A touch-screen control panel interface has a dielectric flat or curved front panel and a printed circuit board with a front side and a reverse side which is the component side. Alphanumeric display module(s) or an LCD display and optional protective cap mounted on the reverse side of the circuit board are visible through window cutout(s) on the board. An array of LED indicators can be mounted on the back side of the circuit board and visible through cutouts in the board. Metallized capacitive pads on or adjacent the back side of the front panel at touch locations permit selection of various modes, functions, and settings. These pads may be formed on the flat front side of the circuit board, on the back of the front plate, or on an intermediate membrane. A microprocessor is connected with the various components and with capacitive pad. Icons may be printed onto the flat panel, in registry with the metallized capacitive electrode pads. A potting dam is formed of a back plate configured to adhere to the front panel and an open frame extending rearwards. Synthetic resin potting material fills the frame and hermetically seals the circuit board. Positions of the capacitive touch pads can be illuminated when active, as a guide for the user or operator. A second circuit board may be positioned in the frame directly proximal of the first circuit board, and optionally encapsulated.

A sensor element device for a capacitive touch switch of an operating device faces with an upper side toward the underside of a control panel of the operating device and has an illuminated display with a lighting means. Provided around the lighting means is a housing with fastening means for fastening the sensor element device to a component carrier. Provided on the outside of the housing or of the structural unit, in the region toward the upper side there is electrically conductive plastic that extends along an outer periphery of the housing. From the electrically conductive plastic there extends in the direction of the underside, toward the component carrier, a contacting means for the electrical connection thereto.

The present disclosure discloses a power supply socket with vibration touch keys, and relates to a touch power supply socket used on an electric kettle and a coffee pot. The power supply socket comprises a face shell, a bottom cover, a lower connector, a control circuit board and a power cord, wherein the inner side of the face shell is provided with a vibration motor installing groove, a vibration motor is installed in the vibration motor installing groove, the vibration surface of the vibration motor is in close contact with the bottom plane of the vibration motor installing groove, the vibration motor is electrically connected with the control circuit board, and the vibration motor has synchronous vibration signal feedback when a finger touches a key. The key of the present disclosure has good waterproof, dustproof, LED light guiding and vibrating effects.

There is described a motor vehicle control device (10), with an at least partly electrically conductive control unit (12) which on an actuating surface (14) includes at least one capacitive actuating area (26), and a printed circuit board (20) associated to the control unit (12), which is spaced from the actuating surface (14) and comprises at least one electrode (34). The capacitive actuating area (26) comprises at least one sensor surface (24) provided on the actuating surface (14), which via at least one electrically conductive portion (28) of the control unit (12) and a press connection element (32) is electrically and directly connected with the at least one electrode (34) on the printed circuit board (20). The printed circuit board (20) and the control unit (12) are pressed against each other, wherein the press connection element (32) is mechanically connected with the electrode (34) and/or the electrically conductive portion (28). There is furthermore described a method for manufacturing an at least partly electrically conductive control unit (12) for a motor vehicle control device (10).

An electronic sensor module for a handle may have one sensor unit having a movable sensor element and a fixed sensor element which is arranged spaced apart from and opposite the movable sensor element. The module may also have an electronics unit which is electrically connected to the sensor elements for triggering a switching signal and on which the fixed sensor element is arranged. At least the movable sensor element may be encapsulated at least in some regions by a foam material and is designed as an integrated component in the form of a preassembly unit. Connection elements of the movable sensor element protrude from the foam material in a preassembly state and are connected to the electronics unit in an assembled state. A handle module and to a movable vehicle element are also described.

A laundry treating apparatus includes a cabinet for forming an appearance of the laundry treating apparatus, wherein the cabinet has a laundry inlet defined therein, a drum disposed inside the cabinet, wherein a drum opening in communication with the laundry inlet is defined in the drum, wherein the drum accommodates laundry therein, and a control unit disposed in the cabinet to receive a control signal. The control unit includes a touch portion for forming an exposed surface outwardly of the cabinet, a circuit board spaced apart from the touch portion and positioned inside the cabinet, and a spring unit having a portion on one side in contact with the touch portion and a portion on an opposite side coupled to the circuit to connect the touch portion and the circuit to each other. The spring unit transmits an electrical signal input through the touch portion to the circuit board.

A capacitive button interface assembly (100) and a method for assembling the same, comprising a housing member (202), an electrode board (204) coupled to the housing member (202), one or more resilient members (212) positioned between the housing member (202) and the electrode board (204), one or more alignment members (216) coupled to the electrode board (204), operable to align the electrode board (204) with respect to the housing member (202), and a cover (804) coupled to the housing member (202) to apply a force on the electrode board (204).

An earphone includes a housing that defines a force input surface opposite a touch input surface. A spring member in the housing includes a first arm that biases a touch sensor toward the touch input surface. The spring member also includes a second arm that biases a first force electrode toward the housing and allows the first force electrode to move toward a second force electrode when a force is applied to the force input surface. A non-binary amount of the force is determinable using a change in a mutual capacitance between the first force electrode and the second force electrode. The mutual capacitance between the first force electrode and the second force electrode may be measured upon detecting a touch using the touch sensor.

Household appliance (2) with a user interface (20) comprising: •—a display (64), •—a switch element (56) associated to said display (64) comprising at least one capacitive sensing element (58) with a sensing surface, •—a capacitive sensing circuit (62), •—a control unit (68) connected to said display (64) and to said capacitive sensing circuit (62), configured to control said household appliance (2) and/or said display (64) in function of a signal received from said capacitive sensing circuit (62) after a user interaction on the capacitive sensing element (58) of said switch element (56), whereby said capacitive sensing element (58) is built as a PCB (60) where the capacitive sensing circuit (62) is provided.

An earphone includes a housing that defines a force input surface opposite a touch input surface. A spring member in the housing includes a first arm that biases a touch sensor toward the touch input surface. The spring member also includes a second arm that biases a first force electrode toward the housing and allows the first force electrode to move toward a second force electrode when a force is applied to the force input surface. A non-binary amount of the force is determinable using a change in a mutual capacitance between the first force electrode and the second force electrode. The mutual capacitance between the first force electrode and the second force electrode may be measured upon detecting a touch using the touch sensor.