1. Field of the Invention
The present invention relates to a sheet switch, a sensing mechanism having the sheet switch, and a card reader having the sensing mechanism.
2. Description of Related Art
Card readers which reproduce the data written on cards such as magnetic cards, IC cards, or the like or record data thereon are installed as subordinate devices in host devices, for example, ATM and the like. Popular card readers of this type include IC card readers which are constructed to prevent IC cards from various frauds (tampering activities) committed in an attempt to reproduce the data stored in the card for counterfeiting (i.e. See JP 2006-180244A).
In the IC card reader as described in JP 2006-180244A, when the IC card reader is removed from the host device and its secure board is physically attacked, the attack is sensed by the tamper-switch, and the key data in the secured board is deleted automatically.
In recent years, in order to prevent tampering, the PCI-PED or PCI-UPT standard based card readers have been demand by the market. In order to satisfy the PCI-PED or PCI-UPT standards, there is a clause requiring sensing of the removal of card readers from host devices.
However, conventionally, a sheet switch is known as a thin light weight switch used for operating parts of electric devices (i.e. See JP 2007-018887A). The sheet switch described in JP 2007-018887A comprises a resin surface sheet on which a contact electrode is mounted and a resin counter sheet on which a counter electrode facing the contact electrode is mounted.
As described above, in order to satisfy the PCT-PED or PCTI-UPT standards, the removal of the card reader from the host device must be sensed. And in order to enhance the security performance of the card reader, it is preferable that the removal of the card reader from the host device be sensed, even if a card reader is lifted only slightly from a host device.
In order to overcome the problem, the present inventors tried to apply the above-mentioned sheet switch to the sensing mechanism to detect the removal of the card reader from the host device. Specifically, the sheet switch was positioned in such a way that a card reader is fixed on the host device in the state in which the contact electrode the counter electrode are in contact with each other, and the contact electrode and the counter electrode separate when the card reader is removed from the host device.
Nevertheless, through the investigation by the inventors, it became clear that, under certain conditions, the conventional sheet switch used as is could not detect the removal of the card reader from the host device appropriately. Specifically, through the investigation by the inventors, it became clear that, particularly under high temperatures, due to creep deformation of the surface sheet or counter sheet, the contact electrode and the counter electrode stay in contact and do not separate when the card reader is removed from the host device.
For this reason, the object of the present invention is to provide a sheet switch which is suitable for the sensing mechanism for sensing the removal of the subordinate device from the host device. Moreover, the object of the present invention is to provide a card reader which comprises a sensing mechanism having the switch, and the sensing mechanism.
In order to overcome the problem, the sheet switch of the present invention is characterized in that it comprises a contact electrode formed in a dome shape with a conductive metal; a counter electrode disposed facing the contact electrode; and a metal sheet made of metal that is disposed on the opposite side of the counter electrode from the side facing the contact electrode with insulating members interposed therebetween wherein the contact electrode and the counter electrode come into contact with each other to become conductive.
In the sheet switch of the present invention, the contact electrode is formed in a dome shape with a conductive metal. In other words, the contact electrode is not mounted on a resin sheet. Therefore, creep deformation does not occur on the resin sheet on which the contact electrode is mounted. Moreover, since the contact electrode is formed with metal, the problem of creep deformation does not occur easily, even under high-temperature conditions.
Moreover, in the sheet switch of the present invention, a metal sheet is disposed on the opposite side of the counter electrode from the side facing the contact electrode with insulating members interposed therebetween. For this reason, even if the counter electrode is mounted (or formed) on a resin sheet, the sheet does not deform easily, and the pressure, generated by the contact between the contact electrode and the counter electrode, tends not to be concentrated on one part of this sheet. Therefore, creep deformation occurs with difficulty on the sheet on which the counter electrode is mounted.
As described above, in the present invention, the creep phenomenon generated on the counter electrode side can be prevented, and, at the same time, the creep phenomenon generated on the contact electrode side can be suppressed. Accordingly, with the sheet switch of the present invention for the sensing mechanism to detect the removal of the subordinate device from the host device, the contact electrode and the counter electrode can be prevented from generating the problem of coming into contact with each other and not separating. In other words, the sheet switch of the present invention is suitable for the sensing mechanism which senses the removal of the subordinate device from the host device.
In the present invention, It is preferable that the sheet switch be provided with an insulating surface sheet to cover the surface of the contact electrode and that the surface sheet be in contact with the contact electrode without being bonded thereto. In this case, for instance, the sheet switch comprises a cover sheet to cover the surface of the conductive pattern connected to the counter electrode, and a spacer interposed between the surface sheet and the cover sheet with an arrangement hole on which the contact electrode is mounted, wherein the surface sheet is bonded to the spacer.
With this configuration, the contact electrode is unlikely to be affected by the effects of creep deformation of the surface sheet, even if the surface sheet for protecting the contact electrode undergoes creep deformation. Accordingly, the contact electrode and the counter electrode can be prevented from generating the problem of coming into contact with each other and not separating without fail.
In the present invention, it is preferable that the contact electrode be formed with a metallic material comprising a spring member. With this configuration, by removing the pressing force against the contact electrode, the elastic recovery force of the contact electrode can separate the contact electrode from the counter electrode reliably.
In the present invention, it is preferable that the contact electrode and the metal sheet be formed from a stainless steel. With this configuration, the contact electrode tends not to undergo creep deformation. Moreover, since the stainless steel plate has a relatively large Young's modulus, with this configuration, permanent deformation occurs with difficulty on the metal sheet, even if the pressure is applied to the metal sheet when the contact electrode and the counter electrode are in contact with each other. Therefore, for example, even if the counter electrode is mounted on a resin sheet, the pressure generated by the contact between the contact electrode and the counter electrode can be spread over the resin sheet easily.
The sheet switch of the present invention can be used for the sensing mechanism equipped with a shock-absorbing member which is in contact with a metal sheet. In this sensing mechanism, the creep phenomenon generated on the contact electrode side can be prevented, and, at the same time, the creep phenomenon generated on the counter electrode side can be suppressed. Therefore, by using this sensing mechanism to sense the removal of the subordinate device from the host device, the contact electrode and the counter electrode can be prevented from generating the problem of coming into contact with each other and not separating.
Moreover, since this sensing mechanism is equipped with a shock-absorbing member which comes into contact with the metal sheet, even if the sheet switch is positioned in such a way that, for example, it protrudes outward from the mounting surface of the subordinate device, the sheet switch can be prevented from damages. For this reason, the sheet switch can be provided in the condition in which it protrudes outwards from the mounting surface of the subordinate device. Therefore, even if the contact sections of the host device vary in size, the contact sections can touch the sheet switch reliably, and enable the contact between the contact section and the sheet switch.
In the present invention, it is preferable that the sensing mechanism be equipped with a holding member to hold a shock-absorbing member and that the holding member be provided with a recessed arrangement section on which shock-absorbing member is mounted. With this configuration, the shock-absorbing member can be aligned easily, and the sensing mechanism can be assembled easily
In the present invention, it is preferable that the shock-absorbing member be equipped with a contact pressure receiving section, which is disposed at the position corresponding the contact point between the contact electrode and the counter electrode, and a notch section so that the entire perimeter of the outside circumference surface of the shock-absorbing member does not touch the wall surface of the recessed arrangement section. With this configuration, the stress applied to the contact pressure receiving section can be released by deforming the shock-absorbing member while the contact electrode and the counter electrode are in contact. Accordingly, the sheet on which the counter electrode is mounted is less subjected to excess stress; creep deformation of the sheet on which the counter electrode is mounted is easily prevented.
In the present invention, it is preferable that the shock-absorbing member be provided with a cross-shaped section formed substantially in a cross-shape around the contact receiving [sic, contact pressure-receiving] section, and that at least one end of the cross-shaped section be able to come into contact with the wall surface of the recessed arrangement section. With this configuration, the stress applied to the contact pressure-receiving section can be released, and the shock-absorbing members can be aligned easily.
In the sensing mechanism of the present invention, for example, in the state in which the subordinate device is attached to the host device, the contact electrode and the counter electrode come into contact with each other, and when the subordinate device is removed from the host device, the contact electrode and the counter electrode separate. This sensing mechanism can be used for the card reader which is attached to the host device in the state in which the contact electrode and the counter electrode are in contact with each other. Since this card reader can prevent the contact electrode and the counter electrode from generating the problem of coming into contact with each other and not separating, the removal of the card reader from the host device can be sensed reliably.
As described above, by using the sheet switch of the present invention for a sensing mechanism which senses the removal of the subordinate device from the host device, the contact electrode and the counter electrode can be prevented from generating the problem of coming into contact with each other and not separating. Moreover, by the use of the sensing mechanism of the present invention for sensing the removal of the subordinate device from the host device, the contact electrode and the counter electrode can be prevented from generating the problem of coming into contact with each other and not separating. Furthermore, because the card reader of the present invention can prevent the contact electrode and the counter electrode from generating the problem of coming into contact with each other and not separating, the removal of the card reader from the host device can be sensed reliably.
It is to be understood that the figures and descriptions of the present invention have been simplified to illustrate elements that are relevant for a clear understanding of the present invention, while eliminating, for purposes of clarity, many other elements which are conventional in this art. Those of ordinary skill in the art will recognize that other elements are desirable for implementing the present invention. However, because such elements are well known in the art, and because they do not facilitate a better understanding of the present invention, a discussion of such elements is not provided herein.
The present invention will now be described in detail on the basis of exemplary embodiments.
Schematic Configuration of the Card Reader:
Card reader 1 of this embodiment comprises, as illustrated in
Card 2 is, for example, a vinyl chloride card formed in a rectangular shape having a thickness of 0.7˜0.8 mm. The surface of this card 2 is provided with, for example, a magnetic stripe to record magnetic data. Moreover, for example, the surface of card 2 is provided with an IC chip fixed thereto. Further, card 2 may have a built-in communication antenna. Additionally, a printing section to undergo thermal printing may also be provided on the surface of card 2. Furthermore, card 2 may be a polyethyleneterefuthalate (PET) card having a thickness of about 0.18˜0.36 mm, or a paper card and the like having a given thickness.
Card insert-eject port 3 comprises exposed section 3a provided through the opening formed on front panel 6 of host device 5. Exposed section 3a is provided so that it protrudes from main body section 3b of card insert-eject section 3 pointing toward the front side of the sheet in
Both the right and left sides of exposed section 3a in
Card processing section 4 is equipped with a recording-reproducing means such as magnetic head, IC contact and/or communication antenna and the like, for recording or reproducing the data. Back of the body frame of card processing section 4 (the rear end of the sheet in
Further, card processing section 4 may or may not comprise a card transfer mechanism to transfer card 2 in card processing section 4. In other words, card reader 1 may be a self-propelled or it may be a manual card reader.
Configurations of Sensing Mechanism and Its Peripheral Components:
As illustrated in
As illustrated in
As illustrated in
This sheet switch 11 comprises, as illustrated in
Contact electrode 15 is formed with a conductive metallic material. Further, contact electrode 15 is formed with a metallic material comprising a spring member. Specifically, contact electrode 15 of this embodiment is formed from a thin stainless steel plate. Further, contact electrode 15 is formed in a dome shape. Specifically, contact electrode 15 is formed in a dome shape rounded toward the upper side in
One part of the lower end of contact electrode 15 in
Surface sheet 16 is formed into a thin sheet using an insulating material. Specifically, surface sheet is formed with a resin such as PET and the like. As illustrated in
Moreover surface sheet 16 is in contact with contact electrode 15 as illustrated in
Counter sheet 18 is formed into a thin sheet using an insulating material. Specifically, counter sheet 18 is formed with a resin such as PET and the like. Moreover, counter sheet 18 is formed into a long sheet elongated in the left-to-right direction in
Conductive pattern 17 is formed with, for example, a printed silver paste. Moreover, conductive pattern 17 is provided from the lower part of contact electrode 15 in
Cover sheet 19 is formed into a thin sheet with an insulating material. Specifically, cover sheet 19 is formed with a resin such as PET and the like. Moreover, cover sheet 19 is formed into a long sheet elongated in the left-to-right direction in
Insulating sheet 22 is also formed into a thin sheet with an insulating material in the same manner as cover sheet 19. Specifically, insulating sheet 22 is formed with a resin such as PET and the like. Moreover, insulating sheet 22 is made thicker than cover sheet 19.
In this embodiment, cover sheet 19 is formed into insulating sheet 22. As illustrated in
Metal sheet 20 is formed into a thin sheet. Metal sheet 20 of this embodiment is formed from a thin stainless steel plate. This metal sheet 20 is fixed on the back face of counter sheet 18 by the use of gummed sheet 25. Gummed sheet 25 is formed with an insulating material such as resins and the like. Moreover, metal sheet 20 is provided on almost the entire area of wide section 11a, and it constitutes a part of wide section 11a.
In sheet switch 11 thus configured, when contact electrode 15 is pressed from the upper side in
Furthermore, in this embodiment, two contact electrodes 15 are provided to wide section 11a, and the lower part of one contact electrode 15 accommodates a pair of counter electrodes 21. Therefore, sheet switch 11 may become conductive when one of these two contact electrodes 15 comes into contact with a pair of counter electrodes 21 disposed on the lower part of contact electrode 15, or it may become conductive when both of these two contact electrodes 15 come into contact with a pair of counter electrodes 21 disposed on the lower part of contact electrode 15. In other words, sheet switch 11 may become non-conductive when both of these two contact electrodes 15 separate from counter electrode 21 disposed on the lower part of contact electrode 15, or it may become non-conductive when one of these two contact electrodes 15 separates from counter electrode 21 disposed on the lower par of contact electrode 15.
Shock-absorbing member 12 is formed with, for example, rubber. Shock-absorbing member 12 of this embodiment is formed with rubber with little compression set and excellent heat resistance, cold resistance, as well as excellent weather resistance, ozone resistance and non-conductance. Shock-absorbing member 12, is formed with, for example, silicone rubber. As illustrated in
Furthermore, shock-absorbing member 12 comprises, as illustrated in
The upper end and both of the right and left ends of cross-shaped section 12a positioned on the upper side in
Sheet switch 11 is secured inside recessed mounting section 4a in such a way that metal sheet 20 comes into contact with shock-absorbing section 12 as illustrated in
As described above, card reader 1 is fixed on host device 5 in such a manner that the plane of the tip of contact projection 5a provided in host device 5 is in contact with mounting surface 4. In the state in which card reader 1 is fixed on host device 5, shock-absorbing member 12 contracts upward in
If card reader 1 is removed from host device 5 in this state, the pressing force applied to contact electrode 15 is eliminated, and the elastic recovery force of contact electrode 15 enables contact electrode 15 to separate from counter electrode 21, which causes sheet switch 11 to be non-conductive. In other words, the removal of card reader 1 from host device 5 is sensed when sheet switch 11 is in the non-conductive state.
Further, as described above, sheet switch 11 may become non-conductive when both of these two contact electrodes 15 separate from counter electrodes 21 provided on the lower part of contact electrode 15; or sheet switch 11 may become non-conductive when one of these two contact electrodes 15 separates from counter electrodes 21 provided on the lower part of contact electrode 15. In other words, the removal of card reader 1 from host device 5 may be sensed when both of these two contact electrodes 15 separate from counter electrodes 21 provided on the lower part of contact electrode, or the removal of card reader 1 from host device 5 may be sensed when one of these two contact electrodes 15 separates from counter electrode 21 provided on the lower part of contact electrode 15.
In the event that the removal of card reader 1 from host device 5 is sensed when both of these two contact electrodes 15 separate from counter electrodes 21 provided on the lower part of contact electrode 15, erroneous sensing made by sensing mechanism 7 can be prevented. Moreover, in the event that the removal of card reader 1 from host device 5 is sensed when one of these two contact electrodes separates from counter electrode 21 provided on the lower part of contact electrode 15, the failure of one of the contact electrodes 15 (and/or counter electrodes 21 provided on the lower part of contact electrode 15) will not affect sensing of the removal of card reader 1 from host device 5.
Major Effects of the Embodiment:
As described above, in this embodiment, contact electrode 15 is formed in a dome shape with a conductive metal. In other words, contact electrode 15 is not mounted on a sheet made of resin. For this reason, the problem of creep deformation the resin sheet on which contact electrode 15 is mounted is eliminated. Moreover, since contact electrode 15 is formed from a stainless steel plate, creep does not occur easily, even under high-temperature conditions.
Furthermore, in this embodiment, metal sheet 20 is provided on the back face of counter sheet 18. For this reason, the elastic recovery force of shock-absorbing member 12 generated when it contracts at the time card reader 1 is fixed on front panel 6, tends not to be concentrated on one part of resin counter sheet 18. As a result, creep occurs with difficulty on counter sheet 18. Particularly, since metal sheet 20 of this embodiment is formed with a stainless steel plate, even though the elastic recovery force generated in shock-absorbing member 12 is applied to metal sheet 20, it is difficult to deform metal sheet 20 permanently. Therefore, it becomes easier for the elastic recovery force generated by shock-absorbing member 12 to be transmitted to counter sheet 18 in a much dispersed manner.
Thus, in this embodiment, the creep phenomenon generated on the contact electrode 15 side can be prevented and, at the same time, the creep phenomenon generated on the counter electrode 21 side can be suppressed. Therefore, with sensing mechanism 7 of this embodiment, contact electrode 15 and counter electrode 21 can be prevented from generating the problem of coming into contact with each other and not separating. Accordingly, this embodiment can reliably sense the removal of card reader 1 from host device 5.
In this embodiment, contact electrode 15 is formed with a metallic material comprising a spring member. Therefore, by removing the pressing force against contact electrode 15, the elastic recovery force of contact electrode 15 can separate contact electrode 15 from counter electrode 21 reliably. In other words, the removal of the pressing force against contact electrode 15 can ensure the state in which contact electrode 15 and counter electrode 21 do not touch each other.
In this embodiment, surface sheet 16 is not bonded to contact electrode 15. Therefore, even if resin surface sheet 16 undergoes creep deformation, contact electrode 15 is unlikely to be affected by the effects of creep deformation of surface sheet 16. As a result, contact electrode 15 and counter electrode 21 are prevented from generating the problem in which they stay in contact and do not separate.
In this embodiment, sensing mechanism 7 is equipped with shock-absorbing member 12 which is in contact with metal sheet 20. Therefore, sheet switch 11 can be placed inside recessed mounting section 4a while protruding outward from mounting surface 4b without being damaged. Accordingly, even if contact projection 5a of host device 5 vary in size, contact projection 5a can touch sheet switch 11 reliably, and ensure the contact between contact electrode 15 and counter electrode 21.
In this embodiment, mounting surface 4b is provided with recessed arrangement section 4c, which accommodates shock-absorbing member 12. Further, the upper end and both of the right and left ends of cross-shaped section 12a, positioned on the upper side in
In this embodiment, shock-absorbing member 12 is formed by connecting one end to the other of each of two cross-shaped sections 12a. Shock-absorbing member 12 is provided with a notch section 12b so that the entire perimeter of the outside circumference surface of shock-absorbing member 12 does not touch wall surface 4d of recessed arrangement section 4c. For this reason, when shock-absorbing member 12 is placed inside recessed arrangement section 4c, the stress applied to contact pressure receiving section 12c can be released by deforming shock-absorbing member 12 while contact electrode 15 and counter electrode 21 are in contact. Accordingly, counter sheet 18 is less subjected to excess stress; creep deformation of counter sheet 18 is easily prevented.
Furthermore, in sensing mechanism 7 of this embodiment, if the plane at the tip of contact projection 5a is lifted 0.2 mm or more above mounting surface 4b (i.e. the plane at the tip of contact projection 5a is lifted from mounting surface by 0.2 mm or more), contact electrode 15 separates from counter electrode 21, and the removal of card reader 1 from host device 5 can be sensed. In other words, in this embodiment, the removal of card reader 1 from host device 5 can be sensed, even if card reader 1 is lifted only slightly from host device 5.
Moreover, in this embodiment, even if the variation range of the plane at the tip of contact projection 5a varies in the range of −0.2 mm˜+0.3 mm, for example, to design values, when card reader 1 is attached to host device 5, contact electrode 15 and counter electrode 21 are in secure contact; moreover, when card reader 1 is removed from host device 5, contact electrode 15 and counter electrode 21 can be separated without fail. In other words, with this embodiment, there can be a larger design tolerance for contact projection 5a.
Alternative Modes:
The above-described embodiment is one of the preferable embodiments of the present invention. However, the present invention is not limited to this, and can have any variations as long as the spirit of the present invention remains the same.
In the above-described embodiment, shock-absorbing member 12 is formed by connecting one end to the other of each of two cross-shaped sections 12a. However, shock-absorbing section 12 may have another shape as long as it comprises a contact pressure receiving section, which is provided to the position which corresponds to the contact position between contact electrode 15 and counter electrode 2, and a notch section so that the entire perimeter of the outside circumference surface of shock-absorbing member 12 does not touch wall surface 4d of recessed arrangement section 4c. Moreover, shock-absorbing member [12] may be formed in a shape of cylinder, polygonal cylinder, truncated cone, or polygonal truncated pyramid. In this case, this shock-absorbing member is provided at the position corresponding to the contact point between electrode 15 and counter electrode 21.
In the above-mentioned embodiment, as illustrated in
In the above-mentioned embodiment, sheet switch 11 is used for sensing mechanism 7 for sensing the removal of card reader 1 from host device 5. Alternatively, sheet switch 11 can be used for a sensing mechanism which is used for sensing the removal of for example, a subordinate device other than card reader 1 from the host device. Moreover, usually, sheet switch 11 may also be used for a sensing mechanism which senses a given state: Usually, the state in which contact electrode 15 and counter electrode 21 stay in contact, or on an as needed basis, the state in which contact electrode 15 and counter electrode 21 separate.
While this invention has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the invention as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the inventions as defined in the following claims.
Number | Date | Country | Kind |
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2008-273904 | Oct 2008 | JP | national |
The present application claims priority from PCT Patent Application No. PCT/JP2009/005479 filed on Oct. 20, 2009, which claims priority from Japanese Patent Application Nos. JP 2008-273904 filed on Oct. 24, 2008 the disclosures of which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/005479 | 10/20/2009 | WO | 00 | 5/6/2011 |