paper”, which can hold (maintain) a display without a power source, has been put into practical use. A prior art of a charged state detection device using such an electronic paper display element is disclosed in Patent Document 1.

JP 2004-294273 A

The device disclosed in Patent Document 1 relates to a display device that visualizes a charged state of an object such as an electrical insulating sheet easily and accurately without fouling the object, and static electricity is discharged from the charged object. It is not a matter of detecting whether or not it has been recorded and holding it.
The present invention has been made based on such a background. When static electricity is discharged from a charged object in an assembly line, a production line, etc., it is detected and the display and display are maintained. The main purpose is to provide an earth line marker that is a new tool that can be used.

  The present invention also provides an earth line marker which can be inserted into an earth line connected to an electrical equipment device, and is a novel tool for detecting and displaying when there is a leakage from the electrical equipment equipment. For other purposes.

The invention according to claim 1 is an earth line marker for detecting and displaying that static electricity of an object has flowed to the ground, and is connected to the input side connected to the object side and to the ground side An output terminal and a display unit provided between the input terminal and the output terminal, the display unit having a predetermined distance from the front transparent electrode and the front transparent electrode. A back electrode provided opposite to the side, and an electric charge that is filled between the front transparent electrode and the back electrode, and performs state inversion in response to a current flowing between the front transparent electrode and the back electrode. The earth line marker is characterized in that it contains and displays whether or not static electricity has passed according to the state of the electrophoretic substance observed from the front transparent electrode side.
The invention according to claim 2 is an earth line marker applied to an earth line connected to an electrical equipment device, an input terminal connected to an upstream side of the earth line, and a downstream side of the earth line or a ground An output terminal connected to the input terminal, and a display unit provided between the input terminal and the output terminal. The display unit is transparent at the front surface with a predetermined interval from the front transparent electrode and the front transparent electrode. Reversing the state in response to a current flowing between the front transparent electrode and the back electrode, the back electrode provided opposite to the back side of the electrode and filled between the front transparent electrode and the back electrode And the presence or absence of passage of leakage current is stored and displayed according to the state of the electrophoretic substance observed from the front transparent electrode side. A scan line marker.
According to a third aspect of the present invention, the display unit includes two sets of display units including the front transparent electrode, the back electrode, and the electrophoretic substance, and the input terminal includes the front transparent electrode of one display unit and the other of the display unit. The display unit is electrically connected to a back electrode of the display unit, and the output terminal is electrically connected to a back electrode of one display unit and a front transparent electrode of the other display unit. Item 3. The earth line marker according to item 1 or 2.

  The invention according to claim 4 is provided in a closed loop circuit for connecting the front transparent electrode of the one display unit, the rear electrode of the other display unit, the front transparent electrode of the other display unit, and the rear electrode of the one display unit. The earth line marker according to claim 3, further comprising a normally closed switch for connecting a reset power source.

  According to the first aspect of the present invention, when static electricity charged on the object is discharged, static electricity flows from the input terminal connected to the object side to the display unit, and from the output terminal to the ground via the display unit. Flowing. When static electricity flows through the display unit, for example, charges move from the front transparent electrode to the back electrode. Along with the charge transfer, the electrophoretic substance filled between the two electrodes reverses its state, detects and displays that static electricity has flowed, and maintains the display.

Therefore, when observed from the front transparent electrode side of the display unit, for example, the white display becomes a black display, the black display becomes a white display, for example, due to the inversion state of the electrophoretic substance, and Since the display state is maintained, the presence or absence of the passage of static electricity can be confirmed after the passage of static electricity.
According to the second aspect of the present invention, when there is a leakage from the electrical equipment, the leakage current flows to the ground through the earth line. At that time, a leakage current flows from the input terminal connected to the upstream side of the earth line to the display unit, and flows from the output terminal to the ground via the display unit. When the leakage current flows through the display unit, for example, charges move from the front transparent electrode to the back electrode. Along with the charge transfer, the electrophoretic substance filled between both electrodes reverses its state, detects and displays that a leakage current has flowed, and maintains the display.

Therefore, when observed from the front transparent electrode side of the display unit, for example, the white display becomes a black display, the black display becomes a white display, for example, due to the inversion state of the electrophoretic substance, and Since the display state is maintained, the presence or absence of leakage current can be confirmed after the passage.
According to the third aspect of the present invention, the two sets of display units provided in the display unit are connected in parallel with the input terminal and the output terminal so as to have opposite polarities. For this reason, when static electricity or leakage current flows from the input terminal to the output terminal via the display unit, regardless of whether the polarity of the flowing static electricity or leakage current is + polarity or -polarity, Even if it is a case, it can be detected and displayed that static electricity or a leakage current flows. In addition, it can be displayed whether the flowing static electricity or leakage current is + polarity or -polarity.

  According to the fourth aspect of the present invention, the display on the display can be reset to the initial state by opening the normally closed contact provided in the closed loop circuit and applying the reset power supply thereto. That is, it is possible to reset the display on the display unit to the initial state by a simple operation, for example, by inserting a pin plug extending from the power source into the pin jack of the display.

FIG. 1 is a perspective view showing an external configuration of an earth line marker 10 according to an embodiment of the present invention, in which (A) is a perspective view of the earth line marker 10 viewed from one direction, and (B) is from the other direction. It is the perspective view of the earth line marker 10 seen. FIG. 2 is a schematic structural diagram for explaining the configuration and display principle of the earth line marker 10. FIG. 3 is a block diagram showing a display operation of the earth line marker 10. FIG. 4 is a diagram showing a processing procedure in which, for example, in one assembly station in the assembly line, the earth line marker 10 is used to detect and record the occurrence of electrostatic discharge in the assembly station. FIG. 5 is a perspective view showing an external configuration of an earth line marker 40 according to another embodiment of the present invention. FIG. 6 is a diagram for explaining an example of a connection mode in which the earth line marker 40 shown in FIG. 5 is connected to the ground wiring (earth line). FIG. 7 is an illustrative view showing a modification of the earth line marker 50 according to still another embodiment. FIG. 8 is a block diagram of the configuration when various earth line markers 50 (50A, 50B, 50C, 50D) as shown in FIG. 7 are applied to, for example, an assembly line or a production line. FIG. 9 is a view for explaining a modification of the display mode of the earth line marker according to the present invention. FIG. 10 is a diagram illustrating another display configuration of the display unit of the earth line marker. FIG. 11 is a view for explaining still another display mode of the display unit of the earth line marker according to the present invention. FIG. 12 shows an application example of the earth line marker according to the present invention. FIG. 13 is an illustrative view showing one example of a discharge goods.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing an external configuration of an earth line marker 10 according to an embodiment of the present invention, in which (A) is a perspective view of the earth line marker 10 viewed from one direction, and (B) is from the other direction. It is the perspective view of the earth line marker 10 seen. In FIG. 1B, the reset power supply device 11 is also shown.

  The earth line marker 10 includes, for example, a rectangular parallelepiped housing 12, and a pair of display windows 13 and 14 are formed on one surface 12 a of the housing 12. In addition, a pin jack 15 as an input terminal is provided on one side surface 12b of the housing 12, a lead wire 16 extends from the other side surface 12c of the housing 12, and a hook clip 17 as an output terminal is provided at the tip thereof. Is connected.

  When static electricity flows in from the pin jack 15 as an input terminal, passes through a display unit (details will be described later) in the housing 12, and flows out to a lead wire 16 and a mouth clip 17 as an output terminal, the display window 13 or The display on the display window 14 is switched from white to black, for example. More specifically, when a positively charged positive charge (+ charged static electricity) flows from the input terminal (pin jack) 15 to the output terminal (mouth clip) 17, the display in the display window 14 changes from white. Switch to black. In addition, when negatively charged negative charge (-charged static electricity) flows from the input terminal (pin jack) 15 to the output terminal (inlet clip) 17, the display color in the display window 13 switches from white to black. Change.

As described above, the earth line marker 10 selectively switches the display color of the display window 14 or 13 from white to black depending on whether the static electricity passing therethrough is positively charged static electricity or negatively charged static electricity. This is a device that can detect and display the passage of static electricity and the type (+ or-) of static electricity that has passed.
The display contents displayed on the display windows 13 and 14 are made by a pair of display units (described later) built in the housing 12. This display unit utilizes so-called electronic paper technology, and maintains the switched display state when the display content is switched (the state is reversed) due to the passage of static electricity.

  The resetting power supply device 11 is an instrument for resetting the display contents displayed in the display windows 13 and 14 to the initial state. The power supply device 11 is a power supply device in which a dry battery is built in a housing 18. A two-pole pin plug 20 as a reset key is connected to the ends of a pair of lead wires 19 extending from the housing 18. By inserting this pin plug (reset key) 20 into a reset pin jack 21 provided on the other side surface 12 c of the housing 12 of the earth line marker 10, the display contents of the display windows 13 and 14 can be reset.

FIG. 2 is a schematic structural diagram for explaining the configuration and display principle of the earth line marker 10. In FIG. 2, 12 is a housing, 13 and 14 are display windows, 15 is an input terminal, 16 is a lead wire, 17 is an output terminal, and 21 is a reset pin jack. Refer to FIG. 1 for specific configurations thereof. As described above.
The earth line marker 10 incorporates, for example, two sets of display units 22 and 23 in a housing 12. The display units 22 and 23 have a common configuration and are display elements based on so-called electronic paper technology.

  More specifically, the display unit 22 includes a front transparent electrode 24, a back electrode 25 provided to face the back side of the front transparent electrode 24 at a predetermined interval from the front transparent electrode 24, and a front transparent electrode. 24 and a plurality of electrophoresis microcapsules 26 filled between the back electrode 25 and the back electrode 25. In each microcapsule 26, positive (+) charged black fine particles 27 and negative (−) charged white fine particles 28 are mixed in a transparent solution 29. The solution 29 is confined in a spherical capsule 26 made of a transparent organic film.

  For this reason, when an electric field is applied between the front transparent electrode 24 and the back electrode 25 from the outside, the floating and sinking of the black fine particles 27 and the white fine particles 28 can be controlled. For example, when a positive potential is applied to the back electrode 25 and a negative potential is applied to the front transparent electrode 24, the black fine particles 27 are attracted to the front transparent electrode 24 side as shown in the left display unit 22 in FIG. The fine particles 28 are attracted to the back electrode 25 side and sink. This state is maintained even if the electric fields applied to the front transparent electrode 24 and the back electrode 25 are removed. For this reason, when the display content in the front transparent electrode 24 is viewed through the display window 13, a black display appears.

  The display unit 23 has the same configuration as the display unit 22. In FIG. 2, the display unit 23 shows a state in which a positive potential is applied to the front transparent electrode 24 and a negative potential is applied to the rear electrode 25. In this state, the white fine particles 28 are attracted to the front transparent electrode 24 side, and the black fine particles 27 are attracted to the rear electrode 25 side. Therefore, when the display is viewed through the display window 14, a white display appears.

For the two sets of display units 22 and 23 described above, an electrical connection structure is adopted so that static electricity flows as follows.
That is, static electricity input from the input terminal 15 is applied in parallel to the front transparent electrode 24 of the display unit 22 and the rear electrode 25 of the display unit 23. The static electricity applied to the front transparent electrode 24 of the display unit 22 is output from the rear electrode 25 of the display unit 22 to the output terminal 17 via the lead wire 16. Further, static electricity applied to the back electrode 25 of the display unit 23 flows from the lead wire 16 to the output terminal 17 through the front transparent electrode 24 of the display unit 23.

In this way, two sets of display units 22 and 23 are connected in parallel and with opposite polarities between the input terminal 15 and the output terminal 17.
Therefore, for example, when negatively charged static electricity flows through the earth line marker 10, the display of the display unit 22 viewed from the display window 13 is displayed in black. Conversely, when a positively charged static electricity flows through the earth line marker 10, the display of the display unit 23 visible from the display window 14 is displayed in black.

In this manner, the earth line marker 10 can detect and display that static electricity has flowed, and can also display whether the flowing static electricity is positively charged static electricity or negatively charged static electricity.
By the way, in the housing 12, the display unit 22 and the display unit 23 are electrically connected so as to form a closed loop. That is, the front transparent electrode 24 of the display unit 22 is connected to the back electrode 25 of the display unit 23, and the front transparent electrode 24 of the display unit 23 is connected to the back electrode 25 of the display unit 22. A normally closed contact 30 is interposed in the closed loop connection circuit. Then, by inserting a pin plug (reset key) 20 from the pin jack 21 into the normally closed contact 30, the normally closed contact 30 is opened, and potentials are respectively applied to the one contact 31 and the other contact 32 of the normally closed contact 30. Can be applied.

  For example, when a positive potential is applied to one contact 31 and a negative potential is applied to the other contact 32, both the display unit 22 and the display unit 23 are applied with a positive potential on the front transparent electrode 24 side. The display units 22 and 23 are both reset to the same display state (inverted state) as the right display unit 23 shown in FIG. That is, the display viewed from the display windows 13 and 14 is both reset to white display.

  FIG. 3 is a block diagram showing a display operation of the earth line marker 10. When the static electricity SE flows into the input terminal 15 of the earth line marker 10, the static electricity SE flows out from the output terminal 17 through the display unit 22 and the display unit 23 connected in parallel between the input terminal 15 and the output terminal 17. When the input static electricity SE is -charged static electricity, the display on the display unit 22 is switched from white to black. The display of the display unit 23 remains white.

On the other hand, when the static electricity SE flowing into the input terminal 15 is positively charged static electricity, the display on the display unit 22 remains white, but the display on the display unit 23 switches from white to black.
As described above, whether the display unit 22 is switched to black display or the display unit 23 is switched to black display indicates that static electricity has flowed, and the flowed static electricity is negatively charged. Or positively charged static electricity.

By applying the reset key 20 to the earth line marker 10, the display state of the display unit 22 and the display unit 23 can be reset to the initial state.
FIG. 4 is a diagram showing a processing procedure in which, for example, in one assembly station in the assembly line, the earth line marker 10 is used to detect and record the occurrence of electrostatic discharge in the assembly station.

Each assembly work station is in a state where static electricity can be discharged through the earth line, and an earth line marker 10 is inserted in the earth line.
Under normal conditions, the worker continues assembling work, and the static electricity is not discharged through the ground line. Therefore, the display of the ground line marker 10 is not switched to the normal display (for example, white display).

  However, when static electricity charged on the assembly object, static electricity charged on the worker's body, or the like is discharged, that is, when there is static charge transfer, an abnormality is generated. Whether or not an abnormality has occurred can be determined by whether or not the display of the earth line marker 10 has been switched. Therefore, when the operator notices that the display of the earth line marker 10 has been switched from, for example, a normal white display to a black display, the worker reports it to the supervisor (superior) while continuing the assembly work.

  Upon receiving the report, the superior confirms the contents of the earth line marker 10 and resets the display of the earth line marker 10 to the initial state. This reset can be easily performed using the reset power supply device 10 described above. In addition, the superior records the fact that there has been electrostatic discharge at the assembly station, and if there is an abnormality in the assembled product, the causal relationship can be confirmed.

By resetting, the display of the earth line marker 10 returns to the normal display, and the operation at the assembly station is continued.
FIG. 5 is a perspective view showing an external configuration of an earth line marker 40 according to another embodiment of the present invention. The earth line marker 40 has a simple configuration in which one display unit 41 is built, and when static electricity flows, the display on the display unit 41 switches from white display to black display, for example.

The earth line marker 40 is provided with a banana jack 43 as an input terminal provided on one side of the housing 42. A banana plug 44 as an output terminal protrudes from the other side surface of the housing 42.
In addition, the display part 41 is a display part using electronic paper technology similarly to the display units 22 and 23 mentioned above.

FIG. 6 is a diagram for explaining an example of a connection mode in which the earth line marker 40 shown in FIG. 5 is connected to the ground wiring (earth line).
The ground wiring (earth wiring) is configured as, for example, a ground wiring for discharging static electricity charged to the worker to the ground. Therefore, there are a wrist strap 45 worn by the operator on the wrist and a wrist strap cord 46 extending from the wrist strap 45, and a banana plug 47 provided at the tip of the wrist strap cord 46 is connected to the banana jack 43 of the earth line marker 40. Plugged into. The banana plug 44 of the earth line marker 40 is connected to a ground connection point connector 48.

FIG. 7 is an illustrative view showing a modification of the earth line marker 50 according to still another embodiment. As shown in FIG. 7A, the earth line marker 50 can be configured as an earth line marker 50A integrated with a wrist strap part worn by an operator.
Further, as shown in FIG. 7B, an earth line marker 50 can be configured to detect and display whether or not static electricity charged in the fixture has been discharged to the ground. In this case, the earth line marker 50 can be an earth line marker 50B incorporated in, for example, the front lower end of the fixture.

Further, as shown in FIG. 7C, the earth line marker 50 may be an earth line marker 50C incorporated so as to be inserted into the earth wire.
Moreover, as shown to FIG 7 (D), an earth line marker can also be used as an earth line marker applied to the earth line connected to an electrical equipment apparatus. In the case of this figure, the earth line marker is incorporated in the plug at the tip of the power supply cord provided for the electrical equipment. The power supply cord has a three-wire structure including two wires for power supply and one wire for grounding, and a plug at the tip is provided with a pair of power supply plug pins and a grounding plug pin. The earth line marker 50D is inserted between a grounding line (earth line) and a grounding plug pin and integrated with the plug.

FIG. 8 shows a block diagram of the configuration when various earth line markers 50 (50A, 50B, 50C, 50D) as shown in FIG. 7 are applied to, for example, an assembly line or a production line.
As shown in FIG. 8, the ground line marker 50 is inserted into a ground wiring for removing static electricity charged on various objects in an assembly line or a production line, thereby charging any object. Whether or not is discharged to the ground potential can be detected and displayed. Moreover, the electric leakage from an electrical equipment apparatus can be detected and displayed by inserting in the earth line of the electrical equipment equipment of an assembly line or a manufacturing line.

  FIG. 9 is a view for explaining a modification of the display mode of the earth line marker according to the present invention. For example, instead of constituting the back electrode 25 with a single leaf electrode, a first back electrode 25a representing a specific shape (square (small) in the example shown), a symbol or a character, and a first back electrode 25 representing a background. The structure is divided into two back electrodes 25b (see FIGS. 9A and 9B). A path through which static electricity flows from the front transparent electrode 24 to the back electrode 25 is a path from the front transparent electrode 24 to the first back electrode 25a or a path from the front transparent electrode 24 to the second back electrode 25b. . Then, when static electricity flows through the display unit, only the display color of the microcapsule corresponding to the first back electrode 25a is switched, and only the symbol or character corresponding to the first back electrode 25a is displayed. can do. Alternatively, the display can be reversed and reversed.

Note that in the case where the display device has the structure illustrated in FIGS. 9A and 9B, the reset circuit may be as illustrated in FIG. 9C. That is, when a potential is applied between the terminals a and b with the switch c closed, the terminal a applies a potential to the first back electrode 25a and the second back electrode 25b, and the terminal b applies a potential to the surface electrode 24. Therefore, the display is reset to the initial state.
On the other hand, after the reset, by opening the switch c, static electricity applied to the display unit flows through the front transparent electrode 24 and the first back electrode 25a, and has a specific shape (not shown) corresponding to the first back electrode 25a. An example is a mechanism in which a square (small) may be used, but a symbol or a character may appear.

In the above description, in the reset state (initial state), a specific shape, symbol, character, or the like is not displayed on the display unit, and a specific shape, symbol, character, or the like is displayed when static electricity flows. Although described, the display can be reversed.
That is, in the initial state (reset state), a specific shape, symbol or character, for example, “square (small)” as a specific shape is displayed on the display unit. When static electricity flows, the entire display is displayed in black or white. Instead of this, the “square (small)” display may disappear.

  FIG. 10 is a diagram illustrating another display configuration of the display unit of the earth line marker. As shown in FIG. 10A, the back electrode 25 facing the back side of the front transparent electrode 24 may be a grid electrode arrangement in which a large number of back electrode elements are divided, for example, in a lattice shape. If static electricity flows selectively to a large number of back electrode elements having a grid electrode arrangement, any design can be displayed by passing static electricity between the front transparent electrode 24 and the back electrode 25. Can be configured. Alternatively, a state in which an arbitrary design is displayed can be a display mode in which the entire surface changes to black or white.

FIG. 11 is a view for explaining still another display mode of the display unit of the earth line marker according to the present invention.
Of the front transparent electrode and the back electrode provided in the display unit, for example, the back electrode is divided into five back electrode elements. Then, resistance values having different values are connected in series to the divided back electrode elements. If it carries out like this, the static electricity which flows from a front transparent electrode to a back electrode will show the tendency to flow in an order from the back electrode element with the small resistance value connected. Therefore, when the flowing static voltage is high, a current flows through many back electrode elements, and when the flowing static current voltage is low, a current flows only through the back electrode element having a small resistance.

For example, as shown in FIG. 11A, the back electrode is divided into five elements, and when 1000V, 100V, 50V, 30V, and 10V static electricity is applied, current flows through the back electrode elements in different combinations. In order to achieve this, as shown in FIG. 11B, five back electrode elements may be electrically connected, and different resistors may be connected in series to each.
In this way, as shown in FIG. 11C, for example, when static electricity having a voltage of 50 V or less flows, the areas corresponding to the three back electrode elements are reversed in display from the lowest resistance value.

As described above, the earth line marker 10 can be an earth line marker that can display the voltage of the flowing static electricity in an approximate range.
In the embodiments described with reference to FIGS. 9 to 11, the back electrode is divided into a plurality of electrode elements. However, the back electrode is a single leaf and the front transparent electrode is a plurality of electrode elements. The structure which divides | segments into may be sufficient.

  FIG. 12 shows an application example of the earth line marker according to the present invention. In FIG. 12, static electricity SE flows from the input terminal 15 of the earth line marker 10, passes through the two sets of display units 22 and 23, and flows out from the output terminal 17 to the ground potential G. At this time, a current sensor 61 for detecting static electricity passing through the display units 22 and 23 may be provided on the upstream side of the output terminal 17. Then, the current detected by the current sensor 61 is rectified by the rectifier 62 and amplified by the amplifier circuit 63 so that the flowing static electricity is automatically recorded by the recording device 64. It is good also as a structure transmitted to the general control apparatus of this. In this case, the amplifier circuit 63, the recording device 64, and the transmission device 65 are driven by the power supplied from the power supply circuit 66.

In the earth line marker according to the present invention described above, the display unit (display units 22, 23, display unit 41) has a front transparent electrode 24 and a back electrode 25, and an electrophoretic microcapsule is filled therebetween. Was described as an example.
However, the structure of the display unit is not limited to the one in which the electrophoretic microcapsule is filled between the front transparent electrode and the rear electrode, but the one in which gyricon view is filled, or cholesteric liquid crystal is used. A display unit using electronic paper technology that is currently in practical use, such as a filled one, may be used.

Furthermore, the earth line marker of the present invention can be applied to stations such as the assembly and manufacturing lines described above, as well as industrial electrical machine equipment and household electrical equipment (for example, electrical equipment such as washing machines and air conditioners). It can be used as an earth leakage detection / display device for electrical machinery and equipment by being inserted into the earth line.
It can also be used as a discharge goods. Discharge goods are tools to prevent unpleasant discharge stimuli from being felt on the fingertips, etc., when static electricity charged on the human body is discharged through the doorknob when touching the doorknob in winter. It is.

  As shown in FIG. 13, the discharge goods usually include a grip 71 and an objective contact 72 for touching a door knob or the like. The grip portion 71 and the objective contact 72 are connected with a material that is not highly conductive so that static electricity charged on the human body slowly flows from the grip portion 71 to the objective contact. The display unit 41 of the present invention is provided in the portion of the material 73 that is not highly conductive. With this configuration, when the discharge goods are used, it is possible to confirm whether or not static electricity has been discharged through the discharge goods on the display unit 41, and the discharge goods are more interesting.

  The present invention is not limited to the various embodiments described above, and various modifications can be made within the scope of the claims.

10, 40, 50 Ground line marker 11 Power supply device for reset 12 Housing 13, 14 Display window 15 Input terminal (pin jack)
17 Output terminal (Hip Clip)
20 Reset key (pin plug)
21 Reset Pin Jack 22, 23 Display Unit 24 Front Transparent Electrode 25 Back Electrode 26 Microcapsule 27 Black Fine Particles 28 White Fine Particles 29 Solution 30 Normally Closed Switch (Normally Closed Contact)
41 Display

Claims (4)

An earth line marker for detecting and displaying that static electricity of an object has flowed to the ground,
An input terminal connected to the object side;
An output terminal connected to the ground side;
A display unit provided between the input terminal and the output terminal,
The display unit
A front transparent electrode;
A back electrode provided to face the back side of the front transparent electrode at a predetermined interval from the front transparent electrode;
An electrophoretic substance that is filled between the front transparent electrode and the back electrode, and that performs state reversal in response to a current flowing between the front transparent electrode and the back electrode,
An earth line marker that stores and displays the presence or absence of passage of static electricity according to the state of the electrophoretic substance observed from the front transparent electrode side. An earth line marker applied to an earth line connected to electrical equipment,
An input terminal connected to the upstream side of the ground line;
An output terminal connected to the downstream side or ground side of the earth line;
A display unit provided between the input terminal and the output terminal,
The display unit
A front transparent electrode;
A back electrode provided to face the back side of the front transparent electrode at a predetermined interval from the front transparent electrode;
An electrophoretic substance that is filled between the front transparent electrode and the back electrode, and that performs state reversal in response to a current flowing between the front transparent electrode and the back electrode,
An earth line marker that memorizes and displays the presence or absence of leakage current depending on the state of the electrophoretic substance observed from the front transparent electrode side. The display unit has two sets of display units including the front transparent electrode, the back electrode, and the electrophoretic substance,
The input terminal is electrically connected to the front transparent electrode of one display unit and the rear electrode of the other display unit,
The earth line marker according to claim 1 or 2, wherein the output terminal is electrically connected to a back electrode of one display unit and a front transparent electrode of the other display unit.   A normal power supply for reset power supply provided in a closed loop circuit connecting the front transparent electrode of the one display unit, the rear electrode of the other display unit, the front transparent electrode of the other display unit, and the rear electrode of the one display unit. The earth line marker according to claim 3, further comprising a closed switch.

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