FR3147425A1 - ELECTRONIC BOX COMPRISING A WHEEL AND A TWO-POSITION DETECTION SWITCH - Google Patents

Abstract

ELECTRONIC BOX COMPRISING A WHEEL AND A TWO-POSITION DETECTION SWITCH The invention relates to an electronic box comprising a rotatable wheel, a printed circuit (108) having an edge (108a), a switch (110) with a body (110a) fixed to the printed circuit (108), a lever (110b) rotatable on the body (110a) between two activation positions where the switch (110) is fixed so as to present its body (110a) on the printed circuit (108) below the edge (108a) and its lever (110b) beyond the edge (108a), and a transmission system (112) comprising a hub (112a) secured to the wheel and a toothed plate (112b) secured to the hub (112a) and having first teeth (112c) meshing successively with the lever (110b) and where the hub (112a) is arranged, relative to the printed circuit (108), so that the toothed plate (112b) is beyond the edge (108a). Fig. 2

Description

ELECTRONIC BOX COMPRISING A WHEEL AND A TWO-POSITION DETECTION SWITCH

The present invention relates to an electronic housing comprising a rotary wheel and a lever-type detection switch with two activation positions where the movement of the lever is controlled by the wheel.

STATE OF THE PRIOR ART

In many fields such as home automation, a user controls devices using electronic boxes. To do this, the electronic box has buttons, screens, dials, etc.

A dial is a rotating movable device that is operated by the user. The dial rotates around its axis and in turn operates a rotary switch that is integral with the dial and mounted in said axis. The rotary switch is itself mounted on a printed circuit board (PCB).

The different elements are therefore superimposed along the axis, since we have successively the printed circuit, the rotary switch and the wheel. This superposition has the effect that the thickness of the electronic box must take into account all these elements, which makes it relatively thick.

It is therefore necessary to find a different arrangement that allows the thickness of the electronic housing to be reduced.

An object of the present invention is to provide an electronic housing comprising a rotary wheel and a lever detection switch with two activation positions where the movement of the lever is controlled by the wheel and where the position of the switch is offset relative to the wheel.

For this purpose, an electronic box is proposed comprising:

- a housing comprising a cover,

- a wheel mounted mobile in rotation on the cover around an axis of rotation,

- a printed circuit fixed to the housing in a plane perpendicular to the axis of rotation and having an edge,

- a switch with a body fixed to the printed circuit, a lever rotatable on the body between two activation positions which are on either side of a zero position, and a return system which returns the lever to the zero position when it is moved away from it, where the lever is movable about an axis parallel to the axis of rotation, where the switch is fixed so as to present its body on the printed circuit below the edge and its lever beyond the edge, and

- a transmission system transforming the movement of the wheel into a movement of the lever, and comprising a hub secured to the wheel and rotatable about the axis of rotation, and a toothed plate secured to the hub and coaxial with the axis of rotation, where the toothed plate has first teeth distributed angularly and regularly around the axis of rotation, where the hub is arranged, relative to the printed circuit, in such a way that during rotation of the toothed plate, each first tooth meshes successively with the lever and where the hub is arranged, relative to the printed circuit, in such a way that the toothed plate is beyond the edge.

Advantageously, the hub takes the form of a barrel coaxial with the axis of rotation which projects through the cover which has a crown coaxial with the axis of rotation and whose internal diameter is sized to receive the barrel.

Advantageously, the electronic housing comprises a stop system comprising a plurality of second teeth where the second teeth are integral with the hub and distributed angularly and regularly around the hub, and at least one pawl integral with the cover and arranged to engage between two successive second teeth at each stop position of the wheel, and where when the pawl is engaged between two second teeth, the lever is no longer in contact with a first tooth.

Advantageously, the electronic box includes an electrical circuit comprising:

- the switch comprising a neutral line and for each activation position, an activation terminal,

- a control unit,

- for each activation terminal, an activation line electrically connected between the activation terminal and an interrupt input of the control unit,

- cut-off means controlled by the control unit and adapted to alternately take a power supply position in which each activation line is under a non-zero voltage and a non-power supply position in which each activation line is under a zero voltage,

where the control unit is configured to control the cut-off means to switch to the non-powered position during a standby period, then to switch back to the powered position during a wake-up period, where during the wake-up period, the control unit is configured to analyze the logic level of each activation line; if during the wake-up period, one of the logic levels remains at logic level 0, then the control unit is configured to control the cut-off means to switch to the non-powered position during the standby period.

The above-mentioned and other features of the invention will become more apparent from the following description of an exemplary embodiment, said description being given in conjunction with the accompanying drawings, in which:

is a perspective view of an electronic housing according to the invention,

is a perspective view of the interior of the electronic housing according to the invention,

is a sectional view through an axial plane of the electronic housing according to the invention and seen from below,

is a perspective view from below of a cover of the electronic housing according to the invention according to arrow IV of the ,

is a sectional view through line VV of the ,

is a schematic representation of an electrical circuit implemented in the electronic housing according to the invention, and

is a schematic representation of an example of a control unit configured to manage information delivered by the switch.

DETAILED PRESENTATION OF IMPLEMENTATION METHODS

There shows an example of an electronic housing 100 according to the invention. In the invention presented here, the electronic housing 100 comprises a housing 102 and a wheel 104, but it may comprise other elements such as buttons, screens, etc.

The wheel 104 is movable in rotation around an axis of rotation X.

There shows the electronic housing 100 seen in section through a plane containing the axis of rotation X and seen from below.

In the embodiment of the invention presented herein, the housing 102 comprises a bottom tank 102a and a cover 102b which covers the bottom tank 102a. The bottom tank 102a and the cover 102b are fixed to each other to delimit an interior volume 106. The bottom tank 102a and the cover 102b are fixed by any known means such as screws, clips, etc.

The wheel 104 is mounted so as to be able to rotate on the cover 102b.

The electronic housing 100 also includes a printed circuit 108, a switch 110 and a transmission system 112.

The printed circuit 108 is fixed to the housing 102 inside the latter, that is to say inside the interior volume 106 and is inscribed in a plane perpendicular to the axis of rotation X.

The switch 110 is fixed on the printed circuit 108 inside the interior volume 106 and is a lever detection switch with two activation positions like that of the company AlpsAlpine © known under the reference “SSCM110100”. The switch 110 comprises a body 110a which has a fixing face (here the lower face) which is against the printed circuit 108 when it is fixed there. The lever 110b is mounted so as to be able to rotate on the body 110a between two activation positions which are on either side of a zero position. The lever 110b moves in a plane parallel to the printed circuit 108 and it is movable about an axis parallel to the axis of rotation X and therefore perpendicular to the printed circuit 108. The switch 110 also comprises a return system which returns the lever 110b to the zero position when it is moved away from it.

The transmission system 112 transforms the rotational movement of the wheel 104 into a rotational movement of the lever 110b.

There shows more specifically the transmission system 112 which comprises a hub 112a arranged inside the interior volume 106 and secured to the wheel 104. The hub 112a is mounted coaxial with the axis of rotation X and movable in rotation about the axis of rotation X. In the embodiment of the invention presented here, the wheel 104 and the hub 112a are fixed to each other by a clamping screw 114 by sandwiching the cover 102b.

There shows a bottom view of the cover 102b without the hub 112a.

In the embodiment of the invention presented here, to ensure the rotation of the wheel 104 relative to the housing 102, the hub 112a takes the form of a barrel 116 coaxial with the axis of rotation X which projects through the cover 102b which has a crown 118 coaxial with the axis of rotation X and whose internal diameter is dimensioned to receive the barrel 116 and ensure its rotational guidance. The barrel 116 is seen in ghost lines on the . The fit between the barrel 116 and the inner diameter of the crown 118 is preferably of the sliding fit type. In the embodiment of the invention presented here, the crown 118 is made up of three arcuate portions distributed angularly around the axis of rotation X.

The printed circuit 108 has an edge 108a, along which the switch 110 is fixed so as to present its body 110a on the printed circuit 108 below the edge 108a and its lever 110b beyond the edge 108a, that is to say in the void relative to the printed circuit 108.

The transmission system 112 also includes a toothed plate 112b secured to the hub 112a and coaxial with the axis of rotation X. The toothed plate 112b has first teeth 112c distributed angularly and regularly around the axis of rotation X.

The hub 112a is arranged, relative to the printed circuit 108, so that, during rotation of the toothed plate 112b, each first tooth 112c meshes successively with the lever 110b to move it to one or other of the activation positions depending on the direction of rotation.

The hub 112a is arranged, relative to the printed circuit 108, in such a way that the toothed plate 112b is not opposite the printed circuit 108, that is to say that it is beyond the edge 108a.

Since there is no printed circuit 108 opposite the toothed plate 112b and therefore the hub 112a, the toothed plate 112b is not hindered by the components which could be installed on the printed circuit 108, and it can be lowered practically to the same height as the printed circuit 108, which will make it possible to reduce the height of the hub 112a parallel to the axis of rotation X and therefore that of the electronic housing 100.

Furthermore, with such a position of the switch 110, it is possible to change the diameter of the toothed plate 112b by moving the rotation axis X without being hindered by the printed circuit 108 which is not present beyond the edge 108a, and the same printed circuit 108 can then be used for different electronic boxes 100 and different toothed plates 112b.

The rotation of the wheel 104 by a user causes the rotation of the toothed plate 112b and therefore the actuation of the lever 110b in one direction or the other to reach one or the other of the activation positions.

To recognize the user's action on the wheel 104, the electronic box 100 also includes a control unit 120 mounted on the printed circuit 108 and connected to the switch 110 which then includes means for recognizing the activation position reached and sending to the control unit 120 information representative of the activation position reached and depending on this position, the control unit 120 controls an associated system. The associated system is for example a thermostat and the rotation of the wheel 104 controls the value of the set temperature.

To mark stable stop positions for the wheel 104, the electronic housing 100 comprises a stop system 140, one embodiment of which is shown in . The stopping system 140 comprises a plurality of second teeth 142, where the second teeth 142 are integral with the hub 112a and distributed angularly and regularly around the hub 112a and the axis of rotation X.

The stop system 140 also comprises at least one pawl 144 secured to the cover 102b and arranged to engage between two successive second teeth 142 at each stop position of the wheel 104. The pawl 144 takes the form of an elastically flexible arm which moves away from the axis X during rotation of the wheel 104 to pass beyond a second tooth 142 and approaches the axis X to place itself between the two second teeth 142.

In the embodiment of the invention presented in the , there are three pawls 144 distributed around the axis of rotation X and each pawl 144 engages between two successive second teeth 142.

Depending on the shape of the second teeth 142 and of each pawl 144, the rotational movement of the wheel 104 can be limited to a single direction of rotation or be permitted in both directions of rotation.

Furthermore, the stable positions of the wheel 104 are synchronized with the zero position of the lever 110b, that is to say that when the pawl 144 is engaged between two second teeth 142, the lever 110b is no longer in contact with a first tooth 112c and can freely return to its zero position under the effect of the return system.

There shows an electrical circuit 600 including the switch 110 and the control unit 120. The switch 110 has a neutral line 602 and for each activation position, an activation terminal 602a-b.

The electrical circuit 600 comprises, produced on the printed circuit 108, for each activation terminal 602a-b, an activation line 604a-b electrically connected between the activation terminal 602a-b and an interrupt input of the control unit 120. Each activation line 604a-b is energized through a pull-up resistor 606a-b, for example at 5V, where the state of each pull-up resistor 606a-b is controlled through a control line 605 of the control unit 120. When the lever 110b is in the zero position, there is no contact between an activation terminal 602a-b and the neutral line 602, each activation line 604a-b is at logic level 1 allowing the control unit 120 to determine that ... 110b is in the zero position. When the lever 110b tilts in a first direction, contact is made between an activation terminal 602a and the neutral line 602. There is then a voltage drop in the corresponding activation line 604a which goes to logic level 0, the corresponding interrupt input of the control unit 120 is then activated and the control unit 120 thus receives the information that the lever 110b has tilted in the first direction. When the lever 110b tilts in a second direction, contact is made between the other activation terminal 602b and the neutral line 602; There is then a voltage drop in the other corresponding activation line 604b, the corresponding interrupt input of the control unit 120 is then activated and the control unit 120 thus receives the information that the lever 110b has tipped in the second direction.

Thus, depending on the direction of tilting of the lever 110b, the control unit 120 is informed of the direction by the information delivered by the activation line 604a-b associated with said direction of tilting.

In normal operation, the lever 110b always returns to the zero position, and the control unit 120 is then only used very moderately, which limits its electrical consumption. The control unit 120 can then be put into standby mode and is woken up when one of its interrupt inputs is activated.

However, it may happen that the wheel 104 remains blocked so that the lever 110b remains in contact with a first tooth 112c. One of the activation lines 604a-b then remains permanently at logic level 0. This state induces permanent consumption through the pull-up resistor 606a-b associated with this activation line 604a-b.

According to a particular embodiment, the electrical circuit 600 comprises cut-off means which are adapted to alternately take a power supply position in which each activation line 604a-b is under a non-zero voltage (5V) and a non-power supply position in which each activation line 604a-b is under a zero voltage (0V). The cut-off means are controlled by the control unit 120. The cut-off means consist, for example, in the non-power supply position of not powering the pull-up resistors 606a-b through the control line 605 and, in the power supply position of powering the pull-up resistors 606a-b through the control line 605.

According to another embodiment not shown, it is possible to install a switch on each activation line 604a-b, said switch constituting cut-off means which are open in the non-power position.

When the lever 110b remains in contact with a first tooth 112c, the control unit 120 then controls the cut-off means so that they switch to the non-power position (non-power supply of the return resistors 606a-b) for a standby time of the order of 100 ms, then return to the power position (power supply of the return resistors 606a-b) for a minimum wake-up time allowing the control unit 120 to detect a change in position of the lever 110b. This time depends on the desired maximum speed of rotation of the switch and the distance between two teeth 112c.

For the wake-up phase, the control unit 120 switches the cut-off means to the power supply position (power supply of the pull-up resistors 606a-b), then analyzes the logic level of each activation line 604a-b, i.e. the interrupt inputs. If the levels of the two activation lines 604a and 604b indicate that the lever 110b has returned to the initial position, i.e. that the two activation lines 604a and 604b are at logic level 1, then this means that the blockage has been resolved and the control unit 120 can return to normal operation. If one of the logic levels of the two activation lines 604a-b remains at logic level 0, then the blocking persists, and the control unit 120 again commands the cut-off means to switch to the non-power position during the standby period, and so on to save energy.

There schematically illustrates an example of a control unit 120 (“processing system” in English), in the form of electronic circuitry, which is adapted and configured to manage the information delivered by the switch 110.

The control unit 120 comprises, connected by a communication bus 701: a processor or CPU (Central Processing Unit) 702; a RAM (Read-Only Memory) 703; a read-only memory 704, for example of the ROM (Read Only Memory) or EEPROM (Electrically-Erasable Programmable ROM) type; a storage unit 705, such as a hard disk HDD (Hard Disk Drive), or a storage media reader, such as an SD (Secure Digital) card reader; and a communication interface 706 making it possible, among other things, to communicate with the switch 120 via the activation lines 604a-b.

The processor 702 is capable of executing instructions loaded into the RAM 703 from the ROM 704, an external memory, a storage medium (such as an SD card), or a communications network. When the control unit 120 is powered on, the processor 702 is capable of reading instructions from the RAM 703 and executing them. These instructions form a computer program causing the processor 702 to implement all or part of the steps and operations described herein.

All or part of the steps and operations described herein may thus be implemented in software form by executing a set of instructions by a programmable machine, for example a DSP (Digital Signal Processor) processor or a microcontroller, or be implemented in hardware form by a machine or a dedicated electronic component (chip) or a set of dedicated electronic components (chipset), for example an FPGA (Field Programmable Gate Array) component or ASIC (Application Specific Integrated Circuit). Generally speaking, the hardware platform includes electronic circuitry adapted and configured to implement the operations and steps described herein.

Claims (4)

Electronic box (100) comprising:
- a housing (102) comprising a cover (102b),
- a wheel (104) mounted so as to rotate on the cover (102b) around an axis of rotation (X),
- a printed circuit (108) fixed to the housing (102) in a plane perpendicular to the axis of rotation (X) and having an edge (108a),
- a switch (110) with a body (110a) fixed to the printed circuit (108), a lever (110b) rotatable on the body (110a) between two activation positions which are on either side of a zero position, and a return system which returns the lever (110b) to the zero position when it is moved away from it, where the lever (110b) is movable about an axis parallel to the axis of rotation (X), where the switch (110) is fixed so as to present its body (110a) on the printed circuit (108) below the edge (108a) and its lever (110b) beyond the edge (108a), and
- a transmission system (112) transforming the movement of the wheel (104) into a movement of the lever (110b), and comprising a hub (112a) integral with the wheel (104) and movable in rotation about the axis of rotation (X), and a toothed plate (112b) integral with the hub (112a) and coaxial with the axis of rotation (X), where the toothed plate (112b) has first teeth (112c) distributed angularly and regularly about the axis of rotation (X), where the hub (112a) is arranged, relative to the printed circuit (108), such that during the rotation of the toothed plate (112b), each first tooth (112c) meshes successively with the lever (110b) and where the hub (112a) is arranged, relative to the printed circuit (108), such that the toothed plate (112b) is beyond the edge (108a). Electronic housing (100) according to claim 1, characterized in that the hub (112a) takes the form of a barrel (116) coaxial with the axis of rotation (X) which projects through the cover (102b) which has a crown (118) coaxial with the axis of rotation (X) and whose internal diameter is sized to receive the barrel (116). Electronic housing (100) according to one of claims 1 or 2, characterized in that it comprises a stop system (140) comprising a plurality of second teeth (142) where the second teeth (142) are integral with the hub (112a) and distributed angularly and regularly around the hub (112a), and at least one pawl (144) integral with the cover (102b) and arranged to engage between two successive second teeth (142) at each stop position of the wheel (104), and where when the pawl (144) is engaged between two second teeth (142), the lever (110b) is no longer in contact with a first tooth (112c). Electronic box (100) according to one of claims 1 to 3, characterized in that it comprises an electrical circuit (600) comprising:
- the switch (110) comprising a neutral line (602) and for each activation position, an activation terminal (602a-b),
- a control unit (120),
- for each activation terminal (602a-b), an activation line (604a-b) electrically connected between the activation terminal (602a-b) and an interrupt input of the control unit (120),
- cutting means controlled by the control unit (120) and adapted to alternately take a power supply position in which each activation line (604a-b) is under a non-zero voltage and a non-power supply position in which each activation line (604a-b) is under a zero voltage,
wherein the control unit (120) is configured to control the cut-off means to switch to the non-powered position during a standby period, then switch back to the powered position during a wake-up period, wherein during the wake-up period, the control unit (120) is configured to analyze the logic level of each activation line (604a-b). If during the wake-up period, one of the logic levels remains at logic level 0, then the control unit (120) is configured to control the cut-off means to switch to the non-powered position during the standby period.