DE19923524C1 - Antenna, for mobile transmitters/receivers working with different frequencies, comprises two body sections with mounting and geometric surface structures using injection molding and surface coating - Google Patents

Abstract

Production of an antenna, comprises an antenna body, produced by injection molding to give two body sections of a different appearance. The antenna body is metallized so that the first body section is wholly metallized, and the second body section is metallized selectively. The antenna body is shaped to give a mounting and a geometric structure to optimize the antenna working and power. Production of an antenna, comprises an antenna body (ANT), produced by injection molding to give two body sections (TK1,TK2) of a different appearance on separate and parallel longitudinal axes (LA1 - shown, LA2 - not shown). The antenna body is covered with a metal cladding so that the first body section (TK1) is wholly metallized, and the second body section (TK2) is metallized selectively. The antenna body is shaped to give a mounting (GW) and a geometric structure (ST) to optimize the antenna working and power.

Description

The invention relates to a method for producing a Antenna for transmitting / receiving devices.

In radio communication systems, messages (for example wise language, image information or other data) with the help transmitted by electromagnetic waves. The blasting of the electromagnetic waves occur through antennas, the Carrier frequencies in the provided for the respective system NEN frequency band.

Wire antennas are used for this purpose, for example. disadvantage the wire antennas are relatively complex to manufacture, which first creates a wire winding and a thread and then the wire winding around the thread must be sprayed to make mechanical contact a transceiver and electrical contact to enable a radio part of the transceiver. When it comes to the production of the wire winding, compromises are made the producibility forced a suboptimal antennas performance.

Since in addition to the requirement that in the case of transmitting / receiving devices The dimensions of the antenna must be limited, in particular with mobile transmitting / receiving devices, also increasingly Measure the demand for the send / receive capability in un different frequency ranges ("dual-band", "multi- Band "devices) arises, antennas are needed, which in meh other frequency ranges can be used.

But this also means a multiplication of costs, because at least two radio-active antenna geometries  manufactured and optimized with regard to the antenna performance have to.

The high competitive pressure in the end device market, in particular in mobile devices, but forces the manufacturers of such Devices that are as cost-optimized as possible with the same or to produce improved device quality.

From WO 97/27642 is a cylindrical ceramic antenna, with a partial metallization based on a rotation sym metric, hollow body is attached, being from a Contact point on the top of the ceramic antenna is a wire is attached electrically conductive and through the cylindrical Cavity of the ceramic body to the underside of the ceramic body is led.

The invention has for its object a simple and Inexpensive method of manufacturing an antenna for Transmission / reception facilities specify.

This object is achieved by the features of claim 1 solved.

According to the manufacturing process according to the invention - according to An saying 1 - becomes an antenna body in an injection molding process manufactured, which is composed of two partial bodies, the first partial body being a body that is designed as a means of attachment, and in which second part body by an extension of the first part body acts, wherein a first longitudinal axis of the first partial body parallel to a second longitudinal axis of the second partial body runs. The antenna body is in a further step covered with a metal layer such that the first part completely metallized and the second part for production a structure as an adapted geometry for optimization the antenna effect / performance is selectively metallized.  

The main advantages of the process are the one inexpensive to manufacture, as a fastener designed with one to optimize antenna performance Adapted geometry (structure) having antenna from one Component is realized, with the necessary work Witnesses and materials in the purchase and use are inexpensive and on the other hand the method of production adapt the structure to optimize the antennas Kung- / achievement permits.

The main advantage of the training according to claim 2 is one by the meander, which is a form of a flat surface Chen structure "Patch structure" represents, acquired adaptations freedom, as variations of the meandering structure to opti antenna effect / performance after injection molding possible are.

An essential gate part of the training according to claim 3 is an advanced way to optimize antennas effect / performance through an arrangement of two radio technology effective antenna areas "double patch" on an antenna body.

A major advantage of the training according to claim 4 is the simple production - one-time production of a spray mold - the structure, especially the structure of both surfaces Chen a "double patch" arrangement, through openings, never so are lectured that an optimal adaptation of the antenna for Optimization of the antenna effect / performance is given.

The advantage of further training according to claim 5 is the possibility ability to insert the antenna in transmitting / receiving devices screws that are used to attach and connect an antenna ne opening with an internal thread.  

The advantage of further training according to claim 6 is the possibility ability to insert the antenna in transmitting / receiving devices screws that are used to attach and connect an antenna have a cylindrical pin with an external thread.

The main advantages of further training according to claim 7 are the cost-effective and time-optimized production of the ange matched structure, since no additional materials ver must be applied and only one further step - the end burn the metal layer - necessary for its production is, the laser is also fast and precise Guaranteed implementation of this step.

A major advantage of the further training according to claim 8 to 10 is a cost reduction by using be already for the manufacture of semiconductor / Receiving tools and materials.

An embodiment of the invention will be explained with reference to FIGS. 1a to 1c. Show:

FIG. 1a is a front view of an inventive transformants nenkörpers,

FIG. 1b is a side view of the antenna according to the invention the body,

Fig. 1c the top view of the antenna body according to the invention.

Figs. 1a to 1c show various views of a metallizable plastic - as known for example from the "molded interconnect device" preparation - in the injection molding manufactured antenna body ANT, the optically into a first part body TK1 having a first longitudinal axis LA1 and distinguishes a second partial grain TK2 with a second longitudinal axis LA2; whereby in the injection molding process, the plastic is injected in a non-solid state of aggregation into a mold, which usually consists of two partial shells and has a negative image of the antenna body ANT, and after the plastic has transitioned into a solid unit, the partial shells of the mold are removed. The plastic blank of the antenna body ANT is then removed.

The antenna body ANT shown is predominantly with a Metal layer, for example made of copper, coated, wherein the metallization following masking by the Be range of the second partial body TK2, which has no metal layer should have occurred.

After copper metallization, the masked second Partial body ANT freed from the masking, the demas places in contrast to the rest of the second part of the body are free of copper by TK2.

Alternatively, it can be used to create a selective metallization a "photo-imaging" known from semiconductor manufacturing - Methods are used, the areas of the An body, which should have a metal layer, after he complete metallization, first with a photore resistive varnish and then exposed. The exposure creates resistance to an etch medium generated, in which the antenna body ANT subsequently is dipped. The unprotected metal layer is removed etched and the varnish removed from the protected layer.

Alternatively used to manufacture the antenna body ANT non-metallizable plastic used, so the selek tive metallization by selective application of a varnish take place, which is characterized in that metal on it sticks because, for example, the finest metal par has particles. After applying this so-called "primary" - Paint the antenna body ANT with the metal layer (Copper) plated.  

In a further alternative, masking of the Antenna body ANT are omitted, so that the antennas body is initially completely coated with copper. On then the places that do not have a metal layer on them should point, processed by a laser such that the applied metal is burned away by the laser.

The locations of the second partial body TK2, which are coated with copper, form a structure ST. The electrically conductive and thus radio-active structure ST to be seen in FIG. 1 is a meander. This meander is adapted depending on the area of application of the antenna body ANT, for example in mobile telecommunications, in such a way that it ensures optimization of the antenna effect / performance.

Alternatively, the structure ST can be configured such that on opposite sides of the second partial body TK2 weighing a metal layer is applied. This as "Double-Patch" known arrangement allows z. B. the adapt Antenna solution for optimal reception of the antennas on two different frequencies, so that this antenna z. B. for "dual Band "handsets can be used.

The geometry of the structure ST can alternatively be by Optimizing the antenna effect / performance suitably arranged te openings, for example slots and / or holes be witnessed that already correspond with the injection molding appropriate training of the form or by drilling and / or milling generated after injection molding.

The first partial body TK has a thread GW which has already been produced by the shape required for injection molding. This thread GW can either be designed as an external thread ( FIGS. 1a-1c) in order to be able to be screwed into a threaded bushing, or as an internal thread in order to be able to be screwed onto a cylindrical pin with an external thread; in both cases the axis of rotation of the thread GW is congruent with the first longitudinal axis LA1.

The first partial body TK1 and with it the thread GW fully metallized, ensuring that the metallic structure ST of the second partial body TK2 elect risch ver with the metal layer of the first partial body TK1 is bound so that a transceiver into which the Antenna body ANT is screwed, an electrically conductive and therefore effective radio contact to the structure ST receives.

Alternatively, the first partial body TK1 can be configured in this way be that a mechanical and electrical connection to the Transmitting / receiving device is also possible without thread GW, for example by snapping and snapping.

From Fig. 1b and 1c it can be seen that the second longitudinal axis (LA2) runs parallel - in the extreme case congruent - to the first longitudinal axis (LA1).

From FIGS. 1a to 1c it can be seen that the geometry of the second partial body TK2 is in particular a cuboid, since the flat surfaces are favorable for the generation of the structure ST, in particular in the case of "double patch" - Arrangement and meander geometry, which is a specific form of "patch geometry".

In the exemplary embodiment (FIGS . 1a to 1c), the first partial body TK1 has a rotationally symmetrical geometry, since it carries a thread GW.

Claims (10)

1. Method for producing an antenna for transmitting / receiving devices with the following features:

• a) an antenna body (ANT) is formed from a plastic in a first process step in the injection molding process, which consists of a first part body (TK1) with a first longitudinal axis (LA1) and a second part body (TK2) with a second longitudinal axis (LA2) , wherein the second longitudinal axis (LA2) runs parallel to the first longitudinal axis (LA1) and the first partial body (TK1) is designed as a means (GW) for fastening,
• b) the antenna body (ANT) is covered in a second process with a metal layer in such a way that the first partial body (TK1) is completely metallized and the second partial body (TK2) for producing a structure (ST) of an antenna conductor.

2. The method according to claim 1, characterized in net that the structure (ST) is applied as a meander. 3. The method according to claim 1, characterized in net that the structure (ST) on two opposite surfaces "Double patch" of the second partial body (TK2) applied becomes. 4. The method according to claim 1 or 3, characterized records that the structure (ST) in the second partial body (TK2) at least partially penetrating openings is applied. 5. The method according to any one of the preceding claims, characterized in that

• a) the first partial body (TK1) is designed to be rotationally symmetrical,
• b) during injection molding a as the fastener (GW) formed from thread on the outer surface of the first part body (TK1) is produced, the longitudinal axis of the thread (GW) being congruent with the first longitudinal axis (LA1).

6. The method according to any one of claims 1 to 4, characterized in that

• a) the first partial body (TK1) is designed to be rotationally symmetrical,
• b) the first partial body (TK1) is generated with a rotationally symmetrical recess, the axis of rotation of the recess being congruent with the first longitudinal axis (LA1) and the depth of which corresponds to a maximum of the length of the first partial body (TK1), the direction of the recess being parallel runs to the first longitudinal axis (LA1),
• c) during injection molding, at least in a part of the inner walls of the depression, a thread (GW) formed as the fastening means (GW) is produced, the axis of rotation of which is congruent with the first longitudinal axis (LA1).

7. The method according to any one of the preceding claims, characterized in that

• a) a metalizable plastic is used for the injection molding of the antenna body (ANT),
• b) the antenna body (ANT) is completely metallized in a first step,
• c) the structure (ST) of the second partial body (TK2) is produced in a second step by burning out the metallization using a laser.

8. The method according to any one of claims 1 to 6, characterized in that

• a) a metalizable plastic is used for the injection molding of the antenna body (ANT),
• b) the structure (ST) of the second partial body (TK2) is generated in such a way that selected areas of the second partial body (TK2) are masked in a first step,
• c) the antenna body (ANT) is coated with a metal layer in a second step,
• d) the masking is removed in a third step, where the areas freed from the masking have no metal layer after removal.

9. The method according to claim 8, characterized in that

• a) a metalizable plastic is used for the injection molding of the antenna body (ANT),
• b) the antenna body (ANT) is coated with a metal layer in a first step,
• c) the structure (ST) of the second partial body (TK2) is generated in such a way that selected areas of the second partial body (TK2) are masked in a second step with a photoresistive layer,
• d) the antenna body (ANT) is exposed in a third step, so that the photoresistive layer is resistant to etching agents,
• e) the antenna body (ANT) is immersed in the etchant in a fourth step, the areas of the antenna body (ANT) which are not covered with a photoresistive layer being freed from the metal layer,
• f) the masking is removed in a fifth step, where the areas freed from the masking have a metal layer after removal.

10. The method according to claim 8, characterized in that

• a) a non-metallizable plastic is used for the injection molding of the antenna body (ANT),
• b) the structure (ST) of the second partial body (TK2) such that it is generated that selected areas of the second partial body (TK2) in a first step masked with a lacquer which is designed such that a metal layer adheres to it become,
• c) the antenna body (ANT) is coated with a metal layer in a second step, the surfaces which are covered with the lacquer having a metal layer.