The invention relates to a reconfigurable, shape-changing button for a vehicle and to a vehicle control panel having reconfigurable, shape-changing buttons.
Modern cars have an ever-increasing number of convenience features such as audio systems, navigations systems, telecommunications equipment, climate control systems, power-operated seats, windows and mirrors. The increasing number of features of a car that can be controlled by vehicle occupants has generally resulted in an increased number of buttons, switches and other control elements on the dashboard, on the center console and on door interior consoles. A disadvantage of such complex control panels is that users are often overwhelmed by the large number of buttons and, as a consequence, users have problems finding the buttons or switches that they are looking for. A further disadvantage of conventional buttons, which are usually rigid protrusions on a surface of the vehicle interior, is that not all functions operated by these buttons tend to be used simultaneously by the user. Thus, more information is thrust on to the user than needed. Another disadvantage of conventional buttons is that non-functional buttons or so-called blank buttons are often present as a pre-installed feature in lower end models for future applications.
There have been efforts to mitigate the problems associated with a large number of buttons, switches and control elements in a car. One solution is a touch screen in the dashboard or front console of the vehicle. A user generally selects a desired function by looking for the function in a menu tree on the touch screen. A disadvantage of touch screens using a menu tree is that users may easily get lost in a complicated maze of menus. A touch screen reduces the number of buttons but generally does not simplify the operation of the vehicle. A further disadvantage of touch screens is that they do not have the tactile feel associated with pressing a button which is important both at a feature perception level as well as acting as an inherent feedback mechanism for the user.
It is accordingly an object of the invention to provide a button configuration and a vehicle control panel configuration which overcome the above-mentioned disadvantages of the heretofore-known button configurations and vehicle control panels of this general type and which overcome problems associated with control panels having a large number of buttons and in particular reduce costs, save space and are more user friendly and less confusing.
With the foregoing and other objects in view there is provided, in accordance with the invention, a button configuration including:
a button having a central region and a peripheral region, the peripheral region encircling the central region and defining a surface plane;
the button having an active state and an inactive state;
the central region of the button protruding from the surface plane and providing a push button function when the button is in the active state; and
the central region of the button extending substantially in the surface plane and providing no push button function when the button is in the inactive state.
By providing a reconfigurable shape-changing button that can be active or inactive, it is possible to present to the user only those buttons that the user needs. This reduces the complexity of conventional button consoles and increases user friendliness. The button configuration according to the invention makes it possible to provide buttons on demand rather than providing buttons by default.
According to another feature of the invention, at least the central portion of the button includes a shape memory material. The shape memory material exhibits a bistability such that it forms a protrusion on the surface plane when the button is in the active state; and the shape memory material forms a substantially flat layer extending in the surface plane when the button is in the inactive state.
According to yet another feature of the invention, the shape memory material is a shape memory polymer and/or a shape memory alloy.
According to a further feature of the invention, a continuous layer of a shape memory polymer forms the central region and the peripheral region of the button. Using a continuous layer simplifies the manufacturing process and reduces cost.
In accordance with another feature of the invention, the shape memory material is a shape memory alloy wire mesh; and the shape memory alloy wire mesh is embedded in a flexible material. A NiTi alloy may be used as a shape memory alloy.
In accordance with yet another feature of the invention, the shape memory alloy wire mesh has an ohmic resistance and is configured to be heated with an electric current flowing through the shape memory alloy wire mesh; and the shape memory alloy wire mesh has a memory shape and deforms into the memory shape when heated to a given transformation temperature. An advantage of this embodiment is that no additional heating device is needed for heating the shape memory alloy.
According to a further feature of the invention, the shape memory material is a shape memory alloy thin film; and a flexible material and the shape memory alloy thin film form a sandwich structure. For example, the shape memory alloy thin film may be embedded in the flexible material or may be attached to the flexible material.
In accordance with another feature of the invention, the shape memory material is a shape memory polymer having a memory shape and the shape memory polymer deforms into the memory shape when heated to a given transformation temperature.
According to a further feature of the invention, an internal heating mechanism is integrated with the shape memory polymer. For example, an ohmic resistance may be used to generate heat.
In accordance yet a further feature of the invention, at least the central region of the button includes a compliant mechanism having two stable states such that the central region of the button forms a protrusion on the surface plane defined by the peripheral region when the button is in the active state and the central region of the button is substantially flat and level with the peripheral region of the button when the button is in the inactive state. The protrusion preferably has a hemispherical or dome-shaped surface. Typically, the compliant mechanism includes single-piece flexible structures wherein the structure can deform in three dimensions and transmit force or deliver motion due to an input actuation. An advantage of a compliant mechanism is that there are no joints and as a result no assembly is required which in turn reduces cost. A further advantage of a compliant mechanism without joints is that there is no wear and no backlash.
With the objects of the invention in view there is also provided, a vehicle control panel configuration, including:
a control panel including a button;
the button having a central region and a peripheral region, the peripheral region encircling the central region and defining a surface plane;
the button having an active state and an inactive state;
the central region of the button protruding from the surface plane and providing a push button function when the button is in the active state; and
the central region of the button extending substantially in the surface plane and providing no push button function when the button is in the inactive state. An advantage of such a control panel is that the reconfigurable, shape-changing button functions and feels like a traditional button when it is in the active state and the button seems to disappear when it is in the inactive state.
According to another feature of the invention, the control panel is provided on a vehicle interior component such as a vehicle console, a door panel, a steering wheel or a dashboard.
According to yet another feature of the invention, a control unit is operatively connected to the button for selectively activating and deactivating the button.
In accordance with a further feature of the invention, the control panel includes further buttons operatively connected to the control unit; and the control unit selectively activates and deactivates the buttons for controlling an electronic vehicle subsystem. For example, the control unit could activate those buttons that are used for controlling the stereo system when the vehicle occupant wants to adjust the settings of the stereo system.
According to another feature of the invention, the buttons are configured to control an electronic vehicle subsystem such as an audio system, a navigation system, a climate control system and a communications system.
According to a further feature of the invention, the control unit is configured to activate the button via a voice control.
According to yet another feature of the invention, the control panel includes further buttons having an active state and an inactive state; and the control panel is configured to operate in a plurality of operating modes wherein a respective subset of the buttons is activated when the control panel is in a respective one of the operating modes; and a selection device is connected to the control unit for selecting the operating modes. The selection device may for example be a central scroll wheel close to or on the steering wheel which would allow scrolling through the various modes for the button console. The operating modes may for example include (a) all buttons off, (b) audio control buttons on, (c) radio, music and/or video control buttons on, (d) navigation buttons on, (e) car climate control buttons on, (e) buttons for driver assistance (e.g. cruise control) on, (f) infotainment buttons on, and (h) all buttons on.
In accordance with yet another feature of the invention, a display is disposed adjacent to the button; and the display indicates a function of the button when the button is in the active state.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in a reconfigurable, shape-changing button for a vehicle and a vehicle control panel having reconfigurable, shape-changing buttons, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now to the figures of the drawings in detail and first, particularly, to
The conventional console interface 12 shown in
Above the center display 14 is a slot 11 that receives disks for audio, video or other digital data. Push buttons on either side of the slot 11 are used to control the disk operation. On either side of the center display 14 are rotary knobs 17 that may be used in a traditional manner for adjusting a radio receiver but may also be used to adjust further functions of the vehicle.
Rotary wheels 19 are provided for adjusting the temperature of a seat heating system. Below the rotary wheels 19 are liquid crystal displays 16 that indicate a temperature for the climate control system. Next to the liquid crystal displays 16 are rocker switches 21 that may be used to adjust a speed of a fan for the climate control system. In the center of the vehicle console 10 is a push button for switching on the hazard warning lights. The conventional vehicle console 10 shown in
The shape-changing buttons 22, 24 are connected via connecting lines 27 to a control unit 26. The control unit 26 selectively activates and deactivates the shape-changing buttons 22, 24. A selection device 28 is connected to the control unit 26. The selection device 28 allows a user to select among a number of operating modes of the vehicle console. For example, the user may select an operating mode that activates the audio control buttons or the navigation control buttons. The selection device 28 may for example be a knob or scroll wheel that allows the user to scroll through the various operating modes of the vehicle console 10.
As can be seen when comparing
Shape-changing buttons 22, 24 according to the invention can be devised in various ways.
A button console using buttons as shown in
Each of the shape-changing buttons can be activated individually. Alternatively, groups of buttons can be activated in accordance with their functionality. For example, a set of buttons dedicated to audio functions could be activated together.
The activation of the shape-changing buttons could be performed through the use of a voice control, a central click knob or scroll wheel close to or on the steering wheel to scroll through the various modes for the button console, through a thermal resistive stimulus, or external thermal stimuli.
A preferred embodiment allows the user to scroll through a number of modes for the console that has the shape-changing buttons. The user may for example select the following modes: (a) All buttons off, (b) Audio control buttons on, (c) Radio/music/video control buttons on, (d) Navigation buttons on, (e) Car climate control buttons on, (f) Driver assistance, such as cruise control related functions, on, (g) Infotainment functions on, (h) All buttons on.
When a shape-changing button is switched on, i.e. activated, the button is advantageously configured to be usable with an audible click sound when pressed. In the active state, the shape-changing buttons according to the invention perform like regular buttons in cars, e.g. a ‘volume up button’ when pressed turns up the volume. Further, in case of a lack of space for a large button console, a small array of shape-changing buttons may be provided, each button having various functions depending on the mode it is being used in.
The texture and feel of the shape-changing buttons is advantageously selected such that the buttons are hard enough to not sag when pressed, and soft enough to be pressable and perform the function of a push button. The outer material or covering layer for the shape-changing buttons is generally a flexible material such as a rubber material, silicone or similar materials that are also used for conventional buttons.
Embodiments of shape-changing buttons that require energy for switching from one stable state to another stable state are advantageously connected to the battery supply voltage of the vehicle. The response time of the shape-changing buttons, i.e. the time necessary to go from a flat surface to the final hemispherical shape or other protruding shape would be about one second with a similar time for the return path to the flat state.
Shape-changing buttons according to the invention can be devised in various ways and may for example be based on a three-dimensional shape morphing via compliant mechanisms such as the mechanism shown in
As already mentioned above, the shape-changing buttons may also be made from shape memory polymers. When subjected to thermal stimuli, these shape changing polymers can exhibit a radical change from a rigid polymer to a very elastic state, then back to a rigid state again. In its elastic state, it will recover its memory shape if left unrestrained. For example, it will recover to a dome-shaped structure as shown in
Another possibility to provide shape-changing buttons includes the use of a shape memory alloy wire mesh. In particular, a composite of a flexible material and a shape memory alloy wire mesh is used. Shape memory alloy wires, such as a NiTi alloy wires, can deform to a so-called memory shape extremely rapidly upon heating to a controllable transformation temperature. A reverse bias mechanism can be used to take the wire mesh from the dome-shape, which is the memory shape, back to the flat state or “buttonless” state. Heat can be resistively applied through the conductive alloy wires. By forming a mesh of NiTi wires and embedding the mesh within a flexible material, such as silicone, button-like structures can be easily formed with the right texture. The shape memory alloy wire mesh provides the required bistability for the shape-changing button.
A further possibility to provide shape-changing buttons includes the use of a sandwich structure formed of a shape memory alloy thin film and a flexible material. In this case, the shape memory alloy thin film could be embedded in the flexible material or the shape memory alloy thin film could be attached to a layer of flexible material.
NiTi thin films when heated beyond their transformation temperature and constrained exhibit enormous stresses which can be used to transmit force and motion. By embedding the NiTi thin film in a flexible material such as silicone and providing given constraints, a shape-changing structure with two stable states is provided, i.e. a dome-shape and a flat surface is provided.
The above-described embodiments of shape-changing buttons and consoles using such buttons are only exemplary and further embodiments are within the scope of the invention.
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