BE1022962B1 - Socket assembly for installation in a wall - Google Patents

Abstract

A socket assembly for wall mounting, comprising a base and a central element; which base comprises a socket function; the central element comprising at least two holes for at least two pins of a plug; which central element is removably attachable to the base, with a rear side of the central element opposite a front side of the base; wherein the base comprises a controllable switch connected to the socket outlet function for controlling the power supply, a microcontroller configured to control the switch, and a communication module; wherein the central element is provided with an antenna, which antenna can be coupled to the communication module when the central element is attached to the base.

Description

Socket assembly for installation in a wall

Field of the Invention

The invention relates to a socket assembly for installation in a wall for enabling, and / or checking and / or measuring the provision of power to an electrical load.

Background

A socket assembly comprises a base and a cover. The base has the electrical socket function. The cover typically comprises a central element (also called central plate or finishing set) and a cover frame (also called mounting frame plate) that extends around the central element.

When smart functionalities are to be added to the socket assembly, a PCB with a communication part and an antenna connected to the base is typically provided.

Summary

The object of the present invention is to provide a socket assembly with improved communication capabilities that is simultaneously robust and securely manipulated. According to a first aspect, a socket assembly is provided for installation in a wall, for enabling and / or checking and / or measuring the provision of power at an electrical load. The socket assembly comprises a base and a central element. The base comprises a socket function and is intended to be at least partially built into an opening in the wall. The central element comprises at least two holes into which at least two pins of a plug can protrude to be electrically connected to the socket function. The central element is arranged to be part of a cover that covers the opening. The central element is removably attachable to the base, the rear side of the central element being located against a front side of the base. The base includes a controllable switch connected to the power supply control function, a microcontroller configured to control the switch, and a communication module connected to the microcontroller. The central element is provided with an antenna, and the antenna is coupled to the communication module when the central element is attached to the base. This coupling can be a contact coupling or a non-contact coupling, such as a capacitive coupling.

By providing the central element with an antenna while the communication module, the microcontroller and the controllable switch are located in the base, the operation of the antenna will be less influenced by the metal parts of the socket function. For embodiments for which the cover frame (mounting frame plate) is made of metal, providing the central element with the antenna will also be advantageous since the central element is not covered by the cover frame. Since the antenna is located at the front of the opening in the wall, the operation of the antenna is further improved in comparison with solutions where the antenna is arranged in the base, i.e. at a certain depth in the opening. On the other hand, by placing it in the base, the communication module, the microcontroller and the controllable switch can be protected in such a way that the base can be manipulated by an installer during installation without touching these parts.

In the context of the present invention, the term wall may refer to a side wall, a ceiling, or a floor.

In the context of the present invention, the term "socket assembly" refers to an assembly that is capable of being placed at a fixed location in a building and that is configured to enable or enable the provision of power to a wall load or to measure the power supplied to the load. The assembly is typically intended and arranged to be mounted at least partially in an opening in the wall with the socket function connected to electrical wires present in the wall. Typically, the electrical wires in the wall include wires connected to the power supply. However, in other embodiments, the electrical wires in the wall may include wires connected to a DC power source. More generally, the wires in the wall can be connected to any AC or DC power source.

In an exemplary embodiment, the antenna is arranged in a zone of the central element that is not covered by the plug when the plug is inserted. This further improves the operation of the antenna. In an exemplary embodiment thereof, the central element has a front side which is provided with a cavity in which a plug can be received, and wherein the antenna is arranged in a zone around the cavity.

In an exemplary embodiment, the antenna is arranged against the rear of the central element. The rear side of the central element can be provided with a groove in which the antenna is mounted, for example by gluing. In a further developed embodiment, the cavity for the plug in the front corresponds to a projection at the rear of the central element, and the groove extends around the projection.

In another exemplary embodiment, the antenna can be at least partially integrated into the central element. The antenna may, for example, be placed in the mold and be over-molded (over-molded) by a plastic material for forming the central element.

In a preferred embodiment, the rear of the central element is provided with at least one contact terminal, and the base is provided with at least one corresponding contact terminal which is connected to the communication module, such that the antenna is automatically electrically connected to the communication module when the central element is mounted on the base. The at least one contact terminal on the rear side of the central element can, for example, be positioned on the projecting part. The at least one corresponding contact terminal on the base can comprise at least one spring contact. In an alternative embodiment, a non-contact coupling may be provided, for example a capacitive or inductive coupling between the antenna and the communication module. The advantage of such a non-contact coupling is that the antenna can be completely accommodated in the cover part, wherein the antenna can be completely surrounded by plastic material. Furthermore, the central element can also have coupling parts which are covered, for example integrated in the central element or mounted against an inner surface of the central element.

In another exemplary embodiment, the central element is made of a plastic material, or more generally any material that does not significantly affect the operation of the antenna. The base can be provided with a metal frame that is configured for mounting the base in the opening in the wall. Since the antenna is located in the central element, such a metal frame will not significantly affect the antenna operation.

In a preferred embodiment, the antenna is a dipole antenna. However, the antenna can also be a monopole antenna. In the case of a dipole antenna, the antenna may comprise a first metal part and a second metal part which are arranged symmetrically in or against the central element.

In a further developed embodiment, the socket assembly further comprises a cover frame that is configured to extend around the central element, such that the cover frame and the central element cover the entire opening in the wall.

In a preferred embodiment, the microcontroller, the communication module and the controllable switch are arranged in the base in such a way that the base can be manipulated by an installer without touching the microcontroller, the communication module and the controllable switch. In an exemplary embodiment the base comprises a rear base part with a rear side and a front side and a front base part with a rear side and a front side. The rear of the rear base part faces away from the cover and the front of the rear base part is attached to a rear of the front base part. The front of the front base part faces the cover. The communication module and optionally also the microcontroller can be accommodated in a cavity of the front base part, preferably a cavity which is provided in the rear side of the front base part. By providing a base with several parts, a more compact electrical assembly is obtained. By providing the front base part with the microcontroller and the communication module, a part of the circuit to be connected to the antenna can further be brought forward, resulting in a better reception compared to a situation in which the antenna must be connected with a circuit mounted at the rear of the base.

In an exemplary embodiment, the controllable switch comprises a relay arranged in a cavity provided in the rear of the rear base part. A relay is typically a relatively large component and by accommodating the relay in such a cavity, the installation depth of the assembly can be further limited.

The base may include a power conversion circuit configured to convert a first voltage present on wires in the wall to a lower second voltage for supplying at least the microcontroller and the communication module. The power conversion circuit is preferably arranged in or against the rear of the rear base part.

The base may further comprise a measuring circuit configured to measure a quantity representative of the power consumed by a load connected to the socket function and the measuring circuit may be connected to the microcontroller. The microcontroller is configured to communicate the variable via the communication module. If the measuring circuit comprises a low-voltage measuring IC, this measuring IC may be provided in the front base part, and an electrical connection may be provided between the front base part and the rear base part around a quantity representative of the power, for example a voltage across transfer a shunt resistor to the measuring IC.

In an exemplary embodiment, the controllable switch and the power conversion circuit are mounted on a PCB, which PCB is connected to the rear of the rear base part. The PCB may comprise a circuit on both sides, for example a relay on a first side, the relay extending into a cavity in the rear of the rear base part, and a power conversion circuit on the other side. Furthermore, the microcontroller and the communication module can be arranged on a second PCB, which second PCB is arranged between the front base part and the rear base part, preferably in a cavity of the rear side of the front base part. In other exemplary embodiments, the electronic circuit may include specifically integrated circuits.

The microcontroller may be configured to process data received by the communication module and to configure or operate the electrical function accordingly, and / or to transmit data wirelessly through the communication module to another electrical assembly and / or to a mobile device and / or to a gateway. The term "mobile device" can refer to any mobile device such as a smartphone, a smartwatch, a tablet, a laptop, a proprietary remote control, etc.

In an exemplary embodiment, two communication modules may be provided: a first communication module configured to operate in a spectrum range above 1.5 GHz; and a second communication module configured to operate in a spectrum range below 1.5 GHz. According to an alternative, the second or the first communication module can be provided. In an embodiment with two communication modules, two antennas or one antenna covering the full frequency range of both communication modules can be provided. When second antennas are provided, both antennas can be provided at or in the central element. According to an alternative, one antenna can be provided at or in the central element and the other antenna can be provided in the base.

Brief description of the figures

The attached drawings are used to illustrate currently preferred non-limiting exemplary embodiments of apparatus of the present invention. The above-mentioned advantages and other advantages of the features and objects of the invention will be better and the invention will be better understood from the following detailed description when read together with the attached drawings, in which:

Figure 1 illustrates a cut-away perspective view looking from the front to the rear of a first exemplary embodiment of a socket assembly of the invention;

Figure 2 illustrates a cut-away perspective view looking from the rear to the front of the first exemplary embodiment of a socket assembly according to the invention;

Figures 3A and 3B are respective views of the assembly in the mounted position with and without plug inserted into the socket;

Figure 4 is a detailed perspective view of the assembled base and the central element of the first exemplary embodiment, looking from the front to the rear; Figures 6A and 6B are perspective views of the first and second electronic circuit according to an exemplary embodiment of the invention; and Figure 7 illustrates a variant of the central element of Figure 5.

Description of embodiments

Figures 1, 2, 3A and 3B, 4 and 5 illustrate a first exemplary embodiment of the socket assembly for mounting in a wall. The socket assembly controls the power supply to an electrical device via a plug 90 inserted into the socket. The assembly is intended to be built into an opening in the wall, the socket function 50 being connected to electrical wires present in the wall. Typically, the electrical wires in the wall include wires connected to the power supply.

In the first exemplary embodiment, the electrical assembly comprises a multi-part base 10, 20 and the cover 60. The base 10, 20 comprises an electrical function, here a socket function 50 with contact sockets. The base 10, 20 is intended and measured to be at least partially built into an opening in the wall. To that end, the assembly can further comprise a mounting box 80 which can be arranged in the opening in the wall and which is dimensioned and adapted to receive the base 10, 20. The electrical wires present in the wall extend into the mounting box 80 and are connected to contacts 51, 52, 53 of the socket function 50 in the base 10, 20 in a known manner. In the first exemplary embodiment, the cover 60 is a multi-part cover which is adapted to be attached to the base 10, 20 and to cover the opening in the wall, see also figures 3A and 3B.

The cover 60 comprises a central element 64 comprising at least two holes 63 for receiving at least two pins of a plug 90 for electrically connecting to the socket function 50. The central element 64 is removably attachable to the base 10, 20 by by means of a central screw 69, with a rear side of the central element 64 against a front side 11 of the base 10, 20.

The base comprises a rear base part 20 with a back side 22 and a front side 21, a proposed base part 10 with a back side 12 and a front side 11. The front base base part 10 can be a plastic part 14, for example a part manufactured by injection molding, and a metal frame 16 include. The metal frame 16 can be provided with several holes and / or with several protruding parts for fixing purposes. The rear base part 20 is typically a plastic part, for example manufactured by injection molding. The rear side 22 of the rear base part 20 faces away from the cover 60, and the front side 11 of the front base part 10 faces the cover 60. The front side 21 of the rear base part 20 is attached to a rear side 12 of the front base part 10. The rear base part 20 is provided with a first electronic circuit 30. The front base part 10 is provided with a second electronic circuit 40 which is connected to the first electronic circuit 30.

The multi-part cover 60 comprises a cover frame 62 (also called mounting frame plate) and a central element 64 (also called central plate or finishing set). When mounting the assembly, the multi-part pedestal 10, 20 with the first and second electronic circuit is first arranged in the mounting box 80, and then the central element 64 is attached to the pedestal 10, 20, after which the cover frame 62 is mounted around the central element 64. The central element 64 is preferably made of a plastic material or other material that does not significantly affect the operation of the antenna. The base 10, 20, and typically the front base part 10, may be provided with a metal frame 16 configured to secure the base 10, 20 in the opening in the wall.

The central element 64 is provided with an antenna 66, for example a dipole antenna. The dipole antenna 66 comprises a first metal part 66a which is provided with a first contact part 67, and a second metal part 66b which is provided with a second contact part 68, see figure 5. The contact parts 67, 68 can be electrically connected to one or more communication modules 43 when the central element 64 is mounted against the base 10, 20. The antenna 66a, 66b is arranged in a zone of the central element 64 that is not covered by the plug 90 when the plug 90 is inserted. The central element 64 has a front side which is provided with a cavity 161 for receiving the plug 90, and the antenna 66a, 66b is arranged at the rear side of the central element 64 in a zone around the cavity 161. The rear side of the central element 64 central element 64 is provided with a groove 163 in which the antenna 66 is mounted. The cavity 161 in the front corresponds to a protruding part 162 at the rear of the central element 64, and the groove 163 extends around the protruding part 62.

The rear of the central element 64 is provided with contact terminals 67, 68 and the front of the base is provided with corresponding contact terminals 117, 118 which are connected to the one or more communication modules 43 such that the antenna 66 is automatically electrically connected to the one or more communication modules 43 when the central element 64 is attached to the base 10, 20. In the illustrated exemplary embodiment, the contact terminals 67, 68 on the rear of the central element 64 are positioned on the projecting part 162, and the at least one corresponding contact terminal 117, 118 provided on the front side 11 of the base 10, 20.

An exemplary embodiment of the first and second electronic circuits 30, 40 is shown in more detail in Figures 6A and 6B. The first electronic circuit 30 comprises a PCB 31 on which a number of electronic components 33, 34, 35 and 36 are mounted and connected. The PCB 31 has a front side 37 which is arranged against the rear side 22 of the rear base part 20, and a rear side 38. A relay 32 is mounted on the front side 37 of PCB 31. For accommodating relay 32, a cavity 23 is provided in the rear side 22 of the rear base part 20. At the rear side 38 of PCB 31, a power conversion circuit 33, a protection circuit 34, a shunt resistor 35, and a fuse 36 are provided. The first PCB 31 can be protected against damage by a cap 70 mounted over the first circuit 30 on the rear of the rear base part 20.

The power conversion circuit 33 is arranged to convert a first voltage present on the wires in the wall into a second lower voltage, typically 12 or 24 Volt DC, for supplying low voltage components of the first and / or second circuit. In the exemplary embodiment of the figures, the low voltage components are part of the second circuit and are mounted on a second PCB 41. The power conversion circuit 33 typically comprises an electrolytic capacitor, an AC / DC converter, and any other component required for connection of the AC / DC converter. The protection circuit 34 can be a voltage-dependent resistor which offers protection against too high transient voltages.

The second PCB 41 is provided in a cavity 13 provided in the rear side 12 of the front base part 10, and more particularly a cavity 13 provided in the plastic part 14 of the front base part 10. The second PCB 41 has a front 47 and rear 48.

A microcontroller 42 and a communication circuit 43 are provided on the rear side 48 (shown in Figure 6B, but not in Figures 1 and 5). The communication circuit 43 is connectable to an antenna 66 arranged against a rear side of the central element 64.

The microcontroller 42 is configured to process data received by the communication circuit 43 and to configure or operate the electrical function 50 accordingly, and / or to transmit data wirelessly via the communication circuit 43 to another electrical assembly, to a gateway, or to a mobile device (not shown). The microcontroller 42 may consist of a control unit or a plurality of control units. In the case of multiple control units, the control units may be part of the second circuit, but one or more of them may also be part of the first circuit.

In a special embodiment, the communication circuit 43 may comprise a first communication module and also a second communication module. The first communication module can be configured to operate in a spectrum range that is higher than 1.5 GHz. The first communication module can be, for example, a Bluetooth low energy module that is configured to work according to the Bluetooth lower energy protocol, also called Bluetooth smart protocol, for example as specified in the Bluetooth core specification version 4.0, 4.1 or 4.2. A spectrum range above 1.5 GHz allows for multiple channels and a smaller antenna. This first communication module can be used, for example, to communicate with the mobile device. The second communication module can be configured to operate in a spectrum range below 1.5 GHz, for example between 800 and 900 MHz. This low frequency range penetrates better through concrete and steel compared to the higher range of the first communication module, and has a longer range for a certain output power. Consequently, the second communication module can be used to communicate with other electrical assemblies in the building.

In addition to the microcontroller 42, other components such as a time knowledge module, a data storage, and a measuring circuit may be provided on the second PCB 41. Such a measuring circuit is configured to measure a quantity representative of the power consumed by a load that is is connected to the socket outlet of the socket assembly. In an exemplary embodiment, a shunt resistor 35 may be provided on the first PCB 31, and the voltage across the shunt resistor 35 may be transferred to a measuring IC (not shown) present on the second PCB 41. The measuring IC (not shown) ) may be provided on the front side 43 of the PCB 41, for example. The measuring IC is connected to the microcontroller 42, and the microcontroller 42 is adapted to communicate this quantity via the communication circuit 43.

A number of interface means, such as an input means, for example a button or a sensor, or an output means accessible from the front side of the cover 60 may also be provided. In the illustrated embodiment, a button 44 is provided on PCB 41, which button can be manually operated by a user to switch the relay 42 manually. The front base part 10 is provided with a hole in which a movable pin 18 is arranged (see figure 4), and the central element 46 is provided with a hole 65 (see figure 2), and the movable pin 18 is accessible through the hole 65 for operating the button 44. More generally, the central element 64 may be provided with a feed-through in which an interface means, such as an input means (e.g. the mechanical button, a touch button, a sensor, etc.), and / or an output means (e.g. a display means, an LED, etc.) is provided or through which an interface means is accessible. Such an interface means can be connected to the PCB 41, and in particular to the microcontroller 42.

The relay 32 is connected to the socket function 50 for controlling the power supply, and the micron controller 42 is configured to control the relay 32. The one or more communication modules 43 are connected to the microcontroller 42. The microcontroller 42, the one or more communication modules 43 and the relay 32 are arranged in the base 10, 20 in such a way that the base 10, 20 can be manipulated by a installer without touching the microcontroller 42, the one or more communication modules 43 and the relay 32. Further, in the exemplary embodiment, components of the first circuit are provided on the rear of PCB 31, and to protect these components, a cap 70 is provided which is mounted on the rear base part 20.

In the embodiment of Figures 6A and 6B, contact terminals 217, 218 are provided in the form of cylindrical spring contacts. According to an alternative, so-called spring fingers can be used. The spring contacts 217, 218 preferably do not protrude outward from the front base member 10. The front base member 10 is provided with holes that allow access to the spring contacts 217, 218. Such an embodiment can be used in combination with the embodiment of figure 7, see further.

Fig. 7 illustrates a variant of the central element 64 of Fig. 5. In the exemplary embodiment of Fig. 7, the antenna parts 66a, 66b each extend substantially half of the circumference of the protruding part 162 instead of substantially a quarter of the circumference as in Figure 5. Further, contact terminals 267, 268 protrude outwards from the rear of the central element 64 such that they can extend into holes in the front base part 10 to make contact with spring contacts 217, 218. The a person skilled in the art understands that other variants are possible. It is also possible to provide a monopole antenna in groove 163 instead of a bipole antenna. Furthermore, it is possible to provide a non-contact coupling such as a capacitive or inductive coupling between the antenna and the communication module instead of a contact coupling.

In the forebed embodiment, the antenna is shown as being mounted in a groove 163. However, in alternative embodiments, the antenna can be at least partially integrated into the central element. If a non-contact coupling is used, the antenna may even be fully integrated in the central element. In an exemplary embodiment, the antenna 66 may be placed in a mold in which the central element 64 is formed. In such embodiments, contact terminals 117, 118 may also be provided in the base 10, 20.

The functions of the various elements shown in the figures, including functional blocks referred to as "units" or "modules" may be provided by specific hardware or hardware capable of executing software together with the modified software. When elements are provided by a processor, the functions may be provided by a single specific processor, by a single shared processor, or by a plurality of individual processors, some of which may be shared. Furthermore, the explicit use of the term "processor" or "controller" may not be construed to refer exclusively to hardware capable of executing software, and a processor may implicitly, without limitation, digital signal processor (DSP) hardware, include a network processor, application specific integrated circuit (ASIC), field programmable gate array (FPGA), read-only memory (ROM) for storing software, random access memory (RAM), and non-volatile storage. Other hardware, both conventional and customized, may also be provided.

Those skilled in the art understand that block diagrams represent conceptual views of illustrative circuits embodying the principles of the invention.

Although the principles of the invention have been set forth with reference to specific embodiments, it is understood that this description was given by way of example only and not as a limitation of the scope of protection defined by the appended claims.

Claims (23)

Conclusions A socket assembly for mounting into a wall for enabling, controlling, or measuring the power supply to an electrical load, said socket assembly comprising a base (10, 20) and a central element (64); wherein the base comprises a socket function (50) and is intended to be at least partially built into an opening in the wall; wherein the central element (64) comprises at least two holes into which at least two pins of a plug can be inserted to be electrically connected to the socket function; wherein the central element (64) is configured to be part of a cover that covers the opening; and wherein the central element is removably attachable to the base, with a rear side of the central element opposite a front side of the base; wherein the base comprises a controllable switch connected to the power supply control function, a microcontroller configured to control the switch, and a communication module connected to the microcontroller; wherein the central element is provided with an antenna, which antenna is connectable to the communication module when the central element is attached to the base. The socket assembly of claim 1, wherein the antenna is disposed in a zone of the central element that is not covered by the plug when the plug is inserted. The socket assembly according to claim 1 or 2, wherein the central element has a front side which is provided with a cavity for receiving a plug, and wherein the antenna is arranged in a zone around the cavity. The socket assembly according to any one of the preceding claims, wherein the antenna is arranged against the rear side of the central element. The socket assembly according to any one of the preceding claims, wherein the rear side of the central element is provided with a groove in which the antenna is mounted. The socket assembly according to claims 3 and 5, wherein the cavity in the front corresponds to a protruding part at the rear of the central element and wherein the groove extends around the protruding part. The socket assembly according to any of the preceding claims, wherein the rear of the central element is provided with at least one contact terminal and the base is provided with at least one corresponding contact terminal connected to the communication module, such that the antenna is automatically electrically connected with the communication module when the central element is attached to the base. The socket assembly according to claims 6 and 7, wherein the at least one contact terminal is positioned on the rear of the central element on the protruding part. The socket assembly according to claim 7 or 8, wherein the at least one corresponding contact terminal on the base comprises at least one spring contact. The socket assembly according to any of the preceding claims, wherein the central element is made of a plastic material. The socket assembly of any one of the preceding claims, wherein the antenna is at least partially integrated into the central element. The socket assembly according to any of the preceding claims, wherein a non-contact coupling is provided between the antenna and the communication module, such as a capacitive coupling. The socket assembly according to any one of the preceding claims, wherein the base is provided with a metal frame configured for mounting the base in the opening of the wall. The socket assembly of any one of the preceding claims, wherein the antenna is one of the following: a dipole antenna or a monopole antenna. The socket assembly of any one of the preceding claims, further comprising a cover frame configured to surround the central element such that the cover frame and the central element cover the entire opening in the wall. The socket assembly according to any of the preceding claims, wherein the microcontroller, the communication module and the controllable switch are arranged in the base in such a way that the base can be manipulated by an installer without having to operate the micro-controller, the communication module and the controllable switch touch. The socket assembly of any one of the preceding claims, wherein the base is a power conversion circuit (33) configured to convert a first voltage present on wires in the wall to a lower second voltage for supplying at least the microcontroller and the communication module. The socket assembly according to any of the preceding claims, wherein the base has a rear base part (20) with a rear (22) and a front (21), and a front base part (10) with a rear (12) and a front (11) ), includes; wherein the rear (22) of the rear base part (20) faces away from the cover and the front (21) of the rear base part (20) is attached to a rear (12) of the front base part (10), the front side (11) of the front base part (10) faces the cover (60); wherein the communication module is accommodated in a cavity of the front base part (20). The socket assembly of claim 18, wherein the controllable switch comprises a relay (32) disposed in a cavity (23) provided in the rear (22) of the rear base part (20). The socket assembly according to claims 17 and 18 or 19, wherein the controllable switch and the power conversion circuit (30) are mounted on a PCB (31), which PCB (31) is attached to the rear (22) of the rear base part (20) ). The socket assembly of any one of the preceding claims, wherein the base comprises a measuring circuit configured to measure a quantity representative of the power consumed by a load associated with the socket function. The socket assembly of claims 18 and 21, wherein the measurement circuit is connected to the microcontroller (42) and the microcontroller (42) is configured to communicate the quantity via the communication module (43). The socket assembly according to any of claims 16-21, wherein the microcontroller and the communication module are mounted on a PCB (41), which PCB (41) is arranged between the front base part (10) and the rear base part (20). A central element (64) for use in a socket assembly according to any one of the preceding claims; said central element (64) comprising at least two holes into which at least two pins of a plug can be inserted to be electrically connected to the socket function; which central element (64) is configured to be part of a cover that covers the opening; and which central element is removably attachable to the base, with a rear side of the central element opposite a front side of the base; wherein the central element is provided with an antenna, which antenna is connectable to a communication module of the base, the central element being attached to the base.