TW200937773A - Electronic functional card and card connecting device - Google Patents

Abstract

The present invention provides an electronic function card and a card connector mounted with the electronic function card. The card is a thin type electronic function card housed with a storage chip and the like, the shape of the cards are almost the same, and the card can easily identify the type of the internal electronic circuits. The housing (1) of a first card (C1) is in a zygomorphic rectangle shape clipping a central line (O-O). A guide identification slots (6, 6) is formed by retracting in the thickness midway from a surface (1a) at a right side section (1e) and a left side section (1f), and an intermediate dent (8, 8) is formed by retracting in the thickness midway from a surface (1a) at the rear side. The length dimensions (L1) of the guide identification slot (6, 6) are different from the categories of the internal circuit. Thus, in a guide identification slot, when the guide identification slot (6, 6) is used to guide, the type of the internal electronic circuits cam be identified by detecting the length of the guide identification slot (6, 6).

Description

[Technical Field] The present invention relates to an electronic function card in which an electronic circuit such as a memory chip is housed in a small and thin casing made of synthetic resin, and a card connector to which the electronic function card can be attached. [Prior Art] Q As described in the following patent documents, a digital camera, a digital camera, or a personal computer is used as a small and thin electronic function card in which a so-called memory card is mounted. This electronic function card is a small-sized and thin-sized case (sometimes referred to as a housing) formed of a synthetic resin material, and houses a memory chip or a 1C wafer having a function such as a memory controller. Next, a plurality of external connections that are conductive to the internal electronic circuit are provided on the surface of the card housing. Such an electronic function card has a small width dimension in order to attach it to the front side of the card connector, and a general shape is formed with a notched portion on the left side portion or the right side portion. The side portion of the card case is formed with a guide groove and a thin plate portion that can be guided when the connector is inserted, and is formed with a holding portion formed by a leaf spring or the like when the card connector is attached to the card connector. Keep the recesses. By the fitting of the holding recess and the holding portion, the card can be kept from being easily detached in the card connector. [Patent Document 1] Japanese Patent Laid-Open Publication No. JP-A-2002-208947 [Patent Document 3] JP-A-2007-165229A Problem] An electronic function card that has been used as a memory device or the like has a memory 'body wafer having a different memory capacity in a card case having the same shape and the same structure. Such a card has a number of memory capacities recorded on the surface thereof by printing or the like, and the user can recognize the difference by visual observation. However, since the shape of the card and the U structure are completely the same, the card is attached to the card connector. At the time of the device side, it is impossible to immediately recognize the difference in the capacity of the billion. In addition, in the future, the use of electronic function cards will have a tendency to require different internal electronic circuit driving voltages depending on the memory capacity or the internal circuit function. In this case, if the shape and structure of the card are completely the same, when the card connector is attached, the difference in the driving voltage cannot be recognized on the device side. Therefore, it is feared that an incorrect voltage is supplied and the internal circuit is damaged. Disadvantages. 〇 On the other hand, a card connector that has been used in common with cards having different internal circuit functions or different interface specifications, as shown in the above Patent Document 2, has a configuration in which cards of different shapes can be attached to the same connector. However, in order to allow cards of different functions and different shapes to be attached to a common card connector, it is impossible to prevent the inside of the card connector from being provided with a plurality of types of connection terminals, etc., resulting in complicated construction. Further, in the card connector, it is necessary to separately provide a holding mechanism that can correspond to each type of card, and thus it is difficult to constitute a small card connector. The present invention has been made to solve the above-mentioned problems of the prior art, and an object of the invention is to provide an outer shape and a structure of a casing -6-200937773 which are almost identical even if the internal electronic circuit specifications are different, and can be used in the same manner, and is attached to When the card connector is inside, it can recognize the electronic function card with different internal circuit specifications or different types. Furthermore, the present invention provides a card connector Φ capable of recognizing a difference in specifications or types of electronic circuits in a case when the electronic function card is attached. [Means for Solving the Problem] The first aspect of the present invention is An electronic function card comprising: a card housing and an electronic circuit housed inside the card case; and a plurality of external connection portions that are electrically connected to the electronic circuit to be exposed on a surface of the card body, wherein the card case has: a first end surface and a second surface facing each other in the thickness direction; a front end portion facing the insertion card connector; and a right side portion and a left side portion extending along the insertion direction, wherein the external connection portion is provided on the first surface And at least one of the right side portion and the left side portion of the surface of the second surface, wherein at least one of the right side portion and the left side portion is provided with a guide recognition groove extending from the front end portion toward the rear side from the first surface recessed to the thickness of the card case. The longitudinal length dimension of the guide identification groove is different depending on the type of the electronic circuit inside the card case. Preferably, an intermediate recess for retaining the card is formed at a position behind the guide identification groove, and the distance from the front end portion to the intermediate recess portion is constant regardless of the longitudinal length of the guide recognition groove. According to a second aspect of the present invention, an electronic function card has a first card and a second card, and the first card and the second card are provided with a card case and an electronic circuit housed inside the case of the card 200937773; The electronic circuit is a plurality of external connecting portions exposed on the surface of the casing, and each of the first card and the second card has a first surface and a second surface facing each other in a thickness direction; a front end portion facing the card connector direction; and a right side portion and a left side portion extending along the insertion direction, wherein the outer connecting portion is provided on at least one of the upper first surface and the second surface, and the right side At least one of φ and the left side portion is provided with a guide recognition groove extending from the ith surface to the thickness of the casing to extend rearward from the front end portion, and the first card and the second card are both The longitudinal lengths of the guide recognition grooves are different from each other. In addition, the first card and the second card have the same shape and structure as the first card, and the first card and the second card are both internal. The above electronic circuits are different. According to a second aspect of the present invention, the electronic function card may be configured such that the intermediate recessed portion for holding the card is formed at the rear of the guide recognition groove at the first card and the second card, and the front end The distance from the portion to the intermediate recess is constant. In the first aspect and the second aspect of the present invention, the basic shape, size, and structure of the cartridge are the same even if the types of electronic circuits housed in the casing are different. Then, only the length of the guide identification groove provided in front of the side of the card case varies depending on the internal circuit type. When the electronic function card is attached to the card connector, the guiding recognition slots of the respective cards can be guided by the common guiding portion in the card connector, and the electronic function card is attached to the detection through the detection of the length of the guiding recognition slot. When the card connector -8-200937773 is used, it is possible to detect the internal electronic circuit specifications or types, and it is possible to immediately perform appropriate control operations for each card. For example, the present invention is configured such that when the length of the pilot recognition groove is different, the driving voltage of the electronic circuit supplied to the inside is different. In this case, when the card is attached to the card connector, the voltage for the internal electronic circuit can be recognized as different, so that accidents caused by incorrect supply of different voltages can be prevented in advance. Further, in the present invention, when the length of the guide recognition groove is different, the memory capacity of the electronic circuit provided inside is different. The third aspect of the present invention is an electronic device to which any of the above-described electronic devices are attached. The card connector of the function card is characterized in that: the guide portion for guiding the identification recognition groove is provided; and the identification detecting means for detecting the length of the guide recognition groove is different. For example, when the electronic function card is attached to the normal position, the above-mentioned identification and detection mechanism performs different actions according to the position of the rear end of the guide identification slot. In the present invention, the card connector is provided with a connection terminal that can be in contact with an external connection portion provided on the electronic function card, and the control unit monitors the connection terminal, thereby recognizing that the electronic function card is attached to the normal position. Then, the operation state of the above-described identification detecting means is confirmed, whereby the type of the electronic function card to be attached can be determined. Through the above-mentioned discrimination process, it is possible to surely recognize the difference in the internal circuit of the card. -9- 200937773 In addition, the card is formed in the same basic shape and configuration, so that the structure of the guide portion or the connection terminal of the card connector is not complicated, and Use a card that handles multiple electronic circuits. [Effect of the Invention] The present invention is configured such that the basic structure or the size of the electronic function card is the same, but the specification or the type of the internal electronic circuit @ can be detected only when the length of the identification groove is different. Therefore, the card connector does not require a complicated mechanism for guiding the guide portion for guiding the groove. In addition, the card does not change the position of the intermediate recess even if the length of the guide recognition groove is different. Therefore, it is possible to separately hold cards having different internal circuit specifications or different types by using one holding portion provided in the connector. In addition, even if the internal circuit is different, since the size or configuration of the card case is the same, it is easy to use a card of a plurality of types that handle different driving voltages or capacities. [Embodiment] BEST MODE FOR CARRYING OUT THE INVENTION Fig. 1 is a perspective view showing the appearance of a card reader 20. Figs. 2 and 3 are perspective views of the card reader 20 with the cover removed. Fig. 4 is a front elevational view of the card reader 20 as seen from the front when the card is not attached. Fig. 5 is a plan view showing the card reader 20 with the cover removed, and Fig. 6 and Fig. 7 are plan views showing a state in which the first card is attached to the card reader 20 after the cover is removed, and section 10- 200937773 8 is a plan view showing a state in which a second card is attached, and FIG. 9 is a plan view showing a state in which a third card is attached. Fig. 10 is a partial perspective view showing the structure of the identification detecting means 70 for recognizing the first card and the second card, and Figs. 11(A) and (B) are enlarged side views showing the operation of the above-described identification detecting means 70. Fig. 12 is a view showing a card attached to the card reader 20 as shown below. Fig. 12 is a plan view of the first card C1, Fig. 13(A) is a left side view of the first card φ C1, and Fig. 14 is a perspective view showing the first card C1 as viewed obliquely from the lower side. Figure 15 is a plan view of the second card C2. _ (Shape of the first card) The first card C1 shown in Figs. 12 to 14 is used as a memory device such as a so-called multimedia card. The first card C1 has a plastic case 1 in which a memory chip such as a flash memory or a 1C chip having a memory controller function is housed. φ As shown in Fig. 13(A), the cartridge 1 has a first surface, i.e., a surface la, and a second surface, i.e., a back surface lb. The surface 1a and the back surface 1b are planes parallel to each other, and the interval between the surface 1a and the back surface 1b is the thickness dimension T of the first card C1. As shown in Fig. 14, a plurality of (13) external connecting portions 5 are exposed in front of the back surface 1b. The surface of the external connecting portion 5 is substantially flush with the back surface lb of the cartridge 1. Here, the "surface" and the "back surface" are for the purpose of distinguishing the names which are not used for the surface having the external connection portion 5, and the first card C1 is attached to the card reader 20 with the surface la up, or the back surface lb. Attached upwards on reading -11 - 200937773 card machine 2 0. As shown in Figs. 12 to 14, the card case 1 has a front end portion ic and a rear end portion 1d. Further, it has a right side portion 1 e and a left side portion 1 f. As shown in Fig. 13(A), the front end portion lc is a plane perpendicular to the surface la, and the front side inclined surface 2 is formed at the corner portions of the surface 1a and the back surface 1b. The rear end portion Id is a plane perpendicular to the surface 1a and the back surface 1b. The right side portion ie and the left side portion If are planes perpendicular to the surface 1a and the back surface 1b. As shown in Fig. 12, the boundary portion between the front end portion lc and the right side portion le and the boundary portion between the front end portion lc and the left side portion 1f, that is, the left and right side portions of the front end portion 1 C are formed with a frontal corner of a cylindrical surface. Surfaces 3, 3. a boundary portion between the rear end portion Id and the right side portion ie and a boundary portion between the rear end portion 1d and the left side portion 1f, that is, the left and right side portions of the rear end portion Id are also formed with a cylindrical corner portion of the rear corner curved surface 4, 4 . As shown in Fig. 12, in the plan view of the card casing 11 as seen from the surface la side, the shape of the card case 1 is a shape in which the center line extending forward and backward is symmetrical with respect to the left and right Q. The front portion of the cartridge 1 is formed with guide identification grooves 6, 6 which are recessed from the right side portion le and the left side portion If toward the center line 〇-〇. The guide recognition grooves 6, 6 have inner side faces 6&, 6& which are parallel to the right side portion 1e and the left side portion 1f and are located from the right side portion 1e and the left side portion If toward the center line 〇-〇 only by the distance W1. And the inner bottom surface 6 parallel to the back surface 11) <;,6 <;. Next, between the rear end portion of the right side guide recognition groove 6 and the right side portion 1 e and between the rear end portion of the left side guide recognition groove 6 and the left side portion 1 f are formed with inclined portions 6b and 6b, respectively. The inclined portions 6b, 6b are curved surfaces formed by the inclined portions 6b, 6b which are gradually separated from the center -12-200937773 by the center -12-〇 toward the rear, or have a curvature. The inclined portions 6b and 6b are step portions located at the rear end portions of the guide recognition grooves 6, 6 and have a function of an identification portion for allowing the identification detecting mechanism 70 provided in the card connector 20 to operate. As shown in Fig. 13(A), the guide recognition grooves 6, 6 are recessed from the surface la of the cartridge 1 toward the rear surface lb. The distance from the surface ia of the cartridge 1 to the inner bottom surface 6c of the guide groove 6, that is, the depth t1 from the surface la of the guide recognition grooves 6, 6 toward the back surface lb is the total thickness T of the first card C1. About 1/2. Further, as a result of the fact that the guide recognition grooves 6, 6 are recessed from the surface la, the thin plate portion 7, which is a portion sandwiched by the rear surface lb and the inner bottom surfaces 6c, 6c, is formed at a position closer to the back side than 7. The thickness dimension t2 of the thin plate portions 7, 7 is also approximately 1/2 of the total thickness T of the first card C1. The guide recognition grooves 6, 6 are opened toward the front Q at the left and right side portions of the front end portion lc. Therefore, as shown in Fig. 14, the thickness of the front end portion lc is almost T in the center, but the thickness is t2 on both sides. As shown in Fig. 12, the front and rear length dimension L1 of the guide recognition grooves 6, 6 means the distance from the front end portion 1c of the card case 1 to the rear end portions of the inclined portions 6b, 6b. The right side portion 1e and the left side portion 1f of the card case 1 are formed with the intermediate concave portions 8, 8 at a position at which the rear end portions of the guide recognition grooves 6, 6 are further separated by a distance L2. The longitudinal dimension L3 of the intermediate recesses 8, 8 in the longitudinal direction is shorter than the longitudinal dimension L1 of the front and rear guide grooves 6, 6. -13- 200937773 The intermediate recesses 8, 8 have inner ends 8a, 8a which are located closer to the center line 〇-〇 side than the right side portion 1e and the left side portion 1f, and which are parallel to the right side portion le and the left side portion If. The width dimension from the right side portion le to the inner side end 8a and the width dimension W2 from the left end portion If to the front inner end 8b are substantially the same as the width dimension W1 of the guide recognition grooves 6, 6. The intermediate recesses 8, 8 have a front inner end 8b and a rear inner end 8c, and the front and rear spaces between the front inner end 8b and the rear inner end 8c are the length ❹ dimension L3 of the intermediate recesses 8, 8. As shown in Figs. 13(A) and 14, the intermediate recesses 8, 8 have inner bottom ends 8d, 8d which are parallel to the back surface lb. The dimension from the surface la to the inner bottom ends 8d, 8d is the depth dimension t3 of the intermediate recesses 8, 8 which is larger than the depth dimension 11 of the guide recognition groove 6. When the first card C1 is attached to the card reader 20, the first card C1 is held in the reading by the holding portion 53 (see FIGS. 2 and 5) passing through the guide recognition grooves 6 and 6. The slider 41 of the card machine 20. As shown in Fig. 13(A), the guide recognition grooves 6, 6 and the intermediate recesses 8, 8 are all recessed from the surface la toward the rear surface lb to the middle of the thickness dimension T, and thus the retention in the identification grooves 6, 6 is guided. The portion 53 can be fitted to the intermediate recesses 8, 8 immediately after passing. Further, since the inclined portions 6b and 6b are formed at the rear end portions of the guide identification grooves 6, 6, the holding portions 53 are smoothly fitted into the intermediate concave portions 8 and 8 by the inclined portions 6b and 6b. Further, as shown in Fig. 13(A), the depth dimension t3 of the intermediate recesses 8, 8 is larger than the depth dimension t1 of the guide recognition grooves 6, 6, and 14-200937773 to enable the pass identification slot. The holding portions 53 in 6, 6 easily enter the intermediate recesses 8, 8. Therefore, the holding portion 53 can be surely fitted to the intermediate recesses 8 and 8, and the slider 41 capable of positioning the first card C1 in the card reader 20 can be formed at the rear end portion of the card housing 1 as shown in FIG. A finger recessed portion 9 recessed from the surface 1a is formed at a position slightly inside the 1 d. As shown in Fig. 1, when the first card C1 is attached to the card reader 20, the rear end portion having the above-described finger recess φ 9 protrudes from the card reader 20. When the hook recess 9 is hooked by the nail, the first card C1 can be taken out from the card reader 20. (Shape of the second card) Fig. 15 is a plan view showing the second card C2 and Fig. 12 in the same manner. The second card C2 has a card case 11 in which a memory chip or another 1C wafer or the like is housed. The guide recognition groove 16 formed in the card case 11 of the second card C2 is longer than the guide recognition groove 6 of the Q1 card C1, and the other shapes are the same, and the first card C1 and the second card C2 are completely identical. That is, the thickness dimension T and the width dimension W0 and the length dimension of the cartridge 11 of the second card C2 are the same as those of the first card C1. The shape, size, and position of the intermediate recesses 8, 8 formed in the second card C2 casing 11 are the same as those of the first card C1. In the other hand, in Fig. 15, the same portions as those of the card case 1 of the first card C1 are denoted by the same reference numerals and the detailed description thereof will be omitted. The second card C2 shown in Fig. 15 has guide identification grooves 16, 16 formed on the left and right sides of the front side. The guide identification grooves 16, 16 are formed with an inner side surface 16a at a position close to the center -15-200937773 line 0-0. The position of the inner side surface 16a, i.e., the width dimension W1 of the guide recognition grooves 16, 16 is the same as the width dimension W1 of the guide recognition grooves 6, 6 of the card case 1 shown in Fig. 12. Further, the dimensions from the surface la1 to the inner bottom surface 16c of the cartridge 11, that is, the depths of the guide recognition grooves 16, 16 are the same as the depth dimension tl of the guide recognition grooves 6, 6 of the cartridge 1 shown in Fig. 13(A) . The card case 11 of the second card C2 is provided with thin plate portions 17 and 17 at a position on the back side of the guide recognition grooves 6, 6, but the width and thickness of the thin plate portions 17, 17 are also the first card. The thin plate portions 7, 7 of C1 are the same. However, the length L11 of the guide recognition grooves 16, 16 and the thin plate portions 17, 17 shown in Fig. 15, that is, the distance L11 from the front end portion lc to the rear end of the inclined portion 16b is larger than that shown in Fig. 12. The length L1 of the guide identification grooves 6, 6 and the thin plate portions 7, 7 of 1 is also long. In other words, the inclined portions 16b and 16b which are the step portions having the function of the identification unit are located closer to the front side [(b) side] than the inclined portions 6b and 6b which are the identification portions of the first card C1. The length L3 of the intermediate recesses 8, 8 formed in the cartridge 11 of the second card C2 is the same as the length L3 of the intermediate recesses 8, 8 of the cartridge 1. Further, the length dimension li 1+L12 shown in Fig. 15 is the same as the length dimension L11+L12 shown in Fig. 12. That is, the distance from the front end portion lc of the card casing 11 to the front inner ends 8b, 8b of the intermediate recess portions 8, 8 shown in Fig. 15 is the same as the above-described distance from the card casing 1 shown in Fig. 12. The number, position, and shape of the external connection portions exposed on the back surface 1b of the card case 11 of the second card C2 are exactly the same as the external connection portions 5 exposed on the back surface 1b of the -16-200937773 card case 1 of the first card CM shown in Fig. 14. . The first card C1 and the second card C2 of the card reader 20' shown in Fig. 1 are attached in the same manner. As shown in Fig. 5, the card reader 20 is provided with a first connection terminal 55 to which the external connection portion 5 of the first card C1 and the external connection portion of the second card C2 are connected in common. However, the first card C1 and the second card C2 are because the lengths L1 and L11 of the guide recognition grooves 6, 16 and the thin plate portion 7' 17 are different, so the card reader φ machine 20 can detect the difference, thereby recognizing the package. The connected card is the first card C1 or the second card C2. The first card C1 and the second card C2 differ in specifications, for example, the driving voltages are different, that is, the voltages supplied to the card housing 1 through the external connection portion for the power supply are different. Further, depending on the above specifications, the memory capacity of the memory chips housed in the cartridges 1 and 1 may be different. Alternatively, either one of the first card C1 and the second card C2 has a memory chip having a large capacity, and is mainly used for data storage, and the other G is a read-only memory in which a specified program is built. , used for the purpose of controlling the program supply. As shown in Fig. 12 and Fig. 15, the card case 1 of the first card C1 and the card case 11 of the second card C2 have a bilaterally symmetrical shape with respect to the center line, and the entire planar shape is a rectangle. Therefore, the internal space of the cartridges 1, 11 can be effectively used in a wide range, and it can be made compact and thin, and the internal 1C wafer or other circuits can be integrated. Further, the guide recognition grooves 6, 16 and the intermediate recess 8 are formed to be depressed from the surface 1a side of the cartridges 1, 1 1 so that the surface -17-200937773 and the back surface of the card are easily discernible. Further, the guide recognition grooves 6, 16 are formed in the front and rear sides on the left and right side portions, and if, so that it is easy to distinguish the front and rear of the card case. Therefore, it is easy to prevent the first card C1 or the second card C2 from being erroneously inserted into the card reader 20. (Shape of the third card) As shown in Fig. 9, the card reader 20 can be attached to the third card C3 in addition to the first card C1 and the second card C2. In the third card C3, the overall width dimension W3 is smaller than the width dimension W0 of the first card C1 and the second card C2. The third card C3 has a notched portion 17 on the right side of the front portion, and the width dimension W4 of the front portion is formed smaller than the entire width dimension W3. Further, the right side portion is formed at a position closer to the front side [(b) side] than the above-described notch portion 17, and a recessed portion 18 penetrating the upper and lower sides of the card case is formed. The thickness of the third card C3 is smaller than the thickness T of the first card C1 and the second card C2. The third card C3 has the same shape as the so-called "Q microSD card", for example. As shown in Fig. 5, the card reader 20 is provided with a second connection terminal 58 for contacting the external connection portion of the third card C3, and for contacting the external connection portions of the first card C1 and the second card C2. The first connection terminal 55 described above. (Structure of Card Reader) Next, the structure of the card reader 20 to which the above various cards can be attached will be described. As shown in Figs. 1 and 4, the card reader 20 has a case (cassette -18 - 200937773) 21. The casing (chassis) 21 is composed of a synthetic resin body (case body) 22 and a cover 23 formed of a metal plate over the casing body 22. As shown in FIGS. 2 to 4, the casing body 22 has a frame shape. The casing body 22 is formed integrally with the front wall portion 24, the rear wall portion 25, the right wall portion 26, the left wall portion 27, and the bottom wall portion 28. The upper surface 24a of the front wall portion 24, the upper surface 25a of the rear wall portion 25, the upper surface 26a of the right wall portion 26, and the upper surface 27a of the left wall portion 027 are flush with each other. As shown in Figs. 1 and 4, the top plate 23a of the lid body 23 is provided so as to be in close contact with the respective upper faces 24a, 25a, 26a, and 27a of the casing body 22. The lid body 23 is provided with a rear side panel 23b and a right side panel 23c and a left side panel 23d which are formed to be bent at right angles from the top panel 23a. The rear side plate 23b is disposed outside the rear wall portion 25 of the casing body 22, and the right side plate 23c and the left side plate 23d are disposed outside the right wall portion 26 of the casing body 22 and the outside of the left wall portion 27, respectively. As shown in Fig. 4, the thickness of the casing 21 is determined by the height dimension from the lower surface 28a of the bottom wall portion 28 of the casing body ❹ 22 to the upper surface of the top plate 23a of the lid body 23. Further, the height dimension Ta of the storage area for card guiding storage is determined by the height dimension of the upper surface 28b of the bottom wall portion 28 of the casing body 22 to the lower surface of the top plate 23a of the lid body 23. The height dimension Ta is formed to be substantially the same as the thickness dimension T of the entire first card C1 and the second card C2 or slightly larger than the thickness dimension T. As shown in FIGS. 2 and 4, the inner surface of the left wall portion 27 of the casing body 22 is the guide reference surface 27b, and the first card C1 and the second card C2 are slid on the side of the guide frame. At the same time as the surface 27b, it is inserted toward the deep side [(a) side] of the casing 21 of -19-200937773. The front wall portion 24 of the casing body 22 is formed with a right guiding surface 24b. The right side portion le of the first card C1 and the second card C2 is guided along the right guide surface 24b. The distance between the guide reference surface 27b on the inner surface of the left wall portion 27 and the right guide surface 24b of the front wall portion 24 is the width dimension Wa of the storage region, and the width dimension Wa is formed to be the width of the first card C1 and the second card C2. The size W0 is substantially the same or slightly larger than the width dimension W0. φ As shown in Fig. 4, the insertion opening 29 of the opening area of the Tax Wa is opened at the front end of the casing 21, and the first card C1, the second card C2, and the third card C3 are inserted from the insertion port 29 toward the inside of the casing 21. insert. As shown in Figs. 2 and 4, the inside of the casing body 22 is provided with an upper guide wall 31 which is integrally formed with the left wall portion 27 and extends in the storage region. As shown in Fig. 4, the height dimension Tb from the upper surface 28b of the bottom wall portion 28 to the lower surface of the upper guide wall 31 is approximately the thickness t2 of the thin plate portion 7 of the first card C1 shown in Fig. 13(A). Same or slightly larger than the thickness 〇 dimension t2. Therefore, as shown in Fig. 2, when the first card C1 is inserted with the front end portion lc facing forward and the surface la facing upward, the thin plate portion 7 enters the upper guide wall 31, so that the first card C1 can be attached to The depth of the shell 21 is up. However, as shown in Fig. 3, when the first card C1 is inserted with the rear end portion id facing forward, or when the front and back sides are oppositely inserted, the case body 22 abuts against the upper guide wall 31, so that the first card C1 does not It will be inserted into the depth of the casing 21. This situation is also the same for the second card C2. As shown in Figs. 4 and 5, a control lifting member 32 is provided at a position closer to the front side than the upper guide wall 31 -20-200937773. As shown in Fig. 4, the regulating lifting member 32 is The notch portion formed in the bottom wall portion 28 protrudes upward, and the regulating elevating member 32 is spring-loaded into a protruding posture by a spring member (not shown). Further, the surface of the regulating elevating member 32 facing the insertion port 29 side is formed as an inclined surface 32a. The inclined surface 32a is formed in a shape that gradually rises above the bottom surface portion 28b of the bottom wall portion 28 as the side ([a) side] of the casing case 21 is deeper. U As shown in Fig. 5, the width dimension between the right side surface of the regulating elevating member 32 and the inner side surface 41a of the slider 4 1 is Wb. The width dimension Wb is set to be narrower than the width dimension W0 of the first card C1 and the second card C2 shown in FIGS. 12 and 15 , but the overall width dimension of the third card C3 shown in FIG. 9 is set. W3 is substantially the same or slightly wider than the width dimension W3. Therefore, as shown in Fig. 9, when the third card C3 is inserted from the insertion port 29, the third card C3 can pass through the depth of the inlet case 21 between the inner side surface 41a of the lift member 32 and the slider 41Q. At the office. Further, when the first card C1 or the second card C2 is inserted from the insertion port 29, the front inclined surface 2 and the back surface 1 b of the card slide onto the inclined surface 32a of the regulating elevating member 32, and the force is suppressed by the force at this time. Lifting member 32. Then, the first card C1 or the second card C2 is moved to the depth of the casing 21 through the controlled elevating member 32 that has been depressed. As shown in Fig. 2 and Fig. 5, the right side of the casing body 22 is formed with a guide portion 34 extending in the front-rear direction [(a) - (b) direction] on the upper surface 28b of the bottom wall portion 28. The guide portion 34 is a rail formed from the upper surface 28b - 21 - 200937773. A slider 41 is provided inside the right wall portion 26 of the casing body 22, and the slider 41 is supported to be linearly reciprocated in the front-rear direction along the guide portion 34. The left side portion of the slider 41 is formed with an inner side surface 4 1 a. The inner side surface 4 1 a is located at the same position as the right guide surface 24b formed on the front wall portion 24, and as shown in Fig. 5, the guide reference surface 27b formed on the left wall portion 27 and the inner side surface 4 1 a are formed. The width dimension between the two is Wa. Similarly to the right guiding surface φ 2 4b described above, the first card C1 and the second card C2 can be guided between the guiding reference surface 27b and the inner side surface 41a. Between the slider 41 and the housing body 22, a spring member such as a coil spring is provided. The slider 4 1 is pushed toward the front wall portion 24 to the front side [(b) side] between the slider 41 and the housing body 22, and is provided to lock the slider 41 to the deep side [(a ) The locking mechanism 35 of the side]. The locking mechanism 35 is constituted by a groove cam 42 formed on the upper surface of the slider 41 and an upper locking pin ❹ 36 provided on the casing 21. The upper end portion 36a and the front end portion 36b of the upper locking pin 36 are bent at right angles. As shown in Figs. 5 to 9, the base end portion 36a of the upper locking pin 36 is rotatably supported in the holding recessed portion 24c formed in the upper portion of the front wall portion 24 of the casing body 22. The front end portion 36b of the upper lock pin 36 is slidably inserted into the groove cam 42. As shown in Fig. 1, the top plate 23a of the lid body 23 formed of a metal plate is integrally formed with a lock leaf spring 37 on the right front side. The lock leaf spring 37 is a cantilever support spring formed by partial removal of the top plate 23a. The upper locking pin 36 is urged by the locking leaf spring 37 to push the front end portion 36b-22-200937773 toward the bottom of the groove of the groove cam 42. As shown in FIGS. 5 to 9, the groove cam 42 has a lock release portion 42a at the end portion of the deep side [(a) side]; and is located closer to the front side than the lock release portion 42a. The locking portion 42b of the [(b) side]. Between the lock release portion 42a and the lock portion 42b, a forward groove 42d is formed on the left side, and a bypass groove 42d is formed on the right side. Inside the grooved cam 42, a step is formed at a boundary portion between each of the lock releasing portion 42a, the forward groove 42c, the locking portion 42b, and the return groove φ 42d. The front end portion 36b of the upper lock pin 36 can slide only in the order of the lock release portion 42a - the forward groove 42c - the lock portion 42b - the return groove 42d - the lock release portion 42a, and the opposite stroke cannot be followed. In Fig. 5, the slider 41 is moved by the spring pushing member toward the front side [(b') side], and then touches the front wall portion 24 of the casing body 22. At this time, the front end portion 36b of the upper lock pin 36 is located in the lock release portion 42a of the groove cam 42. When the first card C1 or the second card C2 or the third card C3 is inserted from the insertion φ inlet 29, the slider 41 and the card are moved together toward the deep side [(a) side], as shown in Fig. 6, The front end portion 36b of the lock pin 36 passes through the path groove 42c of the groove cam 42. Then, as shown in Fig. 7, the front end portion 36b reaches the upper locking portion 42b of the groove cam 42, so that the slider 41 is placed thereon. The lock cannot be returned to the front side [(b) side] ° Then, when the card is pushed so that the slider 4 1 moves only toward the deep side [(a) side] with a short distance, the front end portion 3 of the upper lock pin 36 6b will be separated from the locking portion 42b of the grooved cam 42 and guided by the return groove 42d to release the locking of the slider 41. Therefore, the slider 41 is pushed back by the force of the spring pushing member back to the initial position shown in Fig. 5-23-200937773, during which the front end portion 36b of the upper locking pin 36 is returned from the return groove 42d. The lock release portion 42a. As shown in Figs. 2 and 5, the slider 41 has a concave portion 41b formed on the upper surface side [(a) side] closer to the inner side surface 41a. The front side of the recessed portion 41b is formed with a support pin 43 projecting upward, and the support pin 43 is formed of a synthetic resin material and integrally formed with the slider 41, and the identification arm 44 is rotatably supported by the support pin 43. Q As shown in Fig. 5, the base portion of the identification arm 44 is provided with an identification convex portion 44a which is integrally formed in the left direction. As shown in Fig. 4, the interval between the lower surface of the identification projection 44a and the upper surface 28b of the bottom wall portion 28 of the housing body 22 is Tb which is the same as the height dimension from the upper surface 28b to the lower surface of the upper guide wall 31. . As shown in Fig. 4, the identification arm 44 is formed with a sliding surface 44b on the lower side of the identification convex portion 44a. As shown in Fig. 5, when the identification arm 44 is rotated in the counterclockwise direction, as shown in Fig. 4, on the deep side of the insertion opening 29, the sliding surface 44b is opposed to the identification convex portion 44a. As shown in Fig. 2 and Fig. 6, when the first card C1 is inserted in the normal orientation toward the insertion opening 29, the right side thin plate portion 7 of the first card C1 enters the lower side of the identification convex portion 44a, and the thin plate portion The front corner curved surface 3 of the front end 7 abuts against the sliding surface 44b, so that the insertion force of the first card C1 causes the identification arm 44 to rotate in the clockwise direction. On the other hand, as shown in Fig. 9, when the third card C3 is inserted into the insertion port 29 with the normal orientation, the notched portion 17 on the right front side of the third card C3 is an identification convex which does not abut against the identification arm 44. Both the portion 44a and the sliding surface 44b pass through the left side thereof. Therefore, the identification -24-200937773 arm 44 does not rotate, and the third card C3 is attached to the left side. As shown in Fig. 5, the deep end portion of the slider 41 is integrally formed with a projecting reference stopper 45 at a position closer to the left side than the inner side surface 41a. As shown in Fig. 4, the reference stopper 45 has a surface facing the front side [(b) side] as the reference stopper surface 45a. As shown in Fig. 5, the deep end portion of the slider 41 is integrally formed with a stopper guide portion φ 46 extending in the left-right direction on the right side of the reference stopper portion 45. The stopper guide portion 46 supports the movable stopper portion 47 that is slidable in the left-right direction. A coupling pin 47a is integrally formed on the upper surface of the movable stopper portion 47. An elongated hole 44c is formed in the front portion of the identification arm 44, and the coupling pin 47a is slidably inserted into the long hole 44c. Therefore, on the slider 44, the movable stopper 47 can move in the left-right direction in accordance with the turning motion of the identification arm 44. As shown in Fig. 5, on the slider 44, a torsion spring 51 having a function of a rotary spring member is attached to the periphery of the support pin 43, and the identification arm 44 is biased in the counterclockwise direction by the torsion spring 51. As shown in Fig. 5, when the card is not attached, the identification arm 44 is rotated counterclockwise, and as it rotates, the movable stopper 47 moves in the left direction and then abuts against the reference stopper 45. The surface of the cymbal stop portion 47 that faces the insertion port 29 is the movable stop surface 48. As shown in Fig. 4, the movable stopper surface 48 has a left stopper portion 48a on the left side and a second stopper surface 48b on the right side. The first stopper surface 48a is formed at a position spaced apart from the upper surface 28b of the bottom wall portion 28 by a distance of Tb. Further, the second stopper surface 48b is formed at a position lower than the first stopper surface 48a. -25- 200937773 As shown in Fig. 5, the upper surface of the slider 41 on the front side [(b) side] is formed with a holding recess 41c in which a holding leaf spring 52 having a function of a holding member is provided. The holding leaf spring 52 is formed of a metal plate having a function of a leaf spring material. The curved portion is bent into a U-shape and embedded in the holding recess 41c. The free end of the holding leaf spring 52 is integrally formed with a holding portion 53 which is a specific sliding member. The inner side surface 4 1 a of 4 1 also protrudes from the left side of the figure. The portion where the crucible portion 5 3 is bent into a V shape 'the direction toward the front side [(b) side] is the inclined guide portion 5 3 a. The inclined guide portion 5 3 a is inclined in a direction away from the card toward the front side [(b) side]. The portion of the holding portion 53 that faces the depth side [(a) side] is a locking portion 53b which is formed in a direction substantially orthogonal to the front-rear direction. As shown in Fig. 4, the holding portion 53 protrudes from the inner side surface 41a of the slider 41 in the left direction, but the height dimension from the upper surface 28b of the bottom wall portion 28 of the case body 22 to the lower edge of the holding portion 53 is set. The above Tb is substantially the same as or slightly larger than Tb. As shown in FIGS. 3 and 5, the deep side [(a) side] of the casing body 22 is provided with a first connection terminal 55. The first connection terminal 55 is formed in the same number as the external connection portion 5 exposed on the back surface 1b of the first card C1 and the second card C2 as shown in Fig. 14 and arranged at the same pitch. On the deep side of the bottom of the casing body 22, a terminal support plate 57 is provided, and the terminal support plate 57 is formed with a plurality of small holes 57a penetrating vertically. As shown in Fig. 3, the first connection terminal 55 is bent upward to have a convex curved shape, and protrudes upward from the inside of the small hole 57a. The first connection terminal 55 is elastically deformable and can be retracted into the small hole 5 7 a after -26-200937773. Each of the first connection terminals 55 is continuously formed with a first external terminal 56 in a one-to-one relationship. As shown in Fig. 5, each of the first external terminals 56 protrudes rearward from the rear wall portion 25 of the casing body 22. The first connection terminal '55 and the first external terminal 56 are individually connected, and these are formed by electroplating a conductive metal plate having a low-resistance precious metal material such as gold. As shown in Figs. 3 and 5, the second connection terminal 58 is provided at a position closer to the insertion port 29 than the first connection terminal 55. The second connecting terminals 58 are the same number as the external connecting portions exposed under the third card C3 shown in Fig. 9, and are arranged at the same pitch. As shown in Fig. 3, the bottom of the casing body 22 is provided with a movable supporting plate 61 which is formed with a plurality of small holes 61a penetrating vertically. Each of the second connection terminals 58 is bent upward to have a convex curved shape, and protrudes upward from the small holes 61a. The movable support plate 61 is rotatably supported upward and downward by an axis provided on the front side [(b) side] of the second connection terminal 58. When the contact is made, the movable supporting plate 61 is lifted upward by the elastic force of the second connecting terminal 58. When the first card C1 and the second card C2 are inserted from the insertion port 29, the front inclined surface 2 of the first card C1 or the second card C2 slides on the movable support plate 61, and the first card C1 or the second card C2 is slid. The back side lb presses the movable support plate 61. When the movable supporting plate 61 is depressed and rotated downward, the movable supporting plate 61 depresses the second connecting terminal 58' to retract each of the second connecting terminals 58 to the inside of the small hole 61a of the movable supporting plate 61. Therefore, the external connection portion 5 provided on the back surface 1b of the first card C1 or the second card C2 does not contact the connection terminal 58 of the -27-200937773 2, but passes through the upper side of the second connection terminal 58 to the deep side. mobile. On the other hand, when the third card C3 shown in Fig. 9 is inserted from the insertion port 29, since the third card C3 is smaller than the thickness of the first card C1 or the second card C2, the movable supporting plate 61 and the When the connection terminal 58 is raised, the third card C3 is lifted, and the third card C3 is pushed to the lower surface of the top plate 23a of the lid body 23. Then, each of the second connection terminals 58 is electrically connected to an external connection portion provided on the back surface of the third card C3. As shown in Fig. 5, each of the second connection terminals 58 is formed with a second external terminal 59, and each of the second external terminals 59 is formed at the bottom of the case body 22. The portion protrudes toward the front side [(b) side] . The second connection terminal 58 and the second external terminal 59 are formed of a conductive metal plate on which a low-resistance noble metal material such as gold is plated. (Structure of Identification Detection Mechanism) 〇 As shown in Fig. 1 and Fig. 2 and Fig. 5, the identification detection mechanism 70 is provided on the left side of the casing 21. As shown in Fig. 2 and Fig. 5, the left wall portion 27 of the casing body 22 is formed with a housing recess 27c in which the detecting movable member 71 for recognizing the identification detecting mechanism 70 is housed. The components for detecting the movable member 71 and the identification detecting mechanism 70 are not protruded to the right side from the inner surface of the left wall portion 27, that is, the guiding reference surface 27b, and the identification detecting mechanism 70 is formed to avoid obstructing the insertion of the card. The storage area of the card is also close to the outer position of the side. -28-200937773 As shown in the enlarged view of Fig. 10, the detection movable member 71 is integrally formed with a support shaft portion 71a at the end portion of the insertion port 29 side [(b) side], and the support shaft portion 71a is rotatably supported The inside of the accommodation recessed portion 27c is formed in the support hole of the left wall portion 27. Therefore, the detecting movable member 71 is formed to be pivotable in the clockwise direction or the counterclockwise direction with the support shaft portion 71a as a fulcrum. The detecting movable member 71 is formed with a holding shaft portion 7ib, and a periphery of the holding shaft portion 71b is formed with a ring-shaped holding concave portion 71c. The detecting movable member 71 is provided with a torsion spring 72. The torsion spring 72 is formed of a conductive metal wire. The surface thereof is plated with a low-resistance metal layer such as gold. The winding portion - 72a of the torsion spring 72 is mounted in the holding recess 71c at the periphery of the holding shaft portion 71b. Each of the wrist portions of the torsion spring 72 is an elastic contact 72b and an elastic contact 72c. The front end of the elastic contact 72b and the front end of the elastic contact 72c are bent in a V shape by a wire for forming the torsion spring 72. The casing body 22 is provided with a pair of ❹ contacts 73 and contacts 74 on the bottom surface 27d of the housing recess 27c. The contact 73 and the contact 74 are metal plates, and the surfaces 73a and 74a are formed with a low-resistance metal layer such as gold by a power shovel. As shown in the nth (A) and (B) diagrams, the contact 73 and the contact 74 are buried inside the bottom surface 27d of the housing recess 27c, and the surface 73a of the contact 73 and the surface 74a of the contact 74 are exposed. It is the same plane as the bottom surface 27d. Therefore, there is almost no step difference between the surfaces 73a, 74a and the bottom surface 27d of the contacts 73, 74. As shown in Figs. 1 1 (A) and (B), the elastic contact 72b is a surface 73a that often contacts the elastic contact 73. The resilient contact 72c is a surface 74a or a bottom surface 27d that contacts the contact 74. The elastic forces of the two elastic joints 72b and 72c-29-200937773 cause the upwardly projecting elastic force to act on the detecting movable member 71' to rotate the detecting movable member 71 in the clockwise direction with the supporting shaft portion 71a as a fulcrum. As shown in Figs. 1 and 10, the top plate 23a of the lid body 23 is provided with a detecting leaf spring 76 on the left side portion. The detecting leaf spring 76 is formed with a notch portion 23e in a portion of the top plate 23. Inside the notch portion 23e, the top plate 23a is formed by cutting a portion of the metal plate as a cantilever leaf spring, thereby forming a top plate 23z 0 As one. The leaf spring 76 is detected, and its base end side 76a is located on the front side [(b) side]. The detecting leaf spring 76 has a linear portion 76b that extends substantially in a straight line from the base end portion 76a in the [a direction] (a direction), and a straight portion 76c that is continuous with the straight portion 76b. The inclined portion 76c gradually faces the left direction as it goes toward the deep side [(a) side]. Next, the front portion of the inclined portion 76c is formed with a pressing portion 76d that extends in a deep prescription toward the [(a) direction]. As shown in Fig. 10, a portion of the straight portion 76b of the detecting leaf spring 76 and a portion of the inclined portion 76c are disposed at positions overlapping the receiving portion. That is, when the first card C1 or the second card C2 is inserted in the normal orientation, a portion of the straight portion 76b and a portion of the inclined portion 76c are located on the passing regions of the cards. The portion of the detecting leaf spring 76 that overlaps the card passing region is the detecting action portion 76e. As shown in Fig. 1 (B), when the detecting leaf spring 76 has no external force, the detecting leaf spring 76 extends straight downward toward the inside of the casing body 22. However, the detecting leaf spring 76 may be deformed downward toward the inside of the casing body 22 at a portion where the detecting portion 76e is detected. The pressing portion 76d at the front of the detecting leaf spring 76 is not overlapped in the first card -30-200937773

Cl or the moving area of the second card C2, but extending beyond the left side of the moving area. A convex curved surface portion 71d is formed on the upper surface of the detecting movable member 71. Since the detecting movable member 71 is pushed upward by the elastic contacts 7 2b, 72c, the convex curved portion 71d is pushed toward the lower surface of the pressing portion 76d of the detecting leaf spring 76. As described above, the detecting movable member 71 is an elastic force acting on the elastic contact 72b and the elastic contact 72c upward, but the pressing force of the pressing portion 76d of the detecting leaf spring 76 is pressed downward to detect the elastic force of the movable member 71. The above-described elastic contacts 72b, 72c push up the elastic force of the detecting movable member 71 to be much larger. As shown in Fig. 11(A), when the first card C1 is attached to the normal mounting position in the normal orientation, the inclined portion 6b at the rear end portion of the guide identification groove 6 on the left side of the first card C1 abuts the detection. The detecting action portion 76e of the leaf spring 76 lifts the detecting leaf spring 76 upward. Therefore, the movable member 71 is detected to be turned clockwise by the elastic force of the elastic contacts 72b and 72c. At this time, the elastic contact 72c is separated from the surface 74a of the contact 74, and the contact 73 and the contact 74 are rendered non-conductive. As shown in FIG. 11(B), when the second card C2 is attached to the deep side in the normal orientation, the inclined portion 16b of the rear end portion of the guide recognition groove 16 on the left side of the second card C2 is located on the insertion port 29 side. The inclined portion 16b does not move below the detecting action portion 76e of the detecting leaf spring 76. Therefore, the detecting action portion 76e does not exert an upward force, and the detecting movable member 71 is pushed downward by the detecting leaf spring 76. As a result, the elastic contact 72b moves to the surface 74a of the contact 74, and the contact 73 and the contact 74 are turned on by the torsion spring 72 to be in the -31 - 200937773 state. (Normal attaching operation of the first card) Next, a description will be given of the case where the card is attached to the card reader 20. Fig. 2, Fig. 6, and Fig. 7 are diagrams showing the operation at the time of attaching the first direction. φ The state in which the card is not attached is as shown in Fig. 5, the sliding inlet 29 side [(b) side] is moved, the slider 41 is rotated counterclockwise, and the movable stopper 47 is moved. When the first card C1 faces forward with its front end portion lc,

When the normal posture on the upper side is inserted from the insertion opening 29, the thin plate portion 7 on the right side of the first card C casing 1 passes through the lower side of the holding portion 53 formed by the slider 41 leaf spring 52. Further, the thin plate portion 7 on the right side passes through the lower side of the identification arm portion 44a, and moves in the region of the height Tb shown in Fig. 4. At this time, when the front corner curved surface on the right side of the first card C1 is pushed by the sliding surface card C1 on the lower side of the identification convex portion 44a of the identification arm 44, the front corner curved surface 3 is pushed and slipped as shown in FIG. 2, so that the identification arm is provided. The turning arm 44 in the clockwise direction 44 rotates the movable stopper 47 on the slider 41. Therefore, the front portion of the thin plate portion 7 on the right side of the first card C1 is located on the left side among the stopper faces 48 of the movable stopper portion 47. The attaching action is performed on the card C1 so that the normal member 41 is moved toward the left side toward the insertion identification arm 44. The surface la is facing toward the side of the retaining portion 44 of the front side of the card, and is moved laterally 3 toward the depth to contact f 44b. When the first moving surface 4 4 b moves, as the identification moves to the right direction, it moves further toward the lower side by forming the first stop surface -32- 200937773 4 8a. On the other hand, the thin plate portion 7 on the left side of the left side of the first card C1 slides on the inclined surface 32a of the regulating elevating member 32 shown in Figs. 4 and 5, and then slides on the regulating elevating member 32 to adjust the elevating member. 3 2 Press down. Next, the thin plate portion 7 on the left side enters the interval Tb between the upper surface 28b of the bottom wall portion 28 shown in Fig. 4 and the above-described guide wall 31. Then, as shown in Fig. 2, the front end portion lc of the first card C1 comes into contact with the reference stopper surface 45a of the reference stopper portion 45 provided on the deep side of the slider 41 0 . During this period, the holding portion 53 of the holding leaf spring 52 of the slider 41 passes through the inside of the guide recognition groove 6 on the right side of the first card C1, that is, through the thin plate portion 7, and contacts the inclined portion 6b behind the guide recognition groove 6. . Since the holding portion 53 is pushed in the right direction by the inclined portion 6b, the holding leaf spring 52 is deformed, and the holding portion 53 is retracted into the holding concave portion 41c of the slider 41. Next, the holding portion 53 slides only on the right side portion 1 e of the first card C1 at the distance L2, and when the intermediate recess portion 8 is reached, the elastic complex Q position force of the leaf spring 52 is retained to cause the holding portion 53 to be fitted to the right side. The inside of the intermediate recess 8 is internal. At this time, the holding portion 53 is slid toward the inclined portion 6b that is inclined in the same direction toward the inclined guide portion 53a on the front side, so that the first card C1 is pushed into the casing 21 with a slight force, so that the holding portion 53 can be fitted Engaged in the intermediate recess 8. Then, the locking portion 53b formed in the holding portion 53 in the direction in which the card insertion direction is substantially orthogonal is engaged with the front inner end 8b of the intermediate recessed portion 8 so that the first card C1 is less likely to face the front direction [ (b) Direction] Detach. As shown in Fig. 13(A), the first card C1 has a depth dimension t3 of -33-200937773 of the intermediate recess 8 which is deeper than the depth dimension t1 of the guide identification groove 6 located at the front. Therefore, it is possible to surely fit inside the intermediate recess 8 by guiding the holding portion 53' inside the identification groove 6. In other words, when the first card C1 is inserted from the insertion port 29, the thin plate portion 7 on the right front side can be placed inside the space Tb in the lower side of the holding portion 53 shown in Fig. 4, and then the push of the first card C1 can be used. In this case, the holding portion 53 can be surely fitted to the intermediate recessed portion 8 of the first card C1. As a result, it is easy to prevent the holding portion 53 from coming into contact with only the right side portion le of the first card C1 without entering the intermediate recess portion 8 or the like. Since the inclined portion 6b is provided behind the guide recognition groove 6 of the first card C1, the depth dimension t3 of the intermediate recess 8 is formed to be large. Therefore, when the first card C1 is inserted, the resistance is reduced, and the holding portion 53 can be made small. It is indeed fitted in the intermediate recess 8. In this way, when the first card C1 is inserted, it is easy to prevent, for example, the slider 41 from being in the (a) direction from the initial position shown in FIG. 2 when the holding portion 53 is fitted before the intermediate recess 8 Move the wrong action. When the first card C1 is pushed after the holding portion 53 is fitted into the intermediate recessed portion 8, the front end portion 1c of the first card C1 is pressed against the reference stopper surface 45a of the slider 41, so that the first card C1 is pressed. The slide member 41 is integrally moved to the deep side. Then, when the first card C1 reaches the attachment completion position shown in FIG. 7, the locking portion 42b of the groove cam 42 formed in the slider 41 is locked to the front end portion 36b of the stopper pin 36, so that the slider 41 locked in that position. At this time, each of the first connection terminals 55 provided on the deep side of the casing body 22 is elastically connected to the external connection portion 5 of the back surface 1b of the -34-200937773 which exposes the first card C1 as shown in Fig. 14 . When the first card C1 is attached to the normal state, as shown in the nth (A) diagram, the identification detecting means 70 forms the upper plate by the inclined portion 6b which is the step portion behind the guide identification groove on the left side of the card C1. The detecting action portion 76e of the detection spring leaf 76 of the body 23a is lifted upward. As a result, the elastic force of the elastic contacts 72b, 72c causes the detecting movable member 7 i to rotate in the clockwise direction so that the elastic contact 72c will disengage from the surface 〇 74a of the contact 74 toward a portion of the housing body 22. The part is moved on the bottom surface 27d. When the first card C1 is to be detached from the card reader 20, as shown in Fig. 7, the i-th card C1 is pushed from the normal attachment state to the deep side [(a) side]. When the slider 41 and the first card C1 move slightly toward the deep side at the same time, the front end portion 36b of the upper locking pin 36 is disengaged from the locking portion 42b of the groove cam 42, and the slider 41 is ejected by the elastic member. The thrust returns to the front side [(b) side]. As a result, as shown in Fig. 2, the slider 41 is returned to the initial position, and the rear end portion of the first card C1 protrudes from the insertion port 29. ❹ (The second card is normally attached) Fig. 8 is a view showing the state in which the second card C2 is normally attached to the card reader 20. The comparison between Fig. 7 and Fig. 8 clearly shows that the operation of each member when the second card C2 is attached, that is, the operation of the holding portion 53 of the leaf spring 52 or the identification arm 44 and the movable stopper portion 47 are The action is exactly the same as when the first card C1 is attached. The difference is only the actions of the identification detecting mechanism 70 shown in the first and eleventh figures. As shown in Fig. 8, the second card C2 is disposed on the left and right sides -35-200937773, and the guide identification groove 16 and the thin portion 17 are long. When the second card C2 is normally attached, it is located behind the guide recognition groove 16. The inclined portion 16b which is the identification portion of the end portion is located close to the insertion port 29 side. As shown in the first 1 (B) diagram, when the second card C2 is normally attached, the inclined portion 16b is located on the front side [(b) side] than the detecting action portion 76e of the detecting leaf spring 76, so that the leaf spring is detected. The pressing portion 76d of the 76 pushes down the detecting movable member 71. As a result, as shown in the first 1 (B) diagram, the detecting movable member 71 D is rotated counterclockwise, so that the elastic contact 72c contacts the surface 74a of the contact 74. Therefore, the contact 73 and the contact 74 can be turned on by the torsion spring 72. (Identification detection operation of the first card 'and the second card') Whether the attachment of the first card C1 is normal or whether the attachment of the second card C2 is normal or not is performed as described below. As shown in Fig. 7, when the first card C1 is normally attached, the first connection terminal 55 individually contacts the external connection portion 5 provided on the rear surface 1b of the first card C1. Similarly, as shown in Fig. 8, when the second card C2 is normally mounted, the first connection terminal 55 individually contacts the external connection portion 5 provided on the back surface of the second card C2. The control unit built in the card reader 20 or the control device of the parent device connected to the card reader 20 such as various electronic devices or personal computers monitors the first connection terminal 5 5 and detects the first connection. When the terminal $5 contacts the external connection portion 5, it recognizes which card is attached. For example, if any of the external connection portions 5 is short -36-200937773 among the plurality of external connection portions 5 of the card, the control unit monitors the first connection terminal 5 5 ' corresponding to the short-circuited external connection portion 5 to detect the first 1 Whether or not the connection terminals 5 5 are short-circuited, it is possible to recognize that the first card C1 is attached or the second card C2 is attached. The control unit also monitors whether or not the contact 73 and the contact 74 of the identification detecting mechanism 70 shown in Fig. 10 are in an on state. The control unit recognizes whether or not the contact 73 and the contact 74 are electrically connected when it is recognized whether the first card C1 is attached or the second card C2 is attached, based on a short circuit or the like between the first connection terminals 55. As shown in Fig. 11(A), when the contact 73 and the contact 74 are in a non-conducting state, it is judged that the attached card is the first card C1. As shown in the first 1 (B) diagram, when the contact 73 and the contact 74 are maintained in the on state, it is determined that the attached card is the second card C2. Next, the control unit executes a control operation suitable for the first card C1 and the second card C2 specifications. For example, when the driving voltages of the first card C1 and the second card C2 are different, different voltages are supplied for the respective cards. Further, when the memory capacities of the first Q card C1 and the second card C2 are different, the memory remaining amount information of each card is included in the control unit's execution of the adjustment of the recorded data amount (the first card or the second card). Error Insertion FIG. 3 is a view showing a state in which the rear end portion ld of the first card C1 is inserted from the insertion port 29 toward the front. As shown in Fig. 4, the identification convex portion 44a of the identification arm 44 is located on the insertion path of the card, and therefore, the rear end portion id of the first card C1 touches the -37-200937773 identification convex portion 44a. When the first card C1 is pushed in this state, the arm 44 is rotated in the clockwise direction, and the movable stopper 47 is moved in the right direction. However, at this time, the rear end portion Id maintains the state in which the identification convex portion 44a is touched. Therefore, the first card C1 cannot move relative to the slider 41 to the deeper side. Then, when the first card C1 is pushed in, the slider 41 is pushed into the deep side together, but since the rear end portion Id of the first card C1 is still in contact with the identification convex portion 44a, the first 1 card C1 φ cannot fully enter the housing 21. Further, when the slider 41 is pushed in toward the deep side along with the first card C1, the rear end portion 1d of the first card C1 touches the upper portion on the left side of the storage area as shown in Fig. 4 The guide wall 31 prevents the first card C1 and the slider 41 from moving to the deep side. When the rear end portion id of the first card C1 hits the upper guide wall 31, the front end portion 36b of the upper lock pin 36 does not reach the locking portion 42b of the groove cam 42 in the lock mechanism 35. position. Therefore, in the state of Fig. 3, even if the first card C1 Q is pushed, the slider 41 is not locked, so that when the force applied to the first card ci is eliminated, the slider 41 can be returned to the front. The elastic force of the spring member in the (a) direction allows the first card C1 to be pushed back to the insertion port 29. In addition, when the first card C1 is inserted from the insertion port 29 in a state in which the front end portion id is directed forward and the back surface 1b is upward, similarly, as shown in FIG. 3, and the front end portion Id is inserted forward. the same. In addition, regarding the erroneous insertion, the second card C2 is also in the same state. (Insert operation of the third card) -38- 200937773 Fig. 9 is a view showing the state in which the third card C3 is normally attached to the card reader 20. In the third card C3, the width dimension W3 is smaller than the width dimension W0 of the third card C1 and the second card C2. Therefore, when the third card C3 is inserted from the insertion port 29 with the right side being biased, the third card C3 is an area that is moved in the width dimension wb between the regulating elevating member 32 and the inner side surface 41a of the slider 41 (refer to the fifth Figure) The inside is inserted deep into the side. φ Since the third card C3 has the notched portion 17 on the right side, the front end of the card does not touch the identification convex portion 44a of the identification arm 44. Therefore, the identification arm 44 is also maintained in the counterclockwise direction, and the movable stopper 47 is maintained to move to the left side. Then, the front end portion of the third card C3 touches the first stopper surface 48a and the second stopper surface 48b of the movable stopper portion 47 (refer to FIG. 4). At this time, the leaf spring 52 is held. The holding portion 53 is fitted to the concave portion 18 that penetrates the right side portion of the third card C3 casing up and down. In this state, when the third card C3 is pushed into the casing 21, the slider Q 41 is pushed in together. As shown in Fig. 9, the left side portion of the third card C3 is inserted into the deep side of the casing 21 without touching the upper guide wall 31. Then, the front end portion 36b of the upper locking pin 36 is locked to the upper locking portion 42b of the groove cam 42, and the slider 41 is locked at this position. At this time, the second connection terminal 58 provided at the bottom of the case body 22 is individually connected to the external connection portion provided under the third card C3. The control unit recognizes that the third card C3 is attached to the normal state based on the monitoring of the short-circuit state of the second connection terminal 58 and the like. -39- 200937773 (Modification of the first card) The figure I3 (B) is a left side view showing a modified version of the third card. In the modification Cal, the inclined portion 0B provided behind the guide recognition groove 6A is different from the inclined portion 6b of the first card ci shown in Fig. 13(A). As shown in Fig. 12, the inclined portion 6b of the first card C1 is inclined so as to gradually move away from the center line 〇 _ 朝向 toward the rear end portion 1 d, but the inclined surface 6 b is a vertical surface of the pair Q to the surface la. On the other hand, the inclined portion 6B of the modified example Ca 1 is inclined so as to gradually move away from the center line ◦-〇' but the inclined portion 6B toward the rear end portion 1 d as the inclined portion 6b of the first card C 1 is inclined. The surface that is not perpendicular to the surface 1 a is inclined so as to gradually approach the surface la as it goes toward the rear end portion Id. That is, the inclined portion 6B is inclined to be a standing body. The modification Cal is configured such that when it is attached to the card reader 20, the holding portion 53 slides on the inclined portion 6B during the insertion process, and then slides on the left side portion 1 e and then can be fitted in the middle. Concave portion 8. Further, as shown by the broken line in Fig. 13(B), the modification Cal can be attached to a card reader having the holding portion 153 which can be biased from the card surface la. In this case, when the modification Cal is inserted into the card reader, the holding portion 53 passes through the inside of the guide recognition groove 6A, and then the holding portion 153 slides on the inclined portion 6B, thereby sliding the surface la of the card, and then, The holding portion 153 is fitted to the intermediate recess portion 8. As described above, the modification Cal is not limited to being attachable to the card reader having the holding portion 53, as shown in Fig. 13(B), and may be attached to the holding portion 153 of the -40-200937773. The card reader is in the opposite position to the side of the surface, and thus the modification Cal is an electronic function card which can be widely used. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view showing a card connector according to an embodiment of the present invention. Fig. 2 is a perspective view showing the card connector after the first card is inserted into the card connector to remove the cover. Fig. 3 is a perspective view showing the card connector after the first card is detachably attached to the card connector, and the cover is removed. Fig. 4 is a front elevational view showing the card connector as seen from the insertion opening. Fig. 5 is a plan view showing the card connector after the cover is removed, when the card is not attached. Fig. 6 is a plan view showing the state in which the card connector is removed from the cover during the first card attachment. Figure 7 is a plan view showing the card connector removed from the cover after the first card is attached. Figure 8 is a plan view showing the card connector removed from the cover after the second card is attached. Figure 9 is a plan view showing the card connector removed from the cover after the third card is attached. Fig. 10 is a partial perspective view showing the configuration of the identification detecting mechanism. The U(A) and (B) diagrams are side views showing the operation of the identification detecting mechanism. Figure 12 is a plan view of the first card. -41 - 200937773 Fig. 13(A) is a left side view of the first card, and Fig. 13(B) is a left side view showing a modification of the first card. Fig. 14 is a perspective view showing the first card as seen from below. Figure 15 is a plan view of the second card. [Description of main component symbols] C1 : 1st card φ C2 : 2nd card C3 : 3rd card 1 , 1 1 : Case 1 a : First surface, 1 b : Second surface, back surface • 1 c : Front end 1 d. Post bribe 1 e : Right side Q 1 f : Left side part 5 : External connection part 6 , 16 : Guide identification groove 6b, 16b: Inclined part 7, 17: Thin plate part 8: Intermediate recessed part 20: Card reader 21: housing 22: housing body -42- 200937773

23 : Cover 4 1 : Slide 55 : 1st connection terminal 58 : 2nd connection terminal -43-

Claims (1)

200937773 X. Patent application scope 1. An electronic function card comprising: a card housing and an electronic circuit housed inside the card case; and a plurality of external connection portions which are exposed to the electronic circuit to be exposed on the surface of the card case, and are characterized The card case has a first surface and a second surface facing each other in the thickness direction, a front end portion facing the insertion card connector, and a right side portion and a left side portion extending along the insertion side Q direction, the outer portion The connection portion is provided on at least one of the upper surface and the second surface, and at least one of the right side portion and the left side portion is formed to be recessed from the first surface to the thickness of the card body from the front end portion The guide recognition groove extending toward the rear, the longitudinal length dimension of the guide recognition groove is different according to the type of the electronic circuit inside the card case. 2. The electronic function card according to the first aspect of the invention, wherein the intermediate recessed portion for holding the card is formed at a position behind the guide identification groove, regardless of the longitudinal length of the guide recognition groove. The distance from the front end portion to the intermediate recess portion is constant. 3. An electronic function card having a first card and a second card, wherein the first card and the second card are provided with: a card case and an electronic circuit housed inside the card case; and the electronic circuit is exposed to the electronic circuit a plurality of external connecting portions on the surface of the casing, wherein each of the first card and the second card has a first surface and a second surface facing each other in a thickness direction; and is connected to the insertion card - 44-200937773 a front end portion in the direction of the device; and a right side portion and a left side portion extending along the insertion direction, the external connection portion being provided on at least one of the first surface and the second surface, the right side portion and the At least one of the left side portions is provided with a guide recognition groove extending from the first surface to the thickness of the casing, and extending from the front end portion to the rear, and the first card and the second card are both of the guide recognition grooves. In addition to the length dimensions, the first card and the second card 0 are the same in shape and structure, and the first card and the second card are both inside. Different electronic circuits. 4. The electronic function card according to claim 3, wherein an intermediate recess for holding the card, the first card and the second card are formed at a position behind the guide identification groove. The distance from the front end portion to the above intermediate recess portion is constant. 5. The electronic function card according to any one of claims 1 to 4, wherein when the length of the guide identification groove is different, the driving voltage of the electronic circuit supplied to the inside of Q is different. 6. The electronic function card according to any one of claims 1 to 4, wherein, when the length of the guide recognition groove is different, the memory capacity of the electronic circuit provided inside is different. A card connector for attaching an electronic function card according to any one of claims 1 to 4, wherein the card connector is provided with: a guiding portion; and an identification detecting mechanism for detecting the difference in the length of the guiding recognition groove. -45- 200937773 8 . -~• The card connector is a card connector that is equipped with the electronic function card described in claim 5, and is characterized in that: the guide for passing the guide identification slot is provided. And an identification detecting mechanism for detecting the length of the identification groove differently. A card connector, comprising: a card connector for an electronic function card according to claim 6; wherein: the guide portion for guiding the identification groove is provided, and the guide identification An identification detection mechanism for detecting different groove lengths. 10. The card connector according to claim 7, wherein when the electronic function card is attached to the normal position, the identification detecting means performs different actions according to the position of the rear end of the guiding recognition slot. . 11. The card connector according to claim 8, wherein when the electronic function card is attached to the normal position, the identification detecting means performs different actions according to the position of the rear end portion of the guiding recognition groove. . 1. The card connector according to claim 9, wherein when the electronic function card is attached to the normal position, the identification detecting mechanism performs differently according to the position of the rear end portion of the guiding recognition slot. action. The card connector according to claim 7, wherein the terminal is connected to the external connection portion of the electronic function card, and the control unit monitors the connection terminal. It is recognized that the electronic function card is attached to the normal position, and then the operation state of the identification detecting means is confirmed, whereby the type of the electronic function card to be attached can be determined. The card connector according to claim 8, wherein a connection terminal that is in contact with an external connection portion of the electronic function card is provided, and the control unit monitors the connection terminal, thereby recognizing the above The electronic Q function card is attached to the normal position, and then the operation state of the above-described identification detecting means is confirmed, whereby the type of the electronic function card to be attached can be determined. The card connector according to claim 9, wherein a connection terminal that is in contact with an external connection portion of the electronic function card is provided, and the control unit monitors the connection terminal, thereby recognizing The electronic function card is attached to the normal position, and then the operation state of the identification detecting means is confirmed, whereby the electronic power card type to be attached can be determined. The card connector according to claim 10, wherein a connector terminal that is in contact with an external connection portion of the electronic function card is provided, and the control unit monitors the connection terminal to identify the electronic component The function card is attached to the normal position, and then the operation state of the identification detecting means is confirmed, whereby the type of the electronic function card to be attached can be determined. 17. The card connector according to claim 11, wherein a connection-47-200937773 terminal is provided to be in contact with an external connection portion of the electronic function card, and the control unit monitors the connection terminal. Recognizing that the electronic function card is attached to the normal position, and then confirming the operation state of the identification detecting mechanism, thereby determining the type of the electronic function card attached. 18. For example, claim 12 The card connector of the present invention is provided with a connection terminal that can be in contact with an external connection portion of the electronic function card, and the control unit monitors the connection terminal, thereby recognizing that the electronic ❹ function card is attached to a normal position. Then, the operation state of the above-described identification detecting means is confirmed, whereby the type of the electronic function card to be attached can be determined. 〇 -48-