DE102006024247A1 - Antenna coil for communication module, has flat coil body whose thickness is in coil body axial direction, where coil carrier construction unit is arranged between substrate and coil body, which is carried on substrate surface - Google Patents

Abstract

The antenna coil (1) has a flat coil body of an air core type. The antenna coil has a thickness in the coil body axial direction. A coil carrier construction unit, which is arranged between the coil body and a substrate as an attachment object of the antenna coil such that the coil body is carried on a surface of the substrate. A coil surface is equal to a surface of a region, which is surrounded by an outline of a projected coil. The projected coil is provided by the coil body projection on a projection level, which is perpendicular to the axial direction of the coil body. Independent claims are also included for the following: (1) a method for manufacturing communication module (2) a wireless card type device with a communication module.

Description

The The present invention relates to a wireless card type device with a communication module, an antenna coil for the communication module and a method of manufacturing the communication module.

In In recent years, an electronic key system (which also has a intelligent access system, etc.) is spread. In this Electronic key system becomes an ID authentication through wireless communication between this system and a user-borne, wireless electronic key (also called a portable device). The Controlling a locking / unlocking a door bolt or a closing / unlocking a Door lock, an engine start, etc. may also be by commands from this portable Device performed become. With the previous wireless electronic key with the proliferation of an IC card etc. as background (3 mm or more and 5 mm or less in thickness) becomes the requirement put this wireless electronic key as a thin-made, wireless card-type device to build the wearing comfort characteristics by storing this wireless electronic key in to improve a purse etc.

The previous electronic key system uses a communication system that is capable of controlling, such as. closing / unlocking the door lock and starting the engine, if the user is within a constant distance of the automobile approaches, even if a user does not have a special button operation, etc. regarding the wireless electronic key. A Inquiry radio wave that sends in one direction from the side of the automobile becomes, is received concretely. An ID authentication information, control command information relating to the previous closing / unlocking or The motor starting refers, etc., are superimposed on the transmitted radio wave and sent to the side of the automobile. In this case react the wireless electronics key and the automobile does not respond to communication when the user is positioned remotely. On the other hand, when the user approaches, there there are many cases where a direct proximity communication using a low frequency band (50 kHz or more and 500 kHz or less) used to redirect the radio wave by redirecting the radio wave even if the user is using the wireless electronic key any part of his body holds.

The Radio wave of the low frequency band has a very long wavelength. at an antenna designed for This radio wave is usually used, therefore, a so called LF antenna (LF = Low Frequency) used, by combining an antenna coil and a capacitor, resonant with this antenna coil in a desired frequency band or is coupled in resonance, is provided. If the LF antenna is installed in the wireless card type device, it is further necessary, the thickness of this antenna coil in accordance with the thickness of a Card type package body (e.g. 1 mm or more and 3 mm or less). In this Case it is desirable attach the antenna coil to a substrate in a mold around the aperture diameter the antenna coil as big as possible to adjust the sensitivity to the radio wave, perpendicular to the substrate surface incident to raise. It is effective to have an antenna coil with a core of one high inductance to use to raise an antenna gain. A flat ferrite core however, is weak in mechanical strength, and a crack, a fragment etc. are easily handled by a coil winding timing etc. caused. Accordingly, normally becomes an air core coil used.

There however, the core type coil has no core, there are defects in that no radio wave magnetic field concentrates on the circumference of the coil can be and that a sensitivity and an antenna gain are inferior.

in view of The problem described above is a task of the present invention therein, a wireless card type device to create with a communication module. Another task The present invention is an antenna coil with a high sensitivity and a high antenna gain to create. Another object of the present invention is to provide a Manufacturing method of a communication module with an antenna coil to accomplish.

An antenna coil has a flat core-type bobbin having a thickness in an axial direction of the bobbin; and a coil support member disposed between the coil bobbin and a substrate as a mounting object of the antenna coil such that the coil bobbin is supported on a surface of the substrate. The thickness of the bobbin is smaller than a radius of a circle, a surface thereof being equal to a surface of a region surrounded by an outline of a projected bobbin, the projected bobbin projecting the bobbin onto a plane perpendicular to the axial plane Direction of the spu is body, is provided. The coil member is made of resin-hardened, soft magnetic material.

at the previous coil are the sensitivity and the gain the antenna coil, since the coil support member is made of a resin-hardened, soft magnetic material is made. This is because of that the resin-hardened, soft magnetic Material is a ferromagnetic material and a high magnetic Having permeability, such that the magnetic field of an electric wave to participate is concentrated during transmission / reception of the antenna coil. The antenna coil therefore has a high sensitivity and a high antenna gain on.

One Method for producing a communication module with an antenna coil and a transmitting / receiving circuit attached to a substrate are further provided. The antenna coil is connected to the transmitting / receiving circuit connected. The method comprises the steps of positioning a coil side connection of the antenna coil together with a A solder member for connecting between a substrate side terminal the substrate and the coil-side terminal of the antenna coil, and the warming of the substrate together with the antenna coil in a solder reflow oven on, such that the soldering member between the coil-side terminal and the substrate side terminal is melted and soldered. The antenna coil further includes a flat air core type bobbin a thickness in an axial direction of the bobbin, and a coil carrier member, that between the bobbin and a substrate as a mounting object of the antenna coil is, such that the bobbin on a surface of the substrate is carried on. The thickness of the bobbin is smaller than a radius of a circle, one surface thereof equal to a surface a region surrounded by an outline of a projected bobbin is, wherein the projected bobbin by projecting the bobbin on a projection plane perpendicular to the axial direction of the bobbin is, is provided. The spool carrier member is a spool sheath with a bobbin receiving space for receiving the bobbin in same. The coil shell has an annular body which corresponds to the bobbin, on, and the coil shell has a part made of the resin-hardened, soft magnetic material is made.

at the previous communication module are the sensitivity and the gain of the antenna coil improves as the coil support member made of resin-hardened, soft magnetic material is made. This is because of that the resin-hardened, soft magnetic material is a ferromagnetic material and has a high magnetic permeability, such that a Magnetic field of an electric wave to assist in transmitting / receiving the antenna coil is concentrated. The antenna coil therefore has a high sensitivity and a high antenna gain.

A The wireless card type device further includes a communication module with an antenna coil, a transmitting / receiving circuit connected to the Antenna coil is connected, and a substrate, and a card type sheathing on. The antenna coil has a flat bobbin of an air core type with a thickness in an axial direction of the bobbin, and a spool carrier member that between the bobbin and a substrate as a mounting object of the antenna coil is, on, such that the bobbin on a surface of the Substrate is worn. The thickness of the bobbin is smaller than a radius a circle, where one area the same equal to a surface a region surrounded by an outline of a projected bobbin is, wherein the projected bobbin by projecting the bobbin on a projection plane perpendicular to an axial direction of the Bobbin is, is provided. The spool carrier component is made of resin-hardened, produced soft magnetic material. The bobbin points an axis coincident with a vertical line of the substrate. The Card type sheathing takes the communication module to such Way that a thickness direction of the substrate in a thickness direction the card type sheath coincides.

at the previous wireless device are the sensitivity and the gain of the antenna coil improves as the coil support member made of a resin-hardened, soft magnetic material is made. This is because of that the resin-hardened, soft magnetic material is a ferromagnetic material and has a high magnetic permeability, such that the Magnetic field of an electric wave to assist in transmitting / receiving the antenna coil is concentrated. The antenna coil therefore has a high sensitivity and a high antenna gain. The The wireless card type device is also for a wireless access key of a Suitable for self-propelled vehicles. The wireless card type device is also thin. It is therefore preferable to place the wireless card type device in a Wallet or the like to lay.

The foregoing and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings it is more obvious. Show it:

1 an exploded perspective view showing an antenna coil according to an embodiment of the present invention;

2A a front view,

2 B a bottom view,

2C a back view, and

2D a side view showing the antenna coil in 1 demonstrate;

3A a cross-sectional view showing the antenna coil along a line IIIA-IIIA in 2A shows, and

3B a cross-sectional view showing the antenna coil along a line IIIB IIIB in 2A shows;

4 a schematic view showing a wireless key system with a wireless card type device;

5 a partial cross-sectional perspective view showing the wireless card type device;

6A an exploded perspective view showing an antenna coil according to a first modification of the present invention, and

6B a cross-sectional view showing the antenna coil in 6A shows;

7 a perspective view showing an antenna coil according to a second modification of the present invention;

8th an exploded perspective view showing an antenna coil according to a third modification of the present invention;

9A an exploded perspective view showing an antenna coil according to a fourth modification of the present invention, and

9B a cross-sectional view showing the antenna coil in 9A shows;

10A an exploded perspective view showing an antenna coil according to a fifth modification of the present invention, and

10B a cross-sectional view showing the antenna coil in 10A shows;

11 an exploded perspective view showing an antenna coil according to a sixth modification of the present invention;

12 Fig. 12 is a cross-sectional view showing an antenna coil according to a seventh modification of the present invention;

13 a schematic view showing a method of manufacturing a communication module according to the embodiment of the present invention;

14A a schematic view explaining a warping of a coil shell in a reflow process, and

14B a schematic view showing a soldering defect of the coil shell; and

15 an exploded perspective view showing an antenna coil according to an eighth modification of the present invention.

1 shows an exploded perspective view of an antenna coil 1 in an example of the invention. 2A to 2D FIG. 14 is four plane views (a plan view, a front view, a side view, and a bottom view) of the antenna coil 1 , The antenna coil 1 has a coil main body 10 an air core type of a flat shape and a coil shell 20 on. The coil jacket 20 is in an annular mode that is the coil main body 10 corresponds, formed, and a coil receiving portion 24 for receiving this coil main body 10 is formed in the circumferential direction.

The coil jacket 20 acts as a coil carrier body and is constituted by resin ferrite (resin-coupled soft magnetic material) in which powder of a soft magnetic ferrite SFP as a powder of a soft magnetic material is coupled by resin (eg, PPS resin) RM. The coil jacket 20 is produced by injection molding using a composition formed by kneading the soft magnetic ferrite powder and the PPS resin. The coil receiving section 24 is formed into a groove shape, which is to an end surface in the axial direction of the coil jacket 20 is open. The entire coil sheath 20 ie the entire floor section 20b the coil receiving portion 24 and two sidewall sections 20w in 3A and 3B are built up by the resin ferrite. The bottom section 20b and the two sidewall sections 20w clearly form a ring molding portion of the resin-coupled soft magnetic material along the circumferential direction of the coil main body 10 , The coil case may further in a bobbin shape, in the coil receiving portion is formed in a groove shape along the outer peripheral surface, be formed.

The thickness of the coil main body 10 in the axial direction thereof is set to be smaller than the radius of a circle of the same area as a surface (surface of a planar outer shape) passing through a separate outer molding line at a projection time to a projection plane perpendicular to this axis , is surrounded. "The coil main body 20 is formed in the flat shape "means that" the thickness of the coil main body 10 in the axial direction thereof is set to be smaller than the radius of the circle of the same area as the area (surface of the planar outer shape) passing through the own outer forming line at the projection time to the projection plane perpendicular to this axis , is surrounded. "A coil-side connection section 21 for soldering and attaching the coil main body 10 on a substrate is in the coil shell 20 arranged.

As in 4 is shown is the previous antenna coil 1 along with a signal transceiver circuit 14 that with this antenna coil 1 in a positional relationship in which the axis of the spool main body 10 with the vertical direction of the substrate 17 matches, is connected to the substrate 17 soldered and attached to the same. A communication substrate module 3M is therefore structured. In this communication substrate module 3M forms the antenna coil 1 together with a capacitor 12 that with this antenna coil 1 coupled in parallel in resonance, an LF antenna 13 , As in 5 shown is this capacitor 12 and the signal transceiver circuit (IC) 14 on a substrate surface on the inside of an air gap of the antenna coil 1 appropriate. A transponder circuit or transceiver circuit 15 Further, with the foregoing LF antenna, it is parallel to the signal transmit-receive circuit 14 connected. As in 5 is shown, the transceiver circuit (IC) is 15 on a substrate surface outside the antenna coil 1 appropriate.

As in 3A and 3B is shown, the coil-side terminal portion 21 as a connection pad 21 for performing surface-mounting on the substrate as a mounting target on the bottom surface side of the coil casing 20 set up. A solder paste pattern formed by printing, etc. is as the preceding solder material 135 between the connection pad 21 and the substrate-side pad 134 arranged. As in 2A to 2D is shown, have the outer shape lines of the coil main body 10 and the coil jacket 20 right-angled shapes, and the connection pad 21 is in an end portion of the direction of a long side of the coil jacket 20 arranged.

The connection point 21 may also be on the bottom surface of the coil shell 20 be arranged. In this case, however, a line section must 11 of the coil main body 10 be connected to a position that the previous connection pad 21 the bottom surface of the coil receiving portion 24 corresponds to a narrow width, and an assembly work of the spool main body 10 in the coat gets very complicated. As in 3A and 3B In this embodiment mode, there is a pin digging portion 23 who has a connection pin 26 buried in the same in the axial direction and is on the outer peripheral surface of the coil jacket 20 educated. The pipe section 11 of the coil main body 10 is built to match the top of the connector pin 26 pointing to the top surface of this pin digging section 23 projects to be connected. The assembly work is therefore very easy. The connection point 21 is on the lower surface of the pin digging section 23 arranged, and a lower end portion of the connecting pin 26 is to the connection pad 21 guided.

The coil axis of the antenna coil 1 coincides with the vertical direction of the substrate surface such that directivity with respect to transmitting and receiving a radio wave is raised in this direction. The separate coils 7 . 8th with axes coincident with two independent directions in the substrate surface may also be attached to the substrate 17 be attached (these coils 7 . 8th be done by omitting a connection wiring in 4 drawn, each of these coils 7 . 8th is however to the antenna coil 1 connected in parallel).

As in 5 is the previous communication substrate module 3M in a housing body 18 of a card shape in a shape consistent with the thickness direction of the substrate 17 such that a wireless card type device 3 is constructed. This wireless card type device 3 is used as a wireless key for an automobile, and is advantageously stored in a purse, etc., because of this wireless card type device 3 is thin. As in 4 is shown is a dry battery 16 as a drive power source of the signal transmission-reception circuit 14 also in the housing body 18 kept. A mechanical key 137 for an emergency is also also in the housing body 18 kept and can be out of a slot 138 attached to a side surface of the housing body 18 , as in 5 is shown, is formed, to be solved.

As in 4 is shown, sends a body system ECU 107 of the automobile 105 a request radio wave for detecting the approaching of a user of the wireless card type device 3 carries, from an antenna 166 by a signal transmission-reception circuit 115 that with this body system ECU 107 connected periodically. If the user is the automobile 5 within a constant distance, the LF antenna receives 13 inserted into the wireless card type device 3 is installed, this request radio wave. The signal transceiver circuit 14 receives this request radio wave and sends out an ID code for authentication by a radio wave of a prescribed frequency band. The automobile-side body system ECU 107 receives through the antenna 116 this ID code radio wave, and the signal transmit-receive circuit 115 authenticates if the sent ID is a correct ID. When the authentication is received, the body system ECU gives 107 a unlock permission signal for releasing the door lock and a start permission signal of an engine. Here is the reference number 119 a transceiver circuit.

On the other hand, if the dry battery 16 the wireless card type device 3 is consumed and no signal transmission-reception circuit 14 is operated, the request radio wave is transmitted through the LF antenna 13 is received to the transceiver circuit 15 Posted. In the transceiver circuit 15 becomes the electromotive force in the antenna coil 10 is excited by the request radio wave, converted into electric power, and the transceiver circuit 15 sends an ID code radio wave from the LF antenna 13 out. In the car 105 This ID code radio wave is transmitted by antennas 113 and 116 received, and post-authentication processing can be similarly performed. The transceiver circuit of the wireless card type device 3 Namely, acts as a fuse circuit at a battery-empty timing.

If the previous wireless card type device 3 is carried along with a purse, etc., there is a fear that a conductor of a comparatively large area, such. As a coin, etc., the antenna coil 1 covered, and the sensitivity of the antenna and the Q (frequency selection degree) are reduced. However, even if a situation of overlapping the coin with the main surface of the wireless card type device 3 is assumed, it is possible to reduce the probability that the antenna coil 1 is perfectly covered by this coin, etc., as mentioned above, when the antenna coil 1 on the substrate as a flat air core type coil of a constant area or more, as in FIG 4 is shown attached. In turn, a wireless card type device 3 a high sensitivity can be realized.

The planar outer shape of the wireless card-type device 3 may be set to have short sides of 40 mm or more and 60 mm or less (eg 50 mm), and 75 mm or more and 95 mm or less (eg 85 mm) and a thickness of 2 mm or more and 5 mm or less (eg, 4 mm) (for example, this planar outer shape is about the same size as the size of a credit card). In the assembled antenna coil, the area of a surface of a planar outer shape may be set to 8 cm ² or more and 15 cm ² or less (eg, 12 cm ² ). The width of the bobbin 10 at a projection time to a projection surface that is perpendicular to the axis may be set to 1 mm or more and 4 mm or less (eg, 3 mm). The thickness of the coil sheath 20 in the axial direction thereof may be further set to 1 mm or more and 3 mm or less (eg, 1.6 mm). As described below, the antenna coil is in this Ausführungsbei game mode 1 constructed to have a planar mode of a rectangular shape and to have a short side of 25 mm or more and 35 mm or less (eg 30 mm) and a long side of 35 mm or more and 45 mm or less (e.g. B. 40 mm) exhibit.

The diameter of a winding wire of the coil is further set to 50 μm or more and 70 μm or less (a resin (eg, polyurethane) coating wire having a coating thickness of 2 μm or more and 5 μm or less (e.g. 3 μm)). The number of turns is set to 200 or more and 300 or less (the self-inductance of the coil main body 10 is set to 4 mH or more and 6 mH or less). The electrostatic capacity of the capacitor 12 is set to 300 pF or more and 400 pF or less (eg 350 pF). A resonant frequency of the LF antenna 13 Therefore, it may be set to 100 kHz or more and 150 kHz or less (eg, 134 kHz). The Q value of the antenna may be realized as 18 to 21.

The radio wave magnetic field related to antenna signal transmission and reception may be applied to the coil shell 20 and in turn on the spool main body 10 by building up the coil jacket (coil carrier body) 20 concentrated by the previous resin ferrite. It is accordingly possible to contribute to the improvements in sensitivity and gain of the antenna.

As in 13 is shown in the communication substrate module 3M in the previous wireless card type device 3 USAGE det, a coil-side terminal section 21 the antenna coil 1 in a substrate-side connection section (substrate-side contact point) 134 together with a soldering material 135 positioned to the connection. In this state, the substrate becomes 17 together with the antenna coil 1 that on this substrate 17 positioned and placed in a reflow oven 150 introduced and warmed. The solder material 135 is therefore melted, and the coil-side terminal portion 21 becomes with the substrate-side terminal section 134 soldered and connected, such that the Kommunikationsssub stratmodul 3M is made. At this time, as in 14A and 14B is shown in an antenna sheath, ie, the pin burying portion 23 on the substrate 17 , a heat transfer on the side of the substrate 17 readily proceed to the side of the lower surface. On the other hand, a large amount of radiant heat from a furnace heat source is readily received on the upper surface side. Accordingly, an increase in the temperature of the upper surface side readily proceeds, such that a temperature gradient of the thickness direction between the upper surface side and the lower surface side that faces the substrate 17 is caused without further ado. Therefore, an expansion displacement of the in-plane direction on the upper surface side becomes larger than that on the lower surface side. When the coil sheath 20 is constructed by a low-synthesis resin simplex, warping in an up-convex mode is easily caused. As a result, the coil-side terminal portion floats 21 by this distortion of the substrate-side contact point (substrate-side connection section) 134 such that a soldering defect is easily caused. However, since the coil sheath 20 is constructed by the resin ferrite formed by mixing the soft magnetic ferrite powder having a higher modulus of elasticity than resin, the rigidity thereof is raised, and warping of the coil sheath 20 may be hindered even if thermal stress is applied at the previous solder melting time.

A modified example of the antenna coil 1 The invention is explained below (sections which 1 and 2 are common are denoted by the same reference numerals, and the explanations thereof are omitted). At the antenna coil 1 from 6A and 6B is a coil sheath 120 a mode similar to that of 2A to 2D however, it is constructed as an injection molded product of a PPS resin simplex. A coil carrier body 50 is between the coil shell 120 and the coil main body 10 on the bottom surface of the bobbin storage section 24 of the coil jacket 120 arranged. The coil carrier body 50 is constructed as a resin ferrite cast product of a ring shape and a plate shape in which soft magnetic ferrite powders are coupled by PPS resin. The Harzferrit- cast product, this coil carrier body 50 can, as an injection molded product or a die-pressed cast product, from the coil shell 120 is separated, be prepared.

At the antenna coil 1 from 7 no coil sheath is arranged, and a coil carrier body 51 is constituted by a cast body of a sheet shape of a resin-coupled soft magnetic material having a surface surrounded by an outer shape line of the coil when the coil main body 10 is projected onto a plane perpendicular to the axis thereof. A line section 11 from the spool main body 10 is directly to a contact point 121 on the substrate 17 soldered. An outer peripheral edge of the spool carrier body 51 a sheet shape is formed in a rectangular shape resulting from the preceding outer shape line of the spool main body 10 extends.

In the construction of 8th is a reinforcement frame 30 made of a material having a higher modulus of elasticity than the resin ferrite along the circumferential direction of the coil mantle 20 integrated by the resin ferrite integrated. The prevention effect of warping of the coil jacket 20 at the melting point is therefore further raised. The reinforcement frame 30 is in the bottom section 20b of the coil jacket 20 for forming the bobbin storage section 24 bury this groove shape. The reinforcement frame 30 is concrete in the bottom section 20b of the coil jacket 20 buried by insert molding in a mode where the outer surface of the reinforcing frame 30 and the outer surface of the bottom portion 20b to be the same area.

The reinforcing frame is as a metal frame (hereinafter also metal frame 30 called). The metal material has a high modulus of elasticity and is excellent in processing property, and it is easily a frame shape similar to that of the coil case 20 corresponds to an air core type, grown by press processing, etc. Further, the frame sectional shapes of an L-shape and a C-shape can also be readily obtained by press molding. The metal frame is a ladder. As by leading in 15 is shown, a path of an electric current, which is around the axis of the coil main body 10 winds, formed when the metal frame in a continuous annular mode (reference numeral 37 ) along the coil jacket 20 is formed. The problem that the metal frame with the coil main body 10 is inductively coupled and the apparent inductance of ge the entire antenna coil is reduced is caused accordingly. Namely, when a radio wave magnetic field H changes, passing through the coil main body 10 extends, an induced electric current flows to the metal frame 30 , The radio wave magnetic field related to the antenna signal transmission and reception is canceled by the opposite magnetic field H 'thereof so that the apparent inductance is reduced. In the case of in 4 shown LF antenna 13 is in particular the capacitor 12 which is set in terms of capacitance to a resonance point at a desired frequency with respect to the inductance of the coil main body 10 the same with the antenna coil 1 connected in parallel. The Q value of the antenna is determined by the characteristics of the LC parallel resonant circuit thereof. However, if the metal frame is formed in a mode as indicated by the reference numeral 37 from 15 is shown, the apparent inductance of the antenna coil is reduced by the inductive coupling thereof. The resonance point of the previous LC parallel resonant circuit is shifted from the desired frequency such that the Q value and the antenna gain are greatly reduced. If in this case an isolation section 30k for partially dividing the path of the electric current, which is about the axis of the coil main body 10 is wound at an intermediate position in the circumferential direction of the metal frame 30 is arranged, the foregoing disadvantages can be canceled very effectively.

In the construction material of the metal frame 30 For example, aluminum or an aluminum alloy is comparatively excellent in strength and corrosion property and preferable in processing property, and therefore, it can be preferably used. The construction material of the metal frame 30 On the other hand, it may be further configured as an iron-system material. In this case, further, a non-magnetic material such. A stainless austenite system steel (aluminum or an aluminum alloy are also non-magnetic), however, a soft magnetic iron system material may also be used. The soft magnetic material is a ferromagnetic material and has a high magnetic permeability, and a radio wave magnetic field related to the antenna signal transmission and reception may be applied to the metal frame 30 to be focused. It is accordingly possible to contribute to the improvements in sensitivity and gain of the antenna. In the soft magnetic iron system material, it is possible to use a silicon steel plate, general carbon steel, an Fe-Ni alloy (eg permalloy, etc.) or a ferritic stainless steel etc. in addition to the electromagnetic soft magnetic iron (it can be further stated in that the electromagnetic soft magnetic iron and the ferrite stainless steel are advantageous from the standpoint of processing property).

In 8th is at the previous metal frame 30 in a mold along the annular path, in the circumferential direction of the coil jacket 20 is arranged is arranged, the previous isolation section 30k as a recess portion (hereinafter, recess portion 30k called) in which the metal frame 30 is omitted at a partial gap of the arrangement path. The isolation section 30k for partially dividing the electric current conducting path of the circumferential direction can be easily achieved by setting up the metal frame 30 be formed with a finished shape instead of the continuous ring shape and by spacing the end portions thereof by a constant length and by establishing a recess mode.

The outer shape lines of the spool main body 10 and the coil jacket 20 have rectangular shapes, and the metal frame 30 is arranged in a C-shape, which has a short side section 30s , which corresponds to the outer shape line of the rectangular shape, and two long side portions 301 with both ends of this short side section 30s are connected. The previous cutout section 30k is formed by using the entire space on the remaining short side of the rectangular shape outer molding line. If the C-shaped section, by integrating the two long side sections 301 and a short side section 30s is provided in the metal frame 30 is formed, the rigidity is raised with respect to a twist deformation of a frame surface as compared with a case partially divided and formed on each side of the rectangular shape, and warping which causes the twist deformation may be effectively hindered.

In 9 and 10 have metal frame 32 . 31 Main body portions 32a . 31a on, in a C-shape on the bottom surface of the coil sheath 20 are arranged. In at least two long side sections 321 . 311 are reinforcing rib sections 32b . 31c to the outer circumferential surface or the inner peripheral surface of the coil jacket 20 are uncovered in the main body sections 32a . 31a integrated into a mold having an L-shaped cut along with these main body sections 32a . 31a forms. Because the sectional shape of the metal frame 30 on the L-shape corresponding to the long side section 301 of the coil jacket 20 , which is easily reinforced in the Verziehungsversetzung is set, the bending stiffness of the same is raised, and the Warp deformation in the direction of the long sides can be effectively hindered.

In 9A and 9B is the reinforcing rib section 32b formed in a continuous C-shape, over a short side section 32s and two long side sections 321 with both ends of this short side section 32s' are connected. When the reinforcing rib section 32b is formed in this way, it is possible to raise the rigidity in terms of the torsional deformation of the frame surface made of the C-shaped portion. Both the main body section 32a as well as the reinforcing rib section 32b are formed in a shape which is laid over a partial gap, ie the short side portion 32s' which has both end portions of the remaining short side portions of two long side portions 321 forms, such that a reinforcing effect is further raised. The metal frame 32 is with the coil jacket 20 integrated by an insert molding, such that the main body portion 32a the same area as the outer surface of the bottom section 20b of the coil jacket 20 and the reinforcing rib portion 32b the same area as the outer surface of a sidewall portion 20w having. The reinforcing rib section 32b is here on the inner peripheral surface side of the coil shell 20b but may be further arranged on the outer peripheral surface side.

In the construction of 10A and 10B on the other hand, the reinforcing rib portion 31a only in two long side sections 311 of the main body portion 31a arranged. This mode has an advantage that manufacturing using press-forming, etc. is easy. The reinforcing rib section 31c is here on the outer peripheral surface side of the coil shell 20b arranged (but may also be arranged opposite).

In the construction of 11 is a metal frame 33 by forming recess portions 30k in four corner portions of the outer shape line of a rectangular shape and by dividing the metal frame 33 in four sections, separated by two long side sections 331 and two short side sections 33s through these recess sections 30k are constructed. According to this construction, there is an advantage in being able to cover all four sides of the coil shell 20 to reinforce the rectangular shape. The warp-preventing effect in this case can be further considerably achieved by building up each portion to have an L-shaped section including a main body portion 33a attached to the bottom surface of the coil jacket 20 is arranged, and further a reinforcing rib portion 33b That with this main body section 33a is integrated in a shape corresponding to the inner circumferential surface (or the outer peripheral surface) of the coil jacket 20 is exposed.

In building both 9 . 10 as well as 11 can the metal frame 34 be constructed to have the sectional shape of a C-shaped mode by integrating the main body portion 34a in the bottom section 20b of the coil mantels 20 and a pair of reinforcing rib portions 34b respectively. 34c that in two sidewall sections 20w are arranged as in 12 is shown formed.

The material of the reinforcing frame is not particularly limited if the modulus of elasticity of this material is higher than that of the resin ferrite comprising the coil sheath 20 forms. It is also possible, for example, an insulating inorganic material such. As glass, ceramics of alumina, etc., sintered soft magnetic ferrite, etc. to use. Further, the material of the reinforcing frame may be constituted by a resin composite material reinforced by a filler of glass, ceramics, etc. In this case, there is no fear of reduction of apparent inductance by inductive coupling of the coil main body 10 even if the reinforcement frame 37 in the mode of a continuous ring shape in the circumferential direction in the coil case 20 , as in 15 is shown, constructed as the reinforcing frame 37 becomes an insulator. The same is accordingly for the reinforcing effect of the coil jacket 20 excellent. In this case, the radio wave magnetic field related to the antenna signal transmission and reception can be applied to the metal frame 32 be concentrated when the reinforcement frame 37 by sintering soft magnetic ferrite and resin ferrite formed by resin-coupled soft magnetic ferrite powder. It is accordingly possible to contribute to the improvements in sensitivity and gain of the antenna.

The Present inventions have the following aspects.

An antenna coil has a flat coil body of an air core type having a thickness in an axial direction of the coil bobbin, and a coil support member disposed between the coil bobbin and a substrate as a mounting object of the antenna coil such that the coil bobbin is supported on a surface of the substrate. on. The thickness of the bobbin is smaller than a radius of a circle, a surface thereof being equal to an area of a region surrounded by an outline of a projected bobbin, the projected bobbin by projecting the bobbin on a projection plane which is perpendicular to the axial direction of the bobbin is provided. The coil support member is made of a resin-hardened, soft magnetic material.

at the previous coil are the sensitivity and the gain the antenna coil, since the coil support member is made of a resin-hardened, soft magnetic material is made. This is because of that the resin-hardened, soft magnetic Material is a ferromagnetic material and a high magnetic Having permeability, such that a magnetic field of an electric wave to participate is concentrated during transmission / reception of the antenna coil. The antenna coil therefore has a high sensitivity and a high antenna gain.

The resin hardened Soft magnetic material may alternatively be made of a soft magnetic powder Be made ferrite. The soft magnetic ferrite is a soft magnetic Oxide material with a spinel structure. The soft magnetic ferrite has a high magnetic permeability and a low eddy current loss on. The concentration of the magnetic field of the electric wave is therefore much improved. Corrosion resistance of the antenna coil is also improved.

Of the Soft magnetic ferrite is generally a kind of ceramic. The soft magnetic Ferrite therefore has a poor cutting behavior, that it is difficult to be a vehicle member with a thin one Plate and a vehicle member with to form a complicated shape. A manufacturing effort of a flat coil for attachment to a substrate is therefore larger. Of the Soft magnetic ferrite is also brittle. If a product of the soft magnetic ferrite is handled accordingly and the Produce a shock can the product will crack or break. At the previous one However, coil can be the carrier member readily formed to form a thin plate or have a complicated shape, since the coil support member from the resin-hardened, soft magnetic material is made. A production yield ratio of Coil continues to increase. The resin-hardened, soft magnetic material is here such that a powder of a soft magnetic ferrite is poured with resin, such that a Harzferrit is formed. at In this case, the resin-hardened, soft magnetic material readily using an injection molding process or a compression molding process synthesized by the liquid state of Resin is used when the resin is melted or in one uncured State is. Due to flexibility of the resin, the impact resistance is the carrier member, that from the resin-hardened, soft magnetic material is made improved. It will therefore, prevents the carrier member becomes cracked and breaks when the vehicle member is used.

The For example, a soft magnetic ferrite powder is a good one known spinel ferrite, such as. Mn-Zn ferrite and Ni-Zn ferrite. The resin-hardened, Soft magnetic material may alternatively be made of soft magnetic powder Iron material, such as. B. soft magnetic iron, permalloy and Permendul be prepared.

It It is preferable that a content of the soft magnetic powder Material in the resin-hardened, soft magnetic material is in a range between 5 vol .-% and 85 vol .-%. When the content of the soft magnetic material powder becomes smaller is 5 vol.%, the concentration of the magnetic field is electrical Wave not enough. When the content of the soft magnetic powder Material larger than 85 vol%, the flexibility of the resin-cured, soft magnetic material small, such that the coil carrier member can be cracked. In particular, when the resin and the powder of the soft magnetic material and a mixture thereof as a mass is injected to form the vehicle member becomes preferred that the content of the powder of the soft magnetic material is in a range between 5 vol.% and 65 vol.%. The salary of the powder of the soft magnetic material is preferably in a range between 10% by volume and 40% by volume. On the other hand the carrier member is formed by a die casting process, the content of the Powder of the soft magnetic material in a range between 50% by volume and 85% by volume. The concentration of the magnetic field of the electric wave is therefore much improved. The shape of the vehicle member here is a block or a leaf.

The resin for molding the soft magnetic material is preferably capable of being injected in a case where the resin-cured soft magnetic material is formed by the injection molding method, and has resistance to softening and deformation in a case where thermal hysteresis is applied to the resin Resin is applied when the antenna coil is attached to the substrate in a Lotaufschmelzverfahren. Specifically, the resin is, for example, polyphenylene sulfide (ie, PPS) having a melting point of 282 ° C, an upper temperature limit of about 240 ° C, and a thermal deformation temperature equal to or higher than 260 ° C. The upper temperature limit is defined herein as a temperature at which the resin is capable of being used continuously. The resin may alternatively comprise a thermoplastic polyimide having a Be melting point of 388 ° C. When the support member is formed by the die-pressing method, the resin may be a cross-linking type resin such as a resin. For example, epoxy resin. For example, the resin is mixed into the soft magnetic material in an uncured state or in a semi-cured state, and then pressed using a punch. The pressed resin with the soft magnetic material is hardened so that the resin-cured soft magnetic material is formed.

The coil support may alternatively comprise a ring portion which extends along a Circumferential direction of the bobbin is arranged, and the ring portion is made of the resin-hardened, produced soft magnetic material. The magnetic field of the electric Wave is therefore close to the bobbin effectively concentrated, such that the sensitivity and the profit the antenna coil are improved.

The coil support Alternatively, a coil shell with a coil receiving space for Picking up the bobbin be in the same. The coil jacket can be a ring molding, the the bobbin corresponds to, and the Spu lenmantel has a part, the resin-hardened, soft magnetic material is made. In this case, at that of the bobbin is accommodated in the coil jacket, the antenna coil as a separate part will be treated. Therefore, if the antenna coil is attached to the substrate, the assembly efficiency of Antenna coil improved. Furthermore, since the part of the coil jacket off the resin-hardened, soft magnetic material is made, the magnetic field is the electric Wave effectively concentrated at the antenna coil. The sensitivity and the gain of the antenna are therefore improved.

Of the Coil receiving space may alternatively be a groove with an opening, arranged on one side of the coil shell in the axial direction is. The ring molding of the coil jacket may have a bottom. The bottom of the coil jacket can be made of the resin-hardened, be produced soft magnetic material, and the bottom of the coil jacket corresponds to a circumference of the bobbin with a ring shape. at In this case, the bobbin, which is formed in another method for winding, without Another recorded in the coil receiving space from the opening of the groove and attached. In this case, the ring shaped body, the from the resin-hardened, soft magnetic material corresponding to the bobbin produced is under the bobbin disposed after the antenna coil is attached to the substrate is. The magnetic field of the electric wave is therefore in the antenna coil very concentrated.

Of the Ring shaped body the coil sheath may further alternatively comprise a pair of sidewalls, and each side wall may be at an edge of the bottom of the coil jacket be arranged such that the side walls and the bottom of the resin-hardened, soft magnetic material formed as a unit or made integrally are. The resin-hardened, Soft magnetic material is readily synthesized. Of the Coil jacket with the complicated shape with the groove for the receiving space is therefore readily formed. Not just the floor, but also the side walls of the coil jacket can furthermore from the resin-hardened, be made of soft magnetic material, such that the magnetic field the electric wave is very concentrated in the antenna coil. The coil sheath is preferably by the injection molding process educated.

The coil support Alternatively, a coil shell with a coil receiving space for Picking up the bobbin be in the same. The coil jacket can be a ring molding, the the bobbin corresponds to. The bobbin receiving space may have a groove with an opening be that on one side of the coil shell in the axial direction is arranged. The ring molding of the coil jacket may have a bottom. The bottom of the coil jacket can be a circumference of the bobbin correspond with a ring shape. The spool carrier member may further comprise a spool carrier ring, which is separated from the coil shell, have. The coil carrier ring can be arranged on the bottom of the coil jacket, such that the coil carrier ring is arranged between the coil shell and the bobbin. The coil carrier ring can be made of resin-hardened, soft magnetic Be made of material. In this case, the coil carrier ring separated from the coil shell, and the coil carrier ring is on the bottom of the Coil jacket arranged. The magnetic field of the electric wave is therefore effectively concentrated. The coil jacket can alternatively Further, from a material other than the resin-hardened, soft magnetic Be made of material. The coil case can, for example made of thermoplastic resin, such as. As PPS, and thermoplastic polyimide be prepared. In this case, the coil shell, for example formed by the injection molding process. The coil carrier ring For example, by the injection molding or a compression molding process be formed. When the coil carrier ring formed by the compression molding process, the content of the powder of the soft magnetic material be much higher, such that the Magnetic field of the electric wave at the antenna coil very concentrated is.

If a part of the coil jacket made of the resin-hardened, soft magnetic material is made the following points are obtained versus a case in which the coil carrier ring is separated from the coil shell. A coil-side connection the antenna coil can be positioned, i. at a sub stratseitigen Aligned connection of the substrate together with a solder member be. The substrate with the antenna coil is then in a Lotaufschmelzofen warmed such that the solder member is melted and the coil side Connection to the substrate side connection is soldered. The communication module is thus formed. While this method of forming the module can be applied to the antenna coil, which is attached to the substrate, warping occur because the reflow furnace has a temperature distribution, such that the temperature in the reflow oven is not homogeneous. But when a part of the coil jacket made of the resin-hardened, soft magnetic material is made, the soft magnetic material is as a filler mixed in the resin, such that the rigidity of the coil shell is improved. Thus, warping of the coil shell is prevented, even when the thermal stress is applied to the coil shell when the substrate together with the antenna coil in the Lotaufschmelzofen heated is to form the communication module. An error ratio of Communication module is therefore very reduced.

The Antenna coil may also alternatively a reinforcing frame, which consists of a Material with a higher modulus of elasticity as the same of the resin-hardened, soft magnetic material of the coil jacket is made have. The reinforcement frame is arranged on the bottom of the coil jacket. In this case Warping of the coil jacket is very prevented.

The Alternatively, the antenna coil may further comprise a reinforcing frame consisting of a Material with a higher modulus of elasticity as the same of the resin-hardened, soft magnetic material of the coil jacket is made have. The reinforcement frame is on the floor and at least one of the side walls of the Coil jacket arranged.

The coil support Alternatively, it may cover the region that is projected from the outline of the projectile bobbin surrounded, and the coil carrier member can be made from a sheet of resin-hardened, be produced soft magnetic material. In the sem case can the bobbin member through a calender casting method, a doctor blade method, an injection molding method or a die pressing method may be formed, such that the coil support member can be readily formed.

One Method for producing a communication module with an antenna coil and a transmitting / receiving circuit attached to a substrate are further provided. The antenna coil is connected to the transmitting / receiving circuit connected. The method comprises the steps of positioning a coil side connection of the antenna coil together with a A solder member for connecting between a substrate side terminal the substrate and the coil-side terminal of the antenna coil, and warming of the substrate together with the antenna coil in a solder reflow oven, such that the solder member between the coil-side terminal and the substrate-side terminal is melted and soldered, on. The antenna coil further comprises a flat bobbin of a Air core type with a thickness in an axial direction of the bobbin, and a coil carrier member, that between the bobbin and a substrate as a mounting object of the antenna coil is, such that the bobbin on a surface of the Substrate is worn on. The thickness of the bobbin is smaller than a radius of a circle, one surface thereof equal to a surface a region surrounded by an outline of a projected bobbin is, wherein the projected bobbin by projecting the Bobbin on a projection plane perpendicular to the axial direction of the bobbin is, is provided. The spool carrier member is a spool sheath with a bobbin receiving space for receiving the bobbin in same. The coil jacket has a ring shaped body, the corresponds to the bobbin, on, and the coil shell has a part made of the resin-hardened, soft magnetic material is made.

at the previous communication module are the sensitivity and the gain the antenna coil, since the coil support member is made of a resin-hardened, soft magnetic material is made. This is because of that the resin-hardened, soft magnetic material is a ferromagnetic material and a high magnetic permeability such that the magnetic field of an electric wave for Contributed to the transmission / reception of the antenna coil is concentrated. The antenna coil therefore has a high sensitivity and a high antenna gain on.

A wireless card-type device further includes a communication module having an antenna coil, a transmitting / receiving circuit connected to the antenna coil, and a substrate, and a card-type sheath. The antenna coil has a flat bobbin one An air core type having a thickness in an axial direction of the bobbin, and a coil support member disposed between the coil bobbin and a substrate as a mounting object of the antenna coil such that the coil bobbin is supported on a surface of the substrate. The thickness of the bobbin is smaller than a radius of a circle, a surface thereof being equal to a surface of a region surrounded by an outline of a projected bobbin, the projected bobbin projecting the bobbin onto a plane perpendicular to an axial plane Direction of the bobbin is provided. The coil support member is made of a resin-hardened, soft magnetic material. The bobbin has an axis which coincides with a vertical line of the substrate. The card type cladding accommodates the communication module in such a manner that a thickness direction of the substrate coincides with a thickness direction of the card type cladding.

at the previous wireless device are the sensitivity and the gain of the antenna coil improves as the coil support member made of a resin-hardened, soft magnetic material is made. This is because of that the resin-hardened, soft magnetic material is a ferromagnetic material and has a high magnetic permeability, such that the Magnetic field of an electric wave to assist in transmitting / receiving the antenna coil is concentrated. The antenna coil therefore has a high sensitivity and a high antenna gain. The wireless Card type device is further for a wireless access key of a Suitable for self-propelled vehicles. The wireless card type device is also thin. It is therefore, prefer the wireless card type device into a wallet or the like to lay.

Even though the invention with reference to preferred embodiments the same is described, it is obvious that the invention is not to the preferred embodiments and the structure is limited. The invention is intended to be various modifications and equivalents Cover arrangements. Despite the preferred different combinations and configurations are additional others Combinations and configurations that are more, less or only have a single element, also within the mind and the scope of the invention.

Claims (23)

Antenna coil with: a flat bobbin ( 10 ) of an air core type having a thickness in an axial direction of the bobbin (FIG. 10 ); and a spool carrier member ( 20 . 51 ), between the bobbin ( 10 ) and a substrate ( 17 ) is arranged as a mounting object of the antenna coil, such that the bobbin ( 10 ) on a surface of the substrate ( 17 ), wherein the thickness of the bobbin ( 10 ) is smaller than a radius of a circle, a surface thereof being equal to an area of a region surrounded by an outline of a projected bobbin, the projected bobbin being formed by projecting the bobbin (FIG. 10 ) on a projection plane which is perpendicular to the axial direction of the bobbin ( 10 ) is provided, and the spool carrier member ( 20 . 51 ) is made of a resin-hardened, soft magnetic material. An antenna coil according to claim 1, wherein the resin-hardened, soft magnetic Material made from a soft magnetic ferrite powder is. An antenna coil according to claim 1 or 2, wherein the coil support member ( 20 . 51 ) a ring section ( 24 . 20b . 20w . 120 ), which along a circumferential direction of the bobbin ( 10 ) is arranged, and the ring portion ( 24 . 20b . 20w . 120 ) is made of the resin-hardened, soft magnetic material. An antenna coil according to any one of claims 1-3, wherein the coil support member ( 20 . 51 ) a coil sheath ( 20 . 51 . 120 ) with a coil receiving space ( 24 ) for receiving the bobbin ( 10 ) is in the same, the coil sheath ( 20 . 51 . 120 ) a ring molding ( 20 . 120 ), the bobbin ( 10 ), and the coil sheath ( 20 . 51 . 120 ) has a part made of the resin-cured soft magnetic material. An antenna coil according to claim 4, wherein the coil receiving space ( 24 ) a groove ( 24 ) is provided with an opening which on one side of the coil jacket ( 20 . 51 . 120 ) is arranged in the axial direction, the annular shaped body ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a floor ( 120b ), the soil ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is made of the resin-hardened, soft magnetic material, and the bottom ( 20b ) of the coil jacket ( 20 . 51 . 120 ) a circumference of the bobbin ( 10 ) corresponds to a ring shape. An antenna coil according to claim 5, wherein the ring molding ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a pair of side walls ( 20w ), and each side wall ( 20w ) at one edge of the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is arranged such that the side walls ( 20w ) and the ground ( 20b ) are made of the resin-hardened, soft magnetic material in one piece. An antenna coil according to claim 3, wherein the coil support member ( 20 . 51 ) a coil sheath ( 20 . 51 . 120 ) with a coil receiving space ( 24 ) for receiving the bobbin ( 10 ) is in the same, the coil sheath ( 20 . 51 . 120 ) a ring molding ( 20 . 120 ), the bobbin ( 10 ), the coil receiving space ( 24 ) a groove ( 24 ) is provided with an opening which on one side of the coil jacket ( 20 . 51 . 120 ) is arranged in the axial direction, the annular shaped body ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a floor ( 20b ), the soil ( 20b ) of the coil jacket ( 20 . 51 . 120 ) a circumference of the bobbin ( 10 ) corresponds to a ring shape, the coil carrier member ( 20 . 51 ) further a coil carrier ring ( 50 ), which of the coil shell ( 20 . 51 . 120 ) is separated, the coil carrier ring ( 50 ) on the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is arranged, such that the coil carrier ring ( 50 ) between the coil shell ( 20 . 51 . 120 ) and the bobbin ( 10 ) is arranged, and the coil carrier ring ( 50 ) is made of the resin-hardened, soft magnetic material. An antenna coil according to claim 5, further comprising: a reinforcing frame (16); 30 - 34 . 37 ) made of a material having a modulus of elasticity greater than that of the resin-hardened, soft-magnetic material of the coil shell ( 20 . 51 . 120 ) is made, wherein the reinforcing frame ( 30 - 34 . 37 ) on the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is arranged. An antenna coil according to claim 6, further comprising: a reinforcing frame (16); 30 - 34 . 37 ) made of a material having a modulus of elasticity greater than that of the resin-hardened, soft-magnetic material of the coil shell ( 20 . 51 . 120 ) is made, wherein the reinforcing frame ( 30 - 34 . 37 ) on the ground ( 20b ) and at least one of the side walls ( 20w ) of the coil jacket ( 20 . 51 . 120 ) is arranged. An antenna coil according to claim 3, wherein the coil support member ( 20 . 51 ) covers the region surrounded by the outline of the projected coil bobbin, and the coil support member (FIG. 20 . 51 ) is made of a sheet of the resin-cured soft magnetic material. Method for producing a communication module with an antenna coil ( 1 ) and a transmitting / receiving circuit ( 14 ) attached to a substrate ( 17 ), the antenna coil ( 1 ) with the transmitting / receiving circuit ( 14 ), comprising the following steps: positioning a coil-side connection ( 21 ) of the antenna coil ( 1 ) together with a solder member for connecting between a substrate side terminal ( 134 ) of the substrate ( 17 ) and the coil-side connection ( 21 ) of the antenna coil ( 1 ); and heating the substrate ( 17 ) together with the antenna coil ( 1 ) in a Lotaufschmelzofen, such that the solder member between the coil-side terminal ( 21 ) and the substrate-side connection ( 134 ) is melted and soldered, wherein the antenna coil ( 1 ) further comprises: a flat air core type bobbin ( 10 ) having a thickness in an axial direction of the bobbin ( 10 ); and a coil carrier member ( 20 . 51 ), between the bobbin ( 10 ) and a substrate ( 17 ) as a mounting object of the antenna coil ( 1 ) is arranged, such that the bobbin ( 10 ) on a surface of the substrate ( 17 ), wherein the thickness of the bobbin ( 10 ) is smaller than a radius of a circle, a surface thereof being equal to an area of a region surrounded by an outline of a projected bobbin, the projected bobbin being formed by projecting the bobbin (FIG. 10 ) on a projection plane which is perpendicular to the axial direction of the bobbin ( 10 ) is provided, the Spulenträgerbauglied ( 20 . 51 ) a coil sheath ( 20 . 51 . 120 ) with a coil receiving space ( 24 ) for receiving the bobbin ( 10 ) is in the same, the coil sheath ( 20 . 51 . 120 ) a ring molding ( 20 . 120 ), the bobbin ( 10 ), and the coil sheath ( 20 . 51 . 120 ) has a part made of the resin-cured soft magnetic material. The method of claim 11, wherein the coil receiving space ( 24 ) a groove ( 24 ) is provided with an opening which on one side of the coil jacket ( 20 . 51 . 120 ) is arranged in the axial direction, the annular shaped body ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a floor ( 20b ), the soil ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is made of the resin-hardened, soft magnetic material, and the bottom ( 20b ) of the coil jacket ( 20 . 51 . 120 ei nem circumference of the bobbin ( 10 ) corresponds to a ring shape. Process according to Claim 12, in which the ring molding ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a pair of side walls ( 20w ), and each side wall ( 20w ) at one edge of the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is arranged such that the side walls ( 20w ) and the ground ( 20b ) are made in one piece from the resin-hardened, soft magnetic material. The method of claim 12, further comprising: a reinforcing frame ( 30 - 34 . 37 ) made of a material having a modulus of elasticity greater than that of the resin-hardened, soft-magnetic material of the coil shell ( 20 . 51 . 120 ) is produced, wherein the reinforcing frame ( 30 - 34 . 37 ) on the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is arranged. A wireless card type device comprising: a communication module ( 3M ) with an antenna coil ( 1 ), a transmitting / receiving circuit ( 14 ) connected to the antenna coil ( 1 ) and a substrate ( 17 ); and a card type sheath ( 18 ), wherein the antenna coil ( 1 ) has the following features: a flat bobbin ( 10 ) of an air core type having a thickness in an axial direction of the bobbin (FIG. 10 ); and a coil carrier member ( 20 . 51 ), between the bobbin ( 10 ) and a substrate ( 17 ) as a mounting object of the antenna coil ( 1 ) is arranged, such that the bobbin ( 10 ) on a surface of the substrate ( 17 ), wherein the thickness of the bobbin ( 10 ) is smaller than a radius of a circle, a surface thereof being equal to an area of a region surrounded by an outline of a projected bobbin, the projected bobbin being formed by projecting the bobbin (FIG. 10 ) on a projection plane which is perpendicular to an axial direction of the bobbin ( 10 ) is provided, the Spulenträgerbauglied ( 20 . 51 ) is made of a resin-hardened, soft magnetic material, the bobbin ( 10 ) has an axis aligned with a vertical line of the substrate ( 17 ) and the card type sheath ( 18 ) the communication module ( 3M ) receives in such a manner that a thickness direction of the substrate ( 17 ) with a thickness direction of the card type sheath ( 18 ) coincides. A wireless card-type device according to claim 15, in which the resin-hardened, soft magnetic material made of a soft magnetic powder Ferrite is made. A wireless card-type device according to claim 15 or 16, wherein the coil support member (10) 20 . 51 ) a ring section ( 24 . 20b . 20w . 120 ), which along a circumferential direction of the bobbin ( 10 ) is arranged, and the ring portion ( 24 . 20b . 20w . 120 ) is made of the resin-hardened, soft magnetic material. A wireless card-type device according to any one of claims 15-17, wherein the coil carrier member (10) 20 . 51 ) a coil sheath ( 20 . 51 . 120 ) with a coil receiving space ( 24 ) for receiving the bobbin ( 10 ) is in the same, the coil sheath ( 20 . 51 . 120 ) a ring molding ( 20 . 120 ), the bobbin ( 10 ), and the coil sheath ( 20 . 51 . 120 ) has a part made of the resin-cured soft magnetic material. A wireless card-type device according to claim 18, wherein the coil receiving space (FIG. 24 ) a groove ( 24 ) is provided with an opening which on one side of the coil jacket ( 20 . 51 . 120 ) is arranged in the axial direction, the annular shaped body ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a floor ( 20b ), the soil ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is made of the resin-hardened, soft magnetic material, and the bottom ( 20b ) of the coil jacket ( 20 . 51 . 120 ) a circumference of the bobbin ( 10 ) corresponds to a ring shape. A wireless card-type device according to claim 19, wherein the annular shaped body ( 20 . 120 ) of the coil jacket ( 20 . 51 . 120 ) a pair of side walls ( 20w ), and each side wall ( 20w ) at one edge of the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) is arranged such that the side walls ( 20w ) and the ground ( 20b ) are made of the resin-hardened, soft magnetic material in one piece. A wireless card-type device according to claim 19, further comprising: a reinforcing frame ( 30 - 34 . 37 ) made of a material having a modulus of elasticity greater than that of the resin-hardened, soft-magnetic material of the coil shell ( 20 . 51 . 120 ) is made, wherein the reinforcing frame ( 30 - 34 . 37 ) on the ground ( 20b ) of the coil jacket ( 20 . 51 . 120 ) arranged is. A wireless card-type device according to claim 20, further comprising: a reinforcing frame (16); 30 - 34 . 37 ) made of a material having a modulus of elasticity greater than that of the resin-hardened, soft-magnetic material of the coil shell ( 20 . 51 . 120 ) is made, wherein the reinforcing frame ( 30 - 34 . 37 ) on the ground ( 20b ) and at least one of the side walls ( 20w ) of the coil jacket ( 20 . 51 . 120 ) is arranged. A wireless card-type device according to claim 17, wherein the bobbin member ( 20 . 51 ) covers the region which is surrounded by the outline of the projected bobbin, and the coil support member (FIG. 20 . 51 ) is made of a sheet of the resin-cured soft magnetic material.