BE1028372A1 - SCREEN EQUIPMENT - Google Patents

Abstract

A screen device comprises a roll-up screen, an electric motor for rotating the roll-up screen, which motor is electrically powered by one or more wires, a power cable comprising one or more wires, an electrical coupling for coupling the wires of the power cable to the wires of the motor, which coupling comprises a male and a female component which are electrically and mechanically coupleable to each other. The male component comprises a printed circuit board (PCB) comprising at least one lip on which at least one printed conductor is provided and which at least one printed conductor is electrically coupled to at least one wire of a first of the motor and the power supply cable. The female component comprises a printed circuit board (PCB) comprising at least one electrically conductive contact object coupled to at least one printed conductor, said at least one printed conductor being electrically coupled to at least one wire from the other of the motor and the power supply cable.

Description

Fencing Technical Area

The present invention relates to screen devices, more screen devices with rollable screens. State of the art

[02] Screen devices comprising a roll-up screen are nowadays often electrically operable, whereby the screen rolls up or down via the drive of an electric motor. This is often mounted in a steel shaft that supports the screen.

[03] Mounting such screen devices is no easy task. The screen in the rolled-up state, including the carriers and the like, and together with the coaxially mounted motor (all this together is called a cloth package), must be slid into the housing suspended on the wall, for example a facade. In addition, the motor must also be connected to the supply current, which can be either mains voltage alternating current, or photovoltaically generated low voltage direct current. The motor often comprises the male or female component of a coupling piece, which must connect to the other (male or female) component that is connected to the power supply when the fabric package is retracted. Such cloth packages can have a weight of up to about 80 kg, so that careful manipulation is not evident.

The connectors must also be manipulated during the lifetime of these screen devices. For example, in case the fabric needs to be replaced or in the event of a motor fault, often the entire fabric package has to be removed from the housing, disconnecting the male and female connection components.

An example of suitable connectors is given in EP2354430B1. The disadvantage of these connectors is the fragility of the connection pins, which may be damaged during manipulation of the components on the job site before insertion of the fabric package into the housing, or which bend during this insertion of the fabric package into the housing. Summary of the Invention

It is an object of the invention to provide screen devices with retractable screens, which in turn are provided with connectors that can withstand the forces during the retraction of the fabric package, with simultaneous coupling of the connectors during this action. It is also a goal to provide connectors that are less fragile to manipulation on the wert.

In a first aspect, a screen installation is provided. The screen device comprises a roll-up screen, an electric motor for rotating the roll-up screen, which motor is electrically powered by one or more wires, a power cable comprising one or more wires, an electrical coupling for coupling the wires of the power cable to the wires of the motor, which coupling comprises a male and a female component which can be electrically and mechanically coupled to each other, characterized in that the male component comprises a printed circuit board (PCB) which comprises at least one lip on which at least one printed conductor is provided and which comprises at least one printed conductor is electrically coupled to at least one wire of a first of the motor and the power supply cable, the female component comprising a printed circuit board (PCB) comprising at least one electrically conductive contact object coupled to at least one printed conductor, said at least one printed conductor electrically is coupled to at least one wire of the a other of the motor and the power cable.

[08] A lip is a protruding part of the printed circuit board, also called a fin, which lies in the plane of the printed circuit board and protrudes from the edge of the printed circuit board. The electrically conductive contact objects on the female component are, for example, spring contacts or sliding contacts intended to make electrical contact with the printed conductors on the lip or lips of the male component. These electrically conductive contact objects are preferably positioned against the edge of the printed circuit board of the female component. For example, they may be made of a copper-beryllium alloy (e.g. comprising about 1.7 to 1.9% Berillium). They may also be coated with a thin layer of gold.

[09] The wires are electrically conductive wires or cores, typically copper wires or cores, which carry current, for example low voltage direct current of 24V or 48V, or 230V to 3 to 4A alternating current, to and from the motor.

[10] The printed circuit boards comprise printed conductors on a board. The sheet is typically made of epoxy, e.g. glass fiber textile (e.g. fabric) reinforced epoxy, and has a thickness in the range 1.0 to 2.0 mm, such as e.g. 1.6 mm.

[11] The printed conductors are electrical conductors. The use of printing plants for the high voltage alternating current is demanding and preferably requires suitable dimensions. In order to conduct sufficient current, especially in the case of higher currents at high voltage AC, the conductors have a weight per surface area of 0.5 to 3 ounces per square foot, such as between 1 and 2 ounces per square foot, inclusive. The cross section is preferably equal to or greater than 0.106 mm°, especially for conductors with a unit area weight of 2 ounces per square foot.

[12] The printed conductors are made of conductive materials, typically metals, and preferably of copper or copper alloys. The printed conductors may optionally be coated with solder, nickel or gold, or may be treated with benzimidazolethiol to prevent corrosion. The printed conductors may have undergone a “conformal coating” to prevent corrosion, current leakage and/or shortened life due to condensation. This can be done by dipping, spraying or vacuum evaporation of silicone rubber, polyurethane, acrylic or epoxy.

[13] The printed conductors on the lip or lips of the printed circuit board should preferably be electrically conductive, but also resistant to corrosion. For example, they may be made of a copper-beryllium alloy (e.g. comprising about 1.7 to 1.9% Berillium). Optionally, the conductors are still coated with a thin layer of gold.

[14] The screen device typically further comprises a device housing for housing the rotatable screen and the motor.

[15] According to some embodiments, the male component may comprise a housing that encloses the printed circuit board and/or wherein the female component comprises a housing that encloses the printed circuit board.

[16] The housing of the male connector may extend beyond the lip or lips. It is understood that the lip or lips are free on the outside of the housing so as to be able to make contact with the contact objects of the female component.

[17] According to some embodiments, the female component may comprise a housing that encloses the printed circuit board and wherein the female component comprises a housing that encloses the printed circuit board.

[18] The housing of the female connector may protrude beyond the contact objects. Obviously these are free so that they are able to contact the lip or lips of the male component.

[19] According to some embodiments, each of the housings may comprise a shell that partially or wholly encloses the housing and encloses the printed circuit board, the printed circuit board being enclosed within the shell by a polymer volume which fills the shell, with the exception of the lip or lips of the male component, and the electrically conductive contact objects of the female component.

[20] The printed circuit board is therefore always completely coated with polymer. The printed circuit board is thus embedded in polymer. With the exception of the lip or lips of the male component, of course, and the electrically conductive contact objects of the female component.

[21] The shell provides each housing with at least a part, and preferably the whole of the outer wall. This shell, which may consist of different parts, can be manufactured with very accurate dimensions, for instance by injection molding the whole or the parts of the shell. An electrical component, for example the printed circuit board housed in this shell, is thus surrounded by a wall whose thickness can be guaranteed very accurately. Thus, a minimum distance between the outer wall of the housing and each of the components present in the shell,

be guaranteed. The minimum thickness of the shell is preferably between 7949/9401 0.5 and 2 mm. A shell with a breakdown voltage between the two sides of the wall of 31 kV/mm is preferably provided. Measured according to EN60355, the insulation must comply with the basic insulation of 1250V.

[22] The polymer volume can be injected or poured into the shell, while the printed circuit board is positioned at the desired location within the shell. Thus, the printed circuit board can be completely encased and enclosed so that none of the electrical components on the printed circuit board are outside the polymer volume, ergo outside the housing, with the exception of the lip(s) or electrically conductive contact object(s). The polymer volume contacts the printed circuit board over its entire surface, with the exception of the lip(s) or electrically conductive contact object(s).

Suitable polymer for the shell are any polymers suitable for housing electrical components, for example extrusion-compatible polymers such as thermoplastics and elastomers. Preferably, wall thickness and polymer are chosen so that a breakdown voltage of at least 600V is obtained. Typical suitable polymers are polyamide (PA), polyester (PES), polyolefins such as polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), polyvinyl chloride (PVC) and similar or mixed polymers, optionally supplemented with plasticizers, flame retardants and fillers and similar. More preferably PA or PVC are used.

[24] Suitable polymers for the polymer volume are any polymers suitable for contacting electrical components, preferably injection moldable polymers such as thermoplastics and elastomers. For example, these polymers are polyamide (PA), polyester (PES), polyolefins such as polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), polyvinyl chloride (PVC), and similar or mixed polymers, optionally supplemented with plasticizers, flame retardants and fillers and the like. More preferably PA or PVC are used, preferably applied via injection moulding.

[25] The polymer used for the shell and the polymer for the polymer volume should be complementary and adherent to each other.

[26] According to other embodiments, the male and/or female component may comprise a housing consisting only of a shell. The shell can consist of different parts which connect to each other and adhere, for example by means of a closing system, for example a click system. The printed circuit board, with the exception of the lip or lips on the male component, is completely enclosed by the shell after mounting and connecting, e.g. snapping shut, any different parts of the shell. For the female component, openings remain free in the closed shell that allow the lips to contact the electrically conductive contact objects situated in the housing.

[27] The shell or shell parts are preferably made of polymer, in particular injection molded polymer. An electrical component, for example the printed circuit board housed in this shell, is thus surrounded by a wall whose thickness can be guaranteed very accurately. A minimum distance between the outer wall of the housing and each of the components present in the shell can thus be guaranteed. The minimum thickness of the shell is preferably between 0.5 and 2 mm. A shell with a breakdown voltage between the two sides of the wall of 31 kV/mm is preferably provided. Measured according to EN60355, the insulation must comply with the basic insulation of 1250V.

[28] Suitable polymers are any polymers suitable for contacting electrical components, preferably injection moldable polymers such as thermoplastics and elastomers. For example, these polymers are polyamide (PA), polyester (PES), polyolefins such as polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), polyvinyl chloride (PVC), and similar or mixed polymers, optionally supplemented with plasticizers, flame retardants and fillers and the like. More preferably PA or PVC are used, preferably applied via injection moulding.

[29] According to other embodiments, the male and/or female component may comprise a housing consisting only of a shell. The shell can consist of different parts that connect to each other and adhere by means of a closing system, for example by means of a click system. The printed circuit board is completely enclosed by the shell after mounting and connecting, for example clicking shut, any different parts of the shell. With the male component, of course, the lip or lips are kept free. With the female component, of course, openings are provided to allow the later retracted lip of the male component to make electrical contact with the contact objects.

[30] The shell or shell parts are preferably made of polymer, in particular injection molded polymer. An electrical component, for example the printed circuit board housed in this shell, is thus surrounded by a wall whose thickness can be guaranteed very accurately. A minimum distance between the outer wall of the housing and each of the components present in the shell can thus be guaranteed. The minimum thickness of the shell is preferably between 0.5 and 2 mm. A shell with a breakdown voltage between the two sides of the wall of 31 kV/mm is preferably provided. Measured according to EN60355, the insulation must comply with the basic insulation of 1250V.

[31] Suitable polymers are any polymers suitable for contacting electrical components, preferably injection moldable polymers such as thermoplastics and elastomers. For example, these polymers are polyamide (PA), polyester (PES), polyolefins such as polypropylene (PP), polyethylene (PE), polyethylene terephthalate (PET), polyvinyl chloride (PVC), and similar or mixed polymers, optionally supplemented with plasticizers, flame retardants and fillers and the like. More preferably PA or PVC are used, preferably applied via injection moulding.

[32] According to still other embodiments, the male and/or female component may comprise a housing that is completely formed around the printed circuit board by overmolding it with polymer in the form of the final housing. The printed circuit board and associated elements are clamped in a mold leaving the contact pins and/or sockets free to allow later electrical contact, and this mold is injection-filled with polymer. With the male component, of course, the lip or lips are kept free. With the female component, of course, openings are provided to allow the later retracted lip of the male component to make electrical contact with the contact objects. The possible polymers are those mentioned above. PA and PVC are preferably used. As a result, the printed circuit board is completely embedded in the housing, leaving the contact pins and/or contact sockets free of course. The minimum thickness of the housing is preferably between 0.5 and 2 mm.

[33] According to still other embodiments, the male and/or female component may comprise a housing which is partly formed from a shell, and partly formed by molding the printed circuit board with polymer in the form of the final housing. The possible polymers are those mentioned above. PA and PVC are preferably used. The minimum thickness of the housing is preferably between 0.5 and 2 mm.

[34] According to some embodiments, the male and female components may be adapted for coupling in a coupling direction, at least one housing, if applicable both housings, comprises control elements, which control elements control the movement of the male and female component during coupling of the male and female component in the coupling direction.

[35] The control elements can determine the mutual movement of male and female components such that the lip or lips of the male component and the respective abutting contact objects of the female component are well aligned during coupling.

[36] The male component may have protruding elements on the housing which can slide into an opening in the housing of the female component during coupling. Or vice versa, where the female component may have protruding elements on the housing which can slide into an opening in the housing of the male component during coupling. These projecting elements protrude from the housing in the direction of movement during coupling, ie. the coupling direction. The openings can be of conical design in order to thus control the movement.

[37] In embodiments, the openings in the female component, behind which the electrically conductive contact objects are positioned, are also conical, or have walls that decrease in mutual distance the closer to the contact object, so that when the corresponding lip of the contact object is inserted, the male component, the movement of the lip is directed towards the electrically conductive contact objects. Also, the lip may be rounded at the front to control the movement of the lip in the opening 299401.

[38] According to some embodiments, the male component may have one or more protrusions in the coupling direction and the female component has one or more recesses corresponding to the protrusion in the coupling direction; and/or e The female component has one or more protrusions in the coupling direction and the male component has one or more recesses corresponding to the protrusion in the coupling direction.

[39] It should be noted that the control elements are an integral part of the housing or housings. The control elements can take a variety of shapes, for example projecting portions of the housing of one of the components, which slides over thinned zones of the other component's housing. With the aid of, for example, projections, ribs and the like, which mate in slots or the like, or conically engaging surfaces, the steering elements will correctly move, steer and guide or guide the two components towards each other. The steering elements can center the two components towards each other. All this with the aim of correctly positioning the electrically coupling parts of the male and female components in front of each other, before they start the electrical coupling. It is therefore important that the controlling elements first make contact with each other and steer before electrical contacts are made between the male and female components.

[40] In some embodiments, at least one of the driver elements of one of the components can make coupling contact with the corresponding driver element of the other component before one or more printed conductors on the one or more tabs of the male component make electrical contact. can make with the corresponding contact object of the female component.

[41] In other words, at least one of the control elements of one of the components projects in the coupling direction further from the housing of the component than the furthest point of the printed conductor or conductors on the lip or tabs or contact object of this component. This is advantageous because realizing the control or guidance of the components for the electrical coupling ensures that the fitting of the printed conductor or conductors on the lip or lips in or on the corresponding contact objects can be done smoothly and with as little dimensional deviation as possible. occur, as a result of which the life of the lips with conductors and contact objects can be extended.

[42] In some embodiments, a grommet may be provided to waterproof the contact between the housings of the male and female component.

[43] In some embodiments, the grommet may be positioned around the at least one lip of the male component.

[44] With multiple lips, each of the lips may be individually ring-enclosed.

[45] The grommet may be housed in or on the housing of the male component and define the location where the lip protrudes through the housing.

In some embodiments, the grommet may surround the opening through which the tab of the male component passes through the housing of the female component to establish electrical contact between conductor on the tab and contact object of the female component.

[47] With multiple apertures, each of the apertures may be individually ring-enclosed.

[48] The grommet may be contained in or on the housing of the female component where the opening in the housing is provided for the passage of the lip or lips.

[49] According to embodiments, this sealing ring may be provided at the base of the wall around the lip. A grommet enclosing this foot may be sufficient.

[50] According to embodiments, this sealing ring may be provided at the top of the opening through which the lip is to be inserted. A sealing ring lying on this top, possibly where the top is provided with a holder to hold this ring, may be sufficient.

[51] In some embodiments, one of the motor wires and one of the power cable wires may be a ground conductor.

[52] In some embodiments, the male and female components may be adapted for coupling in a coupling direction, and during coupling in a coupling direction, the printed electrical conductor of the tab or contact object mated to the ground conductor of the power supply cable contacts the corresponding contact object or printed electrical conductor of the lip coupled to the ground conductor of the motor, before one or more other printed electrical conductor on the lip or lips of the male component can make electrical contact with the corresponding contact objects of the female component.

[53] Making a connection of the earths first is often important to avoid short circuits and the like, and to be able to realize the connection.

[54] The printed electrical conductor of the tab coupled to a grounding conductor may be made more robust than the other printed conductors coupled to current-carrying wires. They can, for example, be made thicker or wider. The same applies to the printed conductors on the printed circuit board of the female component. The contact objects coupled to the grounding conductor can also be made more robust, for example thicker, or a plurality of contact objects can be provided for contacting the same grounding conductor on the corresponding lip.

[55] It is advantageous that the order in which different parts make contact during the coupling of the components is the order in which control of the components is first ensured, then electrically coupled the ground conductors, and only then the current-carrying conductors .

[56] Therefore, according to preferred embodiments, a shield arrangement is provided wherein the male and female components are adapted for coupling in a coupling direction, and during coupling in coupling direction, the printed electrical conductor of the lip or contact object is coupled to the ground conductor of the power supply cable makes contact with the corresponding contact object or printed electrical conductor of the lip coupled to the earth conductor of the motor, before one or more other printed electrical conductor on the lip or printed conductors of the male component can make electrical contact with the corresponding contact objects of the the female component; e wherein the male component comprises a housing enclosing the printed circuit board and wherein the female component comprises a housing enclosing the printed circuit board, and wherein at least one housing, if applicable both housings, comprises steering elements, which controlling elements control the movement of the male and component while coupling the male and female component in the coupling direction, at least one of the controlling elements of one of the components in coupling direction makes contact with the corresponding controlling element of the other component, before one or more printed conductors on the one or more multiple lips of the male component can make electrical contact with the corresponding contact object of the female component.

[57] According to some embodiments, the power cable may comprise M1 wires, the male or female component comprises N1 printed conductors on one or more tabs, or electrically conductive contact objects, where N1>=M1 and M1>=2.

[58] According to some embodiments, the motor may comprise M2 wires, the male or female component comprises N2 printed conductors on one or more tabs, or electrically conductive contact objects, where N2>=M2 and M2>=2.

[59] According to some embodiments, M1=M2 and N1>M1 or N2>M2.

[60] In one embodiment, M1=M2>=3 and N1 and N2 are both greater than 3, for example, M1=M2=N1=N2=4.

[61] In some embodiments, the male or female component coupled to the power cable will be configured to be compatible with a female or male component coupled to the motor and mounted either on the left or right side relative to the rotating screen. Shade devices are often made in two versions, where the motor is positioned either on the left side of the rolled screen or on the right side. When using the same motor, the printed conductors on one or more tabs or electrically conductive contact objects, depending on whether the male or female connector is coupled to the motor, will be mirrored, depending on a left or right installation . To cope with both situations with the same component (male or female) on the power supply cable, the printed conductors on one or more lips or electrically conductive contact objects must be mirrored on the component that is coupled to the power supply cable. For example, in the case of M wires in the power supply cable, a single wire can be electrically coupled to two printed conductors on one or more lips, or electrically conductive contact objects, which two are each integrated in mirror image of each other in the same male or female component.

[62] In other embodiments, the printed conductor on one lip, or the electrically conductive contact objects coupling the grounding conductor, is formed centrally, and therefore should not be duplicated, while the other printed conductors on one or more lips, or electrically conductive contact objects those that carry current are double and mirrored.

[63] In some embodiments, the wires may be coupled to the printed conductors by griplets. The griplets can for instance be made of copper, optionally with a nickel or nickel-tin coating.

In alternative embodiments, the wires may also be soldered to the printed conductors, crimp contacts may be used, or the wires may be coupled to the printed conductors by any of the known techniques.

[65] The griplets or other connectors used are preferably embedded in the polymer volume comprising the printed circuit board.

[66] In some embodiments, the male component may be coupled to the wires of the power supply cable, the female component side coupled to the wires of the motor.

[67] In some embodiments, the female component can be coupled to the wires of the power supply cable, the male component side coupled to the wires of the motor.

[68] In embodiments, each tab, e.g. four tabs, can each carry one printed conductor. In other embodiments, one, some, or all of the tabs includes more than one printed conductor printed side by side on the tab.

[69] According to some embodiments, the printed conductors may be printed in pairs side by side on one lip.

[70] According to a second aspect, there is provided a method of mounting a screen installation according to the first aspect of the invention. The method of mounting a screen installation according to the first aspect of the invention comprises a device housing, the method comprising sliding the motor and the retractable screen laterally into the device housing, and during this insertion the coupling of the male and female components of the link is established.

[71] The motor and the roll-up screen (together the fabric package) can be slid frontally into the device housing, which may even be mounted on the wall where the screen installation is to be attached. The component attached to the power cable may already be present in the housing carried by a housing mounting piece. That is why the coupling of male and female components must be realized simultaneously during the insertion of the cloth package. After sliding in and thus connecting the power cable to the motor, the housing can be closed with a closing piece.

[72] According to a third aspect, a method of manufacturing a screen device is provided. The method for manufacturing a screen device according to the first aspect of the invention comprises steps A and/or B; the steps A being e A1: providing a printed circuit board (PCB) comprising at least one lip with at least one printed conductor thereon which is electrically coupled to at least one wire of a first of the motor and the power supply cable; e A2: inserting the printed circuit board into a first shell, wherein the at least one lip is positioned outside the shell; e A3: filling the shell provided with the printed circuit board with a polymer; e A4: possibly closing the shell with a closing piece; The steps B being: e B1: providing a printed circuit board (PCB) on which at least one electrically conductive contact object is electrically coupled to at least one printed conductor on the printed circuit board and which at least one printed conductor is electrically coupled to at least one wire of the other of the motor and the power cable; e B2: inserting the printed circuit board into a first shell; e B3: filling the shell provided with the printed circuit board with a polymer, while the at least one contact object remains accessible from outside the shell; e B4: possibly closing the shell with a closing piece.

[73] According to some embodiments, steps A and B may be performed.

[74] The shells can be made of one piece, for example a shell that can be closed around a volume, which volume can comprise the printed circuit board and in which shell openings are provided for the lips or openings are left so that the contact objects remain accessible to the people to be contacted. contact lips. Or the shell may consist of at least a volume enclosing portion and a closing piece for closing the shell. Or the shell can consist of several parts that together can enclose a volume. Preferably, the shells, or parts of the shell, are injection molded pieces.

[75] The printed circuit board may be held in place during the introduction of the polymer by fittings, or the shell may have abutment and/or clamping surfaces in which the printed circuit board is clamped or on which it rests.

[76] The shell obviously has an entry for the wires or the entire power cable along where the wires access the printed circuit board in the volume.

[77] The filling of the shell provided with the printed circuit board with a polymer can be done by injection moulding.

[78] According to a fourth aspect, a screen installation is also provided. The screen device may be obtained by a method according to the third aspect of the invention.

[79] According to a fifth aspect, a screen installation is also provided. This screen device comprises a roll-up screen, an electric motor for rotating the roll-up screen, which motor is electrically powered by one or more wires, a power cable comprising one or more wires, an electrical coupling for coupling the wires of the power cable to the wires of the motor, the coupling comprising a male and a female component which can be electrically and mechanically coupled to each other, characterized in that the male component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed conductor on the printed circuit board and which at least one printed conductor is electrically coupled to at least one wire of a first one of the motor and the power supply cable, the male component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector; and/or e the female component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed conductor on the printed circuit board, which at least one printed conductor is electrically coupled to at least one wire from the other of the motor and the power cable, the female component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector.

[80] According to some embodiments, the male component may comprise a printed circuit board (PCB) having at least one electrical connector electrically coupled to at least one printed conductor on the printed circuit board and said at least one printed conductor being electrically coupled to at least one wire of a first of the motor and the power cable, the male component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector; and e the female component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed conductor on the printed circuit board, the at least one printed conductor being electrically coupled to at least one wire from the other of the motor and the power supply cable, the female component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector.

In some embodiments, the printed circuit board of the male and/or female component in the shell may be enclosed by a polymer volume which fills the shell.

[82] In some embodiments, the at least one electrical connector of the male component may be a printed conductor.

According to some embodiments, the at least one electrical connector of the female component may be a spring contact or sliding contact.

[84] Features and/or elements of embodiments of one aspect of the invention may be combined with features and/or elements of the other aspects, so long as they do not technically contradict each other.

[85] The independent and dependent claims set forth specific and preferred features of the embodiments of the invention.

Features of the dependent claims may be combined with features of the independent and dependent claims, or with features described above and/or below, in any suitable manner as would be apparent to a person skilled in the art.

The above and other features, features and advantages of the present invention will be illustrated by the following exemplary embodiments, optionally in combination with the drawings.

[87] The description of these exemplary embodiments is provided by way of illustration, without intent to limit the scope of the invention. The reference numerals in the following description refer to the drawings. Same reference numerals in possibly different figures refer to identical or similar elements. Brief Description of the Drawings

[88] In order to better demonstrate the features of the invention, some preferred embodiments are described below, by way of example without any limiting character, with reference to the accompanying drawings, in which:

[89] Figure 1 schematically illustrates a screen arrangement according to the invention.

[90] Figures 2 and 3 schematically show parts of a male and female component, respectively, which form part of a screen device according to the invention.

[91] Figure 4 shows schematically a male and female component that forms part of a screen device according to the invention.

Figure 5 shows schematically how, according to some embodiments of the invention, the ground conductors first make electrical contact during the coupling of the male and female components.

[93] Figure 6 shows schematically parts of the housing of a female and male component forming part of a screen device according to the invention.

[94] Figure 7 shows schematically a female component that is part of a screen device according to the invention, which is symmetrical. Description of Embodiments

[95] The present invention is described below using specific embodiments.

[96] It is understood that while the embodiments and/or the materials for furnishing embodiments of the present invention have been discussed, various modifications or changes may be made without departing from the scope and/or spirit of this invention. . The present invention is by no means limited to the embodiments described above, but can be realized according to various variants without departing from the scope of the present invention.

A screen device 100 according to the invention is shown in Figure 1, details of the electrical coupling are shown in Figures 2 and 3. The screen device 100 according to the invention comprises a roll-up screen 101 and an electric motor 102 for rotating the roll-up screen . The motor 102 is electrically powered by four wires 103, one of which is the ground conductor. The screen device 100 further includes a power cable 104 including four wires 105, one of which is the ground conductor. For coupling the wires 105 of the power cable 104 to the wires 103 of the motor 102, an electrical coupling 200 comprising a male 210 and a female 220 component is provided, both of which can be electrically and mechanically coupled together. In this embodiment, the female connector 220 is already connected to a mounting piece 110, which is already secured in the housing of the screen device before the cloth wrap comprising rollable screen 101 and the electric motor 102 is retracted in the direction indicated by indication 111.

The male component 210, in Figure 2, comprises a printed circuit board 213 (PCB) on which electrical connectors, being tabs 212 with printed conductors 214 on the printed circuit board 213. These printed conductors are electrically coupled one-to-one with wires 103 of in FIG. in this case the motor 102. The latter is done with the help of griplets 216. The male component 210 in this embodiment comprises two lips 212 and 218. The lip 218 is inter alia coupled to the grounding and is designed slightly longer than the other lip 212. One of the printed conductors, 219, on this lip 218 is also longer, thus extending further from the printed circuit board compared to the other conductors on the other lip 212. This printed conductor 219 is coupled to ground. This conductor 219 on lip 218 is also wider and may be printed slightly thicker.

The female component 220, in Figure 3, comprises a printed circuit board 223 (PCB) on which electrical connectors, being electrically conductive contact objects, here spring contacts 222, are electrically coupled to printed conductors 224 on the printed circuit board 223. The printed conductors are electrically coupled. is the wires of the power supply cable 104. The latter is done by means of griplets 226. The female component 220 comprises five spring contacts 222. Centrally, the female component has a grounding fin 227 which serves to ground the housing. The two spring contacts 228 are coupled to ground. Two spring contacts are provided to contact the printed ground conductor 219 of the male component on the lip 218. The other contacts 214 of the male component are contacted by one spring contact 222.

The printed circuit boards 213 and 223 have a length of about 35 to 58 mm and a width of about 12 to 15 mm, are 1.6 mm thick and are made of fiberglass fabric reinforced epoxy. The conductors 214 and 224 preferably have a weight per unit area of 1 or 2 ounces per square foot, and are made of copper. The conductors that will be coupled to the ground wires preferably have a surface weight of 2 ounces per square foot. The cross section of the conductor is preferably 0.106mm? or more at an area weight of 2 ounces per square foot. The lips protrude 6.7 mm from the edge of the printed circuit board. The printed contacts terminate 2.5mm from the end of the lip, except for the conductor coupled to ground, which ends 1mm from the end of the lip. Thus, when coupled, the conductor will first contact the lip 218 that is connected to the ground with the two spring contacts 222, before the other printed conductors of the male component make contact with the spring contacts 222. The ends of the 7920/5401 printed conductors on the lips of the male component are optionally coated with a conductive coating that protects against corrosion, for example with a gold coating.

[101] The spring contacts are made of metal preferably Cu or Cu alloy (eg CuBe alloy eg 1.7-1.9% Be for improved stiffness and resilience). The spring contacts may or may not be galvanized or hard gold coated for corrosion protection.

[102] Alternative male and female components 211 and 221, provided with their housings, are shown in Figure 4. Here, the male component 211 has four tabs 212 and 218, on each of which one electrically conductive printed conductor 214 or 219 is positioned. On lip 218 and printed conductor 219, the ground wire is electrically coupled. The female component 221 is provided with the same contact objects as the female component 220 and has two openings 254, each of which receives two lips.

The printed circuit boards are completely enclosed by the housing 230 and 250, respectively, with the exception of the lips 212 and 218 of the male component 210. In the female component 220, openings 254 in the housing are provided on the lips 212 to allow the electrical connections to be made. conductive contact objects.

In this embodiment, the male component 211 has two projecting fins 231 projecting in front of the lips 212, one fin on each side of the male component. The fin 213 on the bottom drawn, however, is split into two parts 2314 and 231b.

On these fins 213, the male component 211 has two elevations 232 in the housing 230 of the male component 211 which slide into two depressions or depressions 252 upon engagement with the female component 221. The fins 231, as it were, partly encompass the housing 250 of the female component 221. The fins, and certainly the elevations, guide and control the male and female components during coupling. It is true that during coupling, the bosses 232 and recesses 252 first touch and guide the movement of the components, before the tabs 212 are inserted into the openings 254, i.e. before the grounding conductors contact each other and then the other conductors. contact us.

Furthermore, the housing 250 of the female component 230 includes a stiffening zone 253 that increases the rigidity of the entire housing 250. In the openings 254 of the female component 211, a rebate 255 is provided for receiving a sealing ring which, after coupling with the male component, will encompass each one of the lips and will seal the coupling from lip to opening watertight.

A detail of the coupling between male and female components 210 and 220 is shown in Figure 5. In detail, a conductor 219 is shown electrically coupled to ground, and a spring contact 2224 coupled to ground. When coupling a male and female component 210 and 220 in coupling direction 500, conductor coupled to the ground of the male component will contact the corresponding spring contact 2224 earlier than the other conductors 214 which are to mate with the other spring contacts 222b.

[108] Referring to Figure 6, it is shown in detail how the housing of the female component 220 or 221 and a male component 210 or 211 is manufactured. A shells 260 and 270 consisting of a lower part 261 and 271 respectively and an upper or closing part 262 and 272 respectively are provided.

[109] The shell parts are made of PA or PVC and have a minimum wall thickness of 0.5 to 2 mm. They are manufactured by injection molding.

[10] The printed circuit board, which is provided with the contact objects or contact lips, is positioned in the carrier piece 261.

[111] After inserting the printed circuit board, the upper part is pushed onto the lower part and through the locking system 263a and 263b, 273a and 273b, respectively, the two shell parts are fixed together. Of course, the openings 254 in the female component are left exposed. In the male component, the lips 218 and 212 will protrude from the shell, i.e. the housing.

[112] An alternative way of forming the male component, which has the shape as shown in Fig. 6, is that the printed circuit board 213 is clamped in a mould, the mould, for example, clamp the lips 218 and 212 from the inside of the mold. die. The mold, which has the shape of the contours of the housing similar to the closed pieces 271 and 272, is completely injected with polymer, preferably PA or PVC. In this way a male component is formed, which has the contour like that of figure 6, but in which the housing is formed by injection molding, and in which the printed circuit board, except for the lips, is completely enclosed by polymer.

An alternative way of forming the female component, which has the shape as shown in Figure 6, is that the printed circuit board 213 is supported on a base 261, and this combination is clamped in a mould. The mold, which has the shape of the contour of the housing similar to the top part 262, is completely injected with polymer, preferably PA or PVC. In this way a female component is formed, which has the contour as shown in figure 6, but where the housing is formed partly by injection molding, partly by a shell, and where the printed circuit board, except for the openings, is completely enclosed by polymer .

[114] In figure 7 alternative components are shown which are suitable for mounting in a screen device which can be mounted on either the left or the right side. The female component 2200 is coupled to the current-carrying cable 104. Behind the openings 2201a and 2201b is mounted a contact object, for example a spring or clamp contact, which is coupled to the grounding conductor of the cable. Behind openings 22024 and 2202b are contact objects which are electrically coupled to a first of the two current-carrying wires. Behind openings 2203a and 2202b are contact objects which are electrically coupled to a second of the two current-carrying wires. This female component 2200 can be coupled to the same motor both left and right.

[115] While the present invention has been illustrated with reference to specific embodiments, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied with various modifications and modifications without departing from the scope of the invention.

The present embodiments are therefore to be regarded as illustrative and not restrictive in all respects, the scope of the invention being described by the appended claims and not by the foregoing description, and any modifications which come within the meaning and scope of the claims, are therefore included.

In other words, it is understood that any changes, variations or equivalents that fall within the scope of the underlying principles and whose essential attributes are claimed in this patent application are understood to be included.

In addition, the reader of this patent application will understand that the words "comprising" or "comprising" do not exclude other elements or steps, that the word "a" does not exclude the plural, and that a singular element, such as a computer system, a processor or other integrated unit can perform the functions of various tools stated in the claims.

Any references in the claims should not be construed as limiting the claims in question.

The terms "first", "second", "third", "a", "bp", "c" and the like, when used in the specification or in the claims, are used to distinguish between similar elements or steps and do not necessarily describe a sequential or chronological order.

Likewise, the terms "top", "bottom", "over", below" and the like are used for purposes of description and do not necessarily refer to relative positions.

It is to be understood that those terms are interchangeable under appropriate circumstances and that embodiments of the invention are capable of functioning according to the present invention in other orders or orientations than those described or illustrated above.

Claims (28)

CONCLUSIONS BE2020/5401 A screen device comprising a roll-up screen, an electric motor for rotating the roll-up screen, which motor is electrically powered by one or more wires, a power cable comprising one or more wires, an electrical coupling for coupling the wires of the power cable to the wires of the motor, which coupling comprises a male and a female component which can be electrically and mechanically coupled to each other, characterized in that the male component comprises a printed circuit board (PCB) comprising at least one lip on which at least one printed conductor is provided and said at least one printed conductor being electrically coupled to at least one wire of a first of the motor and the power supply cable, the female component comprising a printed circuit board (PCB) comprising at least one electrically conductive contact object coupled to at least one printed conductor, said at least one printed conductor conductor is electrically coupled with at least one wire the other from the motor and the power cable. A display device according to claim 1, wherein the male component comprises a housing enclosing the printed circuit board and/or wherein the female component comprises a housing enclosing the printed circuit board. A display device according to claim 2, wherein the female component comprises a housing enclosing the printed circuit board and wherein the female component comprises a housing enclosing the printed circuit board. A display device according to claim 3, wherein each of the housings comprises a shell which partially or wholly encloses the housing and encloses the printed circuit board, the printed circuit board being enclosed within the shell by a polymer volume filling the shell, except of the lip or lips of the male component, and the electrically conductive contact objects of the female component. A screen device according to any one of claims 2 to 4, wherein the male and female components are suitable for coupling in a coupling direction, at least one housing, if applicable both housings, comprises control elements, which control elements control the movement of the male and female component steering while coupling the male and female component in the coupling direction. A screen device according to claim 5, wherein the male component has one or more protrusions in the coupling direction and the female component has one or more recesses corresponding to the protrusion in the coupling direction; and/or e The female component has one or more protrusions in the coupling direction and the male component has one or more recesses corresponding to the protrusion in the coupling direction. A screen device according to any one of claims 5 or 6, wherein at least one of the control elements of one of the components makes contact in coupling direction with the corresponding control element of the other component, before one or more printed conductors on the one or more tabs of the male component can make electrical contact with the corresponding contact object of the female component. A screen device according to any one of claims 3 to 7, wherein a sealing ring is provided for waterproofing the contact between the housings of the male and female component. A screen device according to claim 8, wherein the sealing ring is positioned around the at least one lip of the male component. The display device of claim 8, wherein the grommet 99497 surrounds the opening through which the lip of the male component passes through the housing of the female component to make electrical contact between conductor on the lip and contact object of the female component. A screen device according to any one of the preceding claims, wherein one of the wires of the motor and one of the wires of the power supply cable is a grounding conductor. A screen device according to claim 11, wherein the male and female components are adapted for coupling in a coupling direction, and during coupling in coupling direction, the printed electrical conductor of the tab or contact object coupled to the grounding conductor of the power supply cable makes contact with the corresponding contact object or printed electrical conductor of the lip coupled to the ground conductor of the motor, before one or more other printed electrical conductor on the lip or lips of the male component can make electrical contact with the corresponding contact objects of the female component. A screen device according to any one of claims 1 to 12, wherein the supply cable comprises M1 wires, the male or female component comprises N1 printed conductors on one or more lips, or electrically conductive contact objects, wherein N1>=M1 and M1>=2 . A screen device according to any one of claims 1 to 13, wherein the motor comprises M2 wires, the male or female component comprises N2 printed conductors on one or more lips, or electrically conductive contact objects, wherein N2>=M2 and M2>=2 . A screen device according to claim 14, wherein M1=M2 and N1>M1 or N2>M2. A screen device according to any one of the preceding claims, wherein the wires are coupled to the printed conductors by griplets. A screen device according to any one of the preceding claims, wherein the male component is coupled to the wires of the power supply cable, the female component side coupled to the wires of the motor. A screen device according to any one of claims 1 to 16, wherein the female component is coupled to the wires of the power supply cable, the male component side coupled to the wires of the motor. Screen device according to one of the preceding claims, wherein the printed conductors are printed in pairs side by side on one lip. A method of mounting a screen installation according to any one of the preceding claims, comprising a device housing, the method comprising sliding the motor and the retractable screen laterally into the device housing, and wherein during this insertion, the coupling of the male and female components of the link is established. A method for manufacturing a screen device according to any one of claims 1 to 19, wherein the method comprises steps A and/or B; the steps A being e A1: providing a printed circuit board (PCB) comprising at least one lip with at least one printed conductor thereon which is electrically coupled to at least one wire of a first of the motor and the power supply cable; e A2: inserting the printed circuit board into a first shell, wherein the at least one lip is positioned outside the shell; e A3: filling the shell provided with the printed circuit board with a polymer; e A4: possibly closing the shell with a closing piece; The steps B being: e B1: providing a printed circuit board (PCB) on which at least one electrically conductive contact object is electrically coupled to at least one printed conductor on the printed circuit board and which at least one printed conductor is electrically coupled to at least one wire of the other of the motor and the power cable; e B2: inserting the printed circuit board into a first shell; e B3: filling the shell provided with the printed circuit board with a polymer, while the at least one contact object remains accessible from outside the shell; e B4: possibly closing the shell with a closing piece. The method of claim 21, wherein steps A and B are performed. A screen device obtained by a method according to any one of claims 21 to 22. A screen device comprising a roll-up screen, an electric motor for rotating the roll-up screen, the motor being electrically powered by one or more wires, a power cable comprising one or more wires, an electrical coupling for coupling the wires of the power cable to the wires of the motor, which coupling comprises a male and a female component which can be electrically and mechanically coupled to each other, characterized in that the male component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed circuit conductor on the printed circuit board and said at least one printed conductor being electrically coupled to at least one wire of a first one of the motor and the power supply cable, the male component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector; and/or e the female component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed conductor on the printed circuit board, which at least one printed conductor is electrically coupled to at least one wire from the other of the motor and the power cable, the female component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector. A display device according to claim 24, wherein the male component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed conductor on the printed circuit board and the at least one printed conductor is electrically coupled to at least one wire of a first of the motor and the power cable, the male component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector; and e the female component comprises a printed circuit board (PCB) on which at least one electrical connector is electrically coupled to at least one printed conductor on the printed circuit board, the at least one printed conductor being electrically coupled to at least one wire from the other of the motor and the power supply cable, the female component comprising a housing enclosing the printed circuit board and providing at least one connectable electrical connector. A display device according to any one of claims 24 to 25, wherein the printed circuit board of the male and/or female component in the shell is enclosed by a polymer volume which fills the shell. A display device according to any one of claims 24 to 26, wherein the at least one electrical connector of the male component is a printed conductor. A display device according to any one of claims 24 to 27, wherein the at least one electrical connector of the female component is a spring contact or sliding contact.