RU178107U1 - PORTABLE RECEIVER - Google Patents

Abstract

The utility model relates to portable transceivers, in particular to wearable radio stations. The device comprises a housing (1), an antenna (3), a battery (12), a display (4) installed in the front of the housing (1), covered with a protective glass (2), a keypad (6) and electronic components located in the housing . A shielding layer (5) is applied to the inner surface of the housing (1), and an optically transparent electrically conductive coating (10) is applied to the inner surface of the protective glass (2). In this case, the shielding layer (5) of the housing and the electrically conductive coating (10) are electrically connected by means of a frame (11) of electrically conductive material mounted on the inside of the perimeter of the protective glass (2). The technical result is an increase in the electromagnetic compatibility of the components of the device and the intelligence of the device.

Description

The utility model relates to portable transceivers, in particular, wearable radio stations.

When designing portable transceivers, or two-way radios, among others, there is the problem of electromagnetic compatibility (EMC) of the device components caused by the occurrence of electromagnetic interference.

A variety of designs of portable transceivers are known, the layout of which is designed to provide optimal placement of controls and user interface elements on one or more sides of the device and at the same time meet the requirements for the size and ergonomics of the device. In modern portable transceivers, an important role is played by the display as a means of displaying the status of the device and the information received on it, settings and after-sales service. Considering the mentioned requirements for the device’s dimensions and its ergonomics, as well as achievements in the field of creating modern displays with high resolution and low power consumption, there is a tendency to increase the size of the display of the transceiver.

On the other hand, an increase in the density of the components of the transceiver in the housing, which is associated, inter alia, with giving the device new functionality, means an increasing number of sources of electromagnetic radiation that must be shielded if special requirements are imposed on the transceiver for the device’s EMC, and more - his intelligence. Therefore, the presence of a large display, which, as a rule, occupies a significant part of the front side of the device case, is undesirable, since this area of the case is usually unscreened. As an example, you can cite a modular multilateral radio station according to the patent of the Russian Federation for invention No. 2442289, in the description of which screening of the display area of the device is not mentioned at all.

A known design of a transceiver device including a housing, an antenna, a battery, a display with a protective glass and electronic components located inside the housing is disclosed in the RF patent for utility model No. 108697. In order to reduce side electromagnetic radiation and increase electromagnetic compatibility on the inner surface of the housing of the transceiver device, a shielding protective layer is made. At the same time, a transparent shielding coating of metallized material, mesh or fabric is also applied on the inner surface of the glass. According to the description of the said patent, the technical result consists in reducing the radiation power flux density of the device to a minimum, providing more effective protection without significant deterioration in communication quality or distortion of the audio signal, as well as improving the usability of the device in a protective coating.

The well-known solution according to the patent of the Russian Federation No. 108697 adopted as the closest analogue of this utility model.

Since the protective shielding layer, made on the inner surface of the closest analogue case, is not connected to the transparent shielding coating in any way, the latter can act as a secondary emitter for electromagnetic radiation generated by the internal components of the transceiver. Therefore, the closest analogue has the same drawback as the aforementioned transceiver according to the RF patent No. 2442289, namely, it has a low EMC component and intelligence protection.

The objective of the utility model is to eliminate this drawback of known analogues and the closest analogue.

The technical result of the utility model is to increase the electromagnetic compatibility of the components of the device and the intelligence of the device as a whole.

The problem is solved, and the claimed technical result is achieved in the design of a portable transceiver due to the fact that the device contains a housing, antenna, battery, a display installed in the front of the case, covered with a protective glass, a keypad and electronic components placed in the case. In this case, a shielding layer is applied to the inner surface of the housing, and an optically transparent electrically conductive coating is applied to the inner surface of the protective glass. The shielding layer of the housing and the electrically conductive coating are electrically connected by means of a frame of electrically conductive material mounted on the inside along the perimeter of the protective glass.

The claimed design of a portable transceiver device provides full screening of the device components and reconnaissance device.

Preferably, if the electrical connection of the shielding layer of the housing and the electrically conductive coating is made using electrically conductive glue. The connection of this type is not only easy to implement, but also highly reliable, especially in the harsh operating conditions of the device. However, other types of electrical connection can be used, for example, using conductive spring elements, soldering, screw connection, etc.

The frame can be made of copper - this material, being ductile, also provides reliable contact of the connected parts, while maintaining it under various operating conditions.

It is preferable if the protective glass is made of shockproof material, as this guarantees the integrity of the electrically conductive coating applied to the protective glass.

To ensure the integrity of the protective glass and, therefore, the electrically conductive coating, a wear-resistant coating may be applied to the outer surface of the protective glass, preferably being anti-reflective.

Next, one of the possible options for the implementation of the claimed utility model is explained with reference to the accompanying figures, where:

in FIG. 1 shows a General view of the claimed device;

in FIG. 2 shows the front panel of the device case from the back;

in FIG. 3 schematically shows an embodiment of the connection of the housing and the protective glass.

The claimed transceiver device comprises a housing (1), a protective glass (2) located in the front of the housing, a transceiver antenna (3) installed in the upper part of the housing, electronic components located inside the housing, and a liquid crystal display (4) mounted under the protective glass ( 2).

The housing (1) has the shape of a substantially rectangular parallelepiped and is made of plastic with an inner metal shielding layer (5), for example, applied in the form of a conductive coating or made in the form of a thin conductive foil.

On the forming planes of the casing there are control and switching bodies: a keypad (6), acoustic channels (7) for the built-in speaker, a group of multifunction keys (8) protected by a silicone casing, a mechanical interface for attaching external peripherals (not shown) and others .

The liquid crystal display (4) displays the current status of the transceiver, communication modes, exact time, battery charge, product response to operator control actions, and other information.

The protective glass (2) covering the display (4) can be made by impact-resistant technology and, preferably, has a double-sided coating. On the outside of the glass (2), an anti-reflective wear-resistant coating (9) can be applied, which serves to increase the contrast of the displayed information and eliminate the effect of spurious illumination from external light sources, and also has an increased resistance to abrasion. An optically transparent conductive coating (10) is applied to the glass from the inside, which serves to prevent the influence of external electromagnetic radiation on the electronic components inside the product, as well as to suppress the output of electromagnetic radiation generated by the components of the device. This allows you to get a higher degree of failure-free operation of the device, as well as significantly weaken the radiation of electromagnetic radiation from electronic components into the surrounding space, which increases the EMC of the product and its intelligence.

The electronic components located inside the housing (1) are made by a method known to a person skilled in the art. In particular, the electronic components of the transceiver device can be made in the form of modules organized by mezzanine technology, eliminating the presence of unreliable wire connections between functional modules. Progressive loop connections of the functional modules to each other, made on the basis of polyamide flexible flat printed cables, as well as rigid-flexible printed circuit boards, can be used. Functional modules are based on multilayer printed circuit boards with a high trace density of conductors and the use of two-sided surface mounting of highly integrated electrical and radio elements.

A removable battery (12) is installed in the back of the case.

In the claimed transceiver device, reliable electrical contact of the electrically conductive coating (10) of the protective glass (2) with the shield layer (5) of the housing (1) is provided. The specified electrical contact is provided using a flexible part in the form of an electrically conductive frame (11), connected, for example, by means of an electrically conductive adhesive, to the inner peripheral part of the protective glass (2), which is invisible to the user of the device, i.e. along the perimeter of the protective glass (2), and the shielding layer (5) of the housing (1). This allows you to get almost seamless, electrically closed circuit screening of the transceiver and significantly increase its EMC and intelligence. The frame (11) is preferably made of copper, which easily takes shape when sufficiently small forces are applied and thus provides reliable electrical contact around its entire perimeter. The frame (11) can pass along the entire perimeter of the protective glass (2), forming a completely closed loop, or partially, forming an open loop. The first performance is more preferable for the purpose of increasing EMC and intelligence.

Thus, the claimed portable transceiver device can significantly increase the electromagnetic compatibility of the components of the device and the intelligence of the device as a whole.

Claims (7)

1. A portable transceiver device comprising a housing (1), an antenna (3), a battery (12), a display (4) mounted in front of the housing (1), covered with a protective glass (2), a keypad (6) and placed in the case of electronic components, while on the inner surface of the housing (1) applied a shielding layer (5), and on the inner surface of the protective glass (2) applied optically transparent conductive coating (10), characterized in that the shielding layer (5) of the housing and an electrically conductive coating (10) electrically with connected to each other by means of a frame (11) of electrically conductive material mounted on the inner side around the perimeter of the protective glass (2). 2. The device according to claim 1, characterized in that the frame (11) is glued using electrically conductive glue. 3. The device according to claim 1, characterized in that the frame (11) is made of copper. 4. The device according to p. 1, characterized in that the frame (11) is made passing along the entire perimeter of the protective glass (2), forming a closed loop. 5. The device according to p. 1, characterized in that the frame (11) is made passing along the perimeter of the protective glass (2), forming an open loop. 6. The device according to claim 1, characterized in that an anti-reflective wear-resistant coating (9) is applied to the outer surface of the protective glass (2). 7. The device according to claim 1, characterized in that the protective glass (2) is made shockproof.

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