JP2012014937A - Static electricity remover - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display unit connection method in which a liquid crystal display unit is unlikely to break owing to static electricity cheaply for a portable static electricity remover.SOLUTION: A liquid crystal protection element is mounted on a printed board of extremely small size, the positions of an input electrode of the printed board and the liquid crystal display unit are adjusted to set the resistance that a high resistance body for relaxing a shock during an electrostatic discharge between the input electrode of the printed board and an input terminal of the liquid crystal display unit, and the amount of static electricity flowing into the liquid crystal is thereby adjusted to prevent the liquid crystal display unit from breaking.

Description

The present invention relates to a structure of a portable static eliminator.

When entering or leaving a room in an office or hotel where carpets are laid, you may be affected by static electricity or electric shock when you touch the door knob. This is especially the case during the winter dry season.

  This is because static electricity is charged to the human body due to friction between shoes, slippers and carpet when walking on the floor where the carpet is laid, and when touching a conductor such as a door knob, the human body moves to the door knob. This is an impact caused by the discharge of static electricity. It is known that electrostatic discharge is particularly metallic and is likely to occur when touching objects with a large surface area such as doors, door frames, window frames, etc. Generally, when a human body is charged to 2 kV or more, it feels that it will cause electric shock and electric shock. It has been.

  If static electricity discharges from a human body to a conductor such as a metal for a moment, it will cause electric shock and electric shock, so as a method of preventing electric shock and electric shock, a method of extending the electrostatic discharge time by using a high resistance body is adopted. Yes. The static eliminator adopting this conventional method has a configuration in which a high resistance of 1 mega ohm or more is coupled between the discharge electrode and the electrostatic input electrode. In addition to carbon resistance, cement resistance, enamel resistance, etc., which are usually used in electronic circuits, high resistance materials include resistance films that are printed by adding conductive materials such as carbon and metal powder to phenolic resins, etc., polyethylene, urethane In addition, a conductive resin made conductive by adding a conductive material to a resin material such as rubber, or a sponge resistor formed by foaming such a conductive resin is also used.

  In using this static eliminator, the static electricity input electrode of the static eliminator is held by hand, and the electrostatic discharge electrode is brought into contact with a metal such as a door knob. At this time, static electricity flows from the human body through the high resistance to the door knob, etc., but the static electricity slowly flows through the high resistance, so it does not feel squeaky or electric shock.

Here, when a liquid crystal display is connected in series with the high resistance, static electricity passes through the liquid crystal display and reaches the electrostatic discharge electrode, but the liquid crystal display has a structure having two electrodes in parallel. Therefore, a small amount of static electricity remains on the electrodes of the liquid crystal display. This small amount of static electricity causes the electrode of the liquid crystal display to withstand the electric charge, but the electrode in the liquid crystal display on the side connected to the electrostatic discharge electrode is grounded, so it is connected to the electrostatic input electrode side. An electric field is generated between the charged electrodes of the liquid crystal display. Since the liquid crystal molecules in the liquid crystal display are aligned along the electric field generated from the electrodes, the liquid crystal is turned on. In the lighting state, the static electricity charged on the electrodes in the liquid crystal display becomes an equilibrium state by moving between the electrodes through the internal resistance of the liquid crystal display or in the air, or the user is in the ground state And so on until the potential difference between the electrodes in the two liquid crystal displays reaches an equilibrium state.
Thus, when the liquid crystal display is in the display state, the user can know that the charge removal has been performed.
A protective element is connected in parallel to the liquid crystal display indicating that the charge has been removed in order to prevent destruction due to static electricity.
When a large amount of static electricity flows into the liquid crystal display, the protective element generates a spark discharge between the electrodes in the liquid crystal display, thereby destroying the liquid crystal display itself due to breakage of the electrodes, generation of bubbles due to heat, etc. In addition to surge absorbers such as varistors, arresters, and Zener diodes, silicon diodes can also be used. However, since the static electricity charged in the human body exists in both positive and negative directions, the protective element must also be bipolar. In addition, since it is a portable static eliminator, it needs to be small, and a large-volume element, radial lead or axial lead element is not suitable, and a small surface-mount type element is suitable.
The liquid crystal display is composed of a glass substrate, and a contact point with the outside is provided by a transparent electrode such as ITO formed on the glass. A means for connecting the transparent electrode on the glass and the protective element to the high resistance is required. Usually, as a method of connecting a liquid crystal display with an electronic circuit, it is a metal pin provided with a mechanism for fixing the glass, and is fixed to a glass substrate so as to be in contact with a portion where a transparent electrode is formed, A method of soldering pins to a printed circuit board on which electronic circuits are formed. A method of bringing an anisotropic conductive rubber having elasticity into contact between a transparent electrode of a liquid crystal display and an electrode on a printed circuit board. A method of bonding a flexible material cable such as FPC to a liquid crystal display by heat sealing or the like is known.

JP2005-243558 Patent registration No. 4331738

As a method of connecting a liquid crystal display used for a portable static eliminator, first, the pin connection method is raised. A liquid crystal display 1 shown in FIGS. 1 and 2 is connected to a printed circuit board 3 by soldering using pins 2, and a high resistor 4 for reducing an impact during electrostatic discharge is disposed on the printed circuit board 3. A liquid crystal protection element 5 is mounted.
In this system, since the liquid crystal display 1, the high resistance body 4, and the liquid crystal protection element 5 are connected by the print pattern, a stable connection can be obtained, and all the elements are fixed on the printed circuit board 3. There is an advantage that the assembly of the static eliminator body is improved. However, on the other hand, the cost of parts such as the pins 2 and the printed circuit board 3 for connecting the liquid crystal display 1 is expensive, and the manufacturing cost increases because of the cost of soldering. There was a problem.

As a method for suppressing the manufacturing cost, there is a liquid crystal display connecting method to which the method using the anisotropic conductive rubber is applied. Originally, anisotropic conductive rubber is sandwiched between the printed circuit board and the liquid crystal display, but instead of the anisotropic conductive rubber, the high resistance body 6 which is a component part of the portable static eliminator is used as it is. To do. FIG. 3 is a configuration diagram of a static eliminator in which the high resistance body 6 is substituted for the anisotropic conductive rubber, and FIG. 4 is a diagram of FIG. 3 viewed from the left side. In the liquid crystal display connection method using anisotropic conductive rubber, the contact partner is usually a printed circuit board, but the static electricity sent to the liquid crystal display 1 is from the electrostatic input electrode 7 connected to the high resistance body 6. Therefore, the liquid crystal protection element 5 is the only partner to be connected. Therefore, the printed circuit board is not used, and the terminals of the liquid crystal protection element 5 are brought into contact with each other by directly pressing the terminals against the high resistance body 6.
By adopting such a structure, a minimum configuration without using pins and a printed circuit board is obtained, and the high resistance body 6 can be manufactured at low cost because it can be manufactured by cutting off a ready-made high resistance material.

However, it has some problems. The first problem is that, unlike a configuration using a printed circuit board, all components are present without being fixed, and the liquid crystal protection element 5 is particularly difficult to handle because of its small size. For this reason, the assembly of the portable static eliminator main body is poor, and electrical contact is also uncertain compared to soldering.
The second problem is that the distance between the contact terminals 8 is narrow because the liquid crystal protective element 5 to be used is small. On the other hand, the transparent electrode 9 of the liquid crystal display 1 requires a certain contact with the high resistance body 6 and needs a certain area to prevent the transparent electrode 9 itself from being damaged by heat generated when static electricity flows. become. Therefore, when the liquid crystal display 1 and the liquid crystal protection element 5 are installed facing each other, the distance between the transparent electrodes 9 of the liquid crystal display 1 is wider than the distance between the input / output contact terminals 8 of the liquid crystal protection element 5. Then, since the resistance of the transparent electrode 9 of the liquid crystal display 1 is negligibly low as compared with the resistance of the high resistance body 6 that connects both, the transparent of the liquid crystal display 1 is viewed from the electrostatic input electrode 7. The resistance to the liquid crystal protection element 5 is generated by the resistance 10 of the high resistance body 6 existing between the end of the electrode 9 and the contact terminal 8 of the liquid crystal protection element 5. Then, the static electricity flowing through the liquid crystal protection element 1 is reduced and the protection function is weakened. Therefore, when strong static electricity is input, the liquid crystal display 1 may be destroyed.

  A liquid crystal display is provided so as to be exposed from a hollow case made of an insulating material, and an electrostatic input electrode and an electrostatic output electrode are arranged separately in the hollow case, and between the electrostatic input electrode and the input terminal of the liquid crystal display. In addition, a high resistance body for attenuating static electricity input from the static electricity input electrode is connected to the input terminal of the liquid crystal display, and an output is provided between the static electricity output electrode and the output terminal of the liquid crystal display. In addition, the static electricity removal tool is provided with a liquid crystal protection element connected to the static electricity input electrode and the static electricity output electrode on the printed circuit board. An electrostatic discharger for connecting an input electrode and an output electrode connected to a liquid crystal protection element provided on a printed circuit board to an input terminal and an output terminal of the liquid crystal display, wherein the liquid crystal storage device provided on the printed circuit board is provided. The input electrode connected to the element is extended so as to protrude to the electrostatic input electrode side so as to come into contact with the high resistance body first, as seen from the electrostatic input electrode than the input terminal of the liquid crystal display. Is used to propose a static eliminator in which a large amount of static electricity input from the static electricity input electrode flows to the liquid crystal protection element.

With the liquid crystal display connecting method according to the present invention, a portable static eliminator that is not destroyed by strong static electricity can be realized at low cost.

Liquid crystal connection method for portable static eliminator using pins and printed circuit board Side view of FIG. Liquid crystal connection method for portable static eliminator using high resistance instead of anisotropic conductive rubber 3 is a side view of the liquid crystal connection portion of FIG. 3 viewed from the left. Block diagram showing the whole of the present invention The figure which shifted the printed circuit board of FIG. 5 to the left, and put the printed pattern on the surface.

  The present invention will be described below with reference to the accompanying drawings. FIG. 5 is a block diagram showing an embodiment of the present invention. FIG. 6 is a diagram in which the printed circuit board hidden in FIG. 5 is shifted to the left. Reference numeral 11 is a hollow case 11 made of an insulating material. An electrostatic input electrode 12 and an electrostatic output electrode 13 made of a conductive material are separately attached to both ends of the case 11. In the hollow portion of the hollow case 11, a high resistance body 14, a liquid crystal display 15, and a conductor 16 are sequentially arranged in series between the static electricity input electrode 12 and the static electricity output electrode 13. This high resistance body 14 is a resistor for reducing the impact during discharge by lengthening the discharge time during electrostatic discharge. A liquid crystal display 15 for electrostatic discharge display is arranged. The liquid crystal display 15 has a structure that is visible from the outside by exposing the display surface from the case 11 or by using the case 11 itself as a transparent material. The conductor 16 is installed so as to connect the liquid crystal display 15 and the electrostatic output electrode 13. A printed circuit board 18 on which a liquid crystal protection element 17 is mounted is connected in parallel with the liquid crystal display 15.

  The hollow case 11 is formed of an insulating material such as a general-purpose resin. Specific examples of the versatile resin include polyethylene, polypropylene, polyamide, polystyrene, polyester, polyurethane, polycarbonate, polyvinyl chloride, polyepoxy, polyacrylonitrile, acrylonitrile-butadiene-styrene copolymer, acrylonitrile-styrene copolymer. And other thermoplastic resins or thermosetting resins. The hollow case 11 can be formed into any shape by a method such as injection molding or press molding of these resins.

The electrostatic input electrode 12 may be made of a conductive material such as metal, conductive resin, conductive rubber, conductive ceramic, or metal-plated resin. The volume resistivity may be 10 ¹⁰ ohm · cm or less. The shape of the electrostatic input electrode 12 may be arbitrary, but a key holder, a chain, or the like is attached to improve portability.

  The electrostatic output electrode 13 can be made of a conductive material such as a metal, a conductive resin, a conductive rubber, a conductive ceramic, or a metal-plated resin, like the electrostatic input electrode 12. Further, as the electrostatic output electrode 13, a stainless fiber web or felt, a metal-plated synthetic fiber woven or non-woven fabric, a synthetic fiber woven or non-woven fabric added with a conductive material such as carbon black, or a foamable conductive polyethylene resin. The same foaming conductive urethane resin can also be used. The shape of the electrostatic output electrode 13 is preferably a fibrous one because it preferably has a large surface area in order to facilitate discharge of static electricity, and more preferably has a sharp tip. Further, static electricity can be discharged into the air by partially exposing the electrostatic output electrode 13 arranged in the hollow case 11 to the outside of the case 11 or by providing a hole in the case 11 and circulating air. When the hole formed in the case 11 is in contact with or close to the electrostatic output electrode 13, it can be discharged faster. Further, static electricity can be released by simply bringing the electrostatic output electrode 13 exposed outside the case 11 into direct contact with a conductive object such as a metal door knob or a metal door frame, or by bringing the hole of the case 11 close.

  The high resistance body 14 is used to lengthen the electrostatic discharge time and reduce the impact during discharge. The resistance value is preferably a high resistance of about 5 MΩ to 1 GΩ, and the material is polyethylene, polypropylene, polyamide, polystyrene, polyester, polyurethane, polycarbonate, polyvinyl chloride, polyepoxy, polyacrylonitrile, acrylonitrile-butadiene-styrene. A material obtained by mixing a conductive material such as carbon or metal powder with a thermoplastic resin such as a copolymer, an acrylonitrile-styrene copolymer, butyl rubber, or silicon rubber, or a thermosetting resin can be used. However, since this high resistance body 14 needs to be in electrical stable contact with a transparent electrode formed on a hard glass surface, it needs to be a highly elastic material, and is rubbery or foamed. A sponge-like material is desirable.

The liquid crystal display 15 is a TN (Twisted Nematics) system, a reflection type, which operates when static elimination is performed, and displays characters, characters, etc. to notify the user of static elimination. Electrode terminals for inputting and outputting static electricity are made of a transparent conductive material such as ITO, and are formed by arranging input terminals 19 and output terminals 20 on a glass constituting a liquid crystal display. Each terminal is desirably large enough not to obstruct the external shape of the liquid crystal display in order to ensure electrical connection, but there is no problem if it has an area of about 2 square millimeters or more. The distance between the input terminal 19 and the output terminal 20 is preferably 1 mm or more in order to prevent static electricity from being discharged between the terminals.
As the liquid crystal protection element 17, a silicon diode or the like can be used in addition to a surge absorber such as a varistor, arrester, or Zener diode. However, since the static electricity charged in the human body exists in both positive and negative directions, the liquid crystal protection element 17 must also be bipolar. In addition, since it is a portable static eliminator, it needs to be small, and a large-volume element, radial lead or axial lead element is not suitable, and a small surface-mount type element is suitable. The liquid crystal protection element 17 is installed on the printed circuit board 18 by soldering.
The printed board 18 may be made of any material such as glass epoxy, paper epoxy, bakelite, alumina, and PET, but a material having hygroscopicity is not suitable because it leads to leakage of static electricity. In addition to pads for soldering the liquid crystal protection element 17, an input electrode 21 and an output electrode 22 for inputting static electricity are formed on the printed board 18 with copper foil. Although it is desirable to increase the size of each terminal in order to ensure electrical connection, there is no problem as long as it has an area of about 2 square millimeters or more. The interval between the input terminal 19 and the output terminal 20 of the liquid crystal display device 15 is preferably 1 mm or more in order to prevent static electricity from being discharged between the terminals. The printed circuit board 18 is installed so that the input terminal 19 output terminal 20 of the liquid crystal display 15 and the input electrode 21 output electrode 22 of the printed circuit board 18 face each other. At this time, the input electrode 21 of the printed circuit board 18 needs to extend outside the input terminal of the liquid crystal display 15. The printed pattern of the printed circuit board 18 is formed of copper foil, and the resistance value is close to 0Ω. Therefore, the static electricity input from the static electricity input electrode 12 reaches the liquid crystal protection element 17 instantaneously when it reaches the input electrode 21 of the printed circuit board 18, but at that time, the reference to the input terminal of the liquid crystal display 15 is referred to. There is a resistance corresponding to reference numeral 23, and the voltage rise is delayed.
Further, the amount of static electricity flowing through the liquid crystal display 15 and the liquid crystal protection element 17 can be adjusted by the positional relationship between the electrodes. The more the input electrode 21 of the printed circuit board 18 is located on the outer side than the input terminal 19 of the liquid crystal display 15, the more static electricity flows through the liquid crystal protection element 17, and the load on the liquid crystal is reduced. However, if an extremely long distance is set, the static electricity flowing in the liquid crystal becomes too small, and it becomes difficult to turn on the liquid crystal or the time for displaying the liquid crystal becomes short. On the contrary, by shortening the distance, static electricity flowing in the liquid crystal is increased, and the display time of the liquid crystal can be lengthened. The appropriate distance varies depending on the resistance value of the high resistor 14, the capacitance value of the liquid crystal display 15, the time to be displayed, and the like.
The conductor 16 electrically connects the liquid crystal display 15 and the electrostatic output electrode 13 and is made of a material having both conductivity and elasticity. The resistance value may be 1 GΩ or less, and may be low resistance. However, it is desirable that the resistance value is made of the same material as that of the high resistance element 14 in order to make the contact pressure of the electrode constant. The conductor 16 is installed so as to be sandwiched between the output terminal 20 of the liquid crystal display 15 and the output electrode 22 of the printed circuit board 18 and is in electrical contact with both, and at the same time, is electrically connected to the electrostatic output electrode 13. However, if the electrostatic output electrode 13 can contact the output electrode 22 of the printed circuit board 18, the conductor 16 does not need to be connected to the electrostatic output electrode 13.

  The operation of the portable static eliminator will be described. When static electricity is input from the static electricity input electrode 12, the static electricity flows through the high resistance body 14 connected in series to the input electrode 21 of the printed circuit board 18. The printed circuit board 18 is provided with a liquid crystal protection element 17. When static electricity exceeds a prescribed protection voltage of the liquid crystal protection element 17, the liquid crystal protection element 17 flows through the liquid crystal protection element 17, It passes through the body 16 and is discharged from the electrostatic output electrode 13 to the outside. At this time, since the static electricity passes through the high-resistance element 14, the discharge is not abrupt, and the user does not feel an impact during the discharge. Here, in addition to the printed circuit board 18, the liquid crystal display 15 is connected in parallel to the high resistance body 14. Static electricity reaches the liquid crystal display later than the liquid crystal protective element, but the liquid crystal protective element 17 has a time lag because it does not operate unless the voltage exceeds a specified voltage. Therefore, the liquid crystal display 15 also has a small amount of time. Static electricity flows. The liquid crystal display 15 is substantially an insulator, but when the electrostatic voltage exceeds the dielectric breakdown voltage of the liquid crystal display 15, static electricity flows through the liquid crystal display 15 and reaches the output terminal 20 of the liquid crystal display 15. It is emitted to the outside from the electrostatic output electrode 13 through the conductor 16. However, at this time, electrostatic charges remain between the electrodes of the liquid crystal due to the electrostatic capacity of the liquid crystal display 15, and the liquid crystal operates with a potential difference caused by the charges. Thereby, the liquid crystal display 15 is turned on, and the user recognizes that the charge removal has been performed.

1. 1. Liquid crystal display Pin 3. Printed circuit board 4. High resistance 5. Liquid crystal protective element 6. High resistance 7. Electrostatic input electrode 8. Contact terminal 9. Transparent electrode 10. Resistance 11. Case 12. Electrostatic input electrode 13. Electrostatic output electrode 14. High resistance 15. Liquid crystal display 16. Conductor 17. Liquid crystal protective element 18. Printed circuit board 19. Input terminal 20. Output terminal 21. Input electrode 22. Output electrode 23. Resistance

Claims (1)

  A liquid crystal display is provided so as to be exposed from a hollow case made of an insulating material, and an electrostatic input electrode and an electrostatic output electrode are arranged separately in the hollow case, and between the electrostatic input electrode and the input terminal of the liquid crystal display. In addition, a high resistance body for attenuating static electricity input from the static electricity input electrode is connected to the input terminal of the liquid crystal display, and an output is provided between the static electricity output electrode and the output terminal of the liquid crystal display. In addition, the static electricity removal tool is provided with a liquid crystal protection element connected to the static electricity input electrode and the static electricity output electrode on the printed circuit board. An electrostatic discharger for connecting an input electrode and an output electrode connected to a liquid crystal protection element provided on a printed circuit board to an input terminal and an output terminal of the liquid crystal display, wherein the liquid crystal storage device provided on the printed circuit board is provided. The input electrode connected to the element is extended so as to protrude to the electrostatic input electrode side so as to come into contact with the high resistance body first, as seen from the electrostatic input electrode than the input terminal of the liquid crystal display. A static eliminator characterized in that a large amount of static electricity input from the static electricity input electrode flows to the liquid crystal protection element.

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