DE102022001522A1 - Device for displaying variable information - Google Patents

Abstract

The present technical solution fulfills two tasks in equal measure: It makes changeable, digital information visually accessible to people and at the same time achieves high energy efficiency, which only depends on the update interval of the underlying information. To do this, it uses at least one display object, which corresponds to an objective element, whose position on at least one display surface conveys the information to be displayed to the viewer. To make this possible, the at least one display object is connected to at least one connection device behind the display surface. The at least one connecting device is in turn mechanically connected to at least one drive device, which is controlled by at least one control device such that the drive device shifts the position of the connecting device and thus that of the display object on the display surface. At least one holding device ensures that the position of the display object is maintained even without energy supply. This means that the information can be read even if energy supply is not possible, or energy supply can be dispensed with as long as the information displayed does not change.

Description

With the digitalization of almost all areas of people's lives, more and more information is being generated, processed and made available. The networking of everyday life simultaneously enables and stimulates people's need to be informed at all times and everywhere about current personal data, such as private messages or body and fitness values, as well as general and public data such as the weather forecast or current securities prices. Therefore, the technical task is to make the relevant information easily accessible to people. In many cases this is done visually, usually using displays that make the digital, changeable information accessible to people in a variety of forms. The examples of this are diverse and include devices for limited display options such as 7-segment displays through to universal devices with high-resolution screens that allow information to be displayed text-based, graphically or even in moving images. In conventional solutions, the benefit of always having current information available goes hand in hand with low energy efficiency, since conventional display devices generally consume energy to display information as long as the information is kept on the display. The desire and need for high energy and resource efficiency is therefore often not taken into account or only inadequately taken into account.

• Aus US 3 668 106 ist ein Display bekannt, welches universell einsetzbar ist und nur dann Energie aufnimmt, wenn die dargestellte Information geändert wird. Es nutzt dazu Partikel mit unterschiedlichen Reflexionseigenschaften, welche durch eine angelegte Spannung unterschiedliche ausgerichtet werden können. Damit bietet diese Lösung eine vergleichbare Alternative im Bezug auf das Verhalten des Energieverbrauchs, nutzt jedoch eine grundsätzlich andere technische Umsetzung, die sich jedoch vorteilhaft in Verbindung mit der vorliegenden Erfindung einsetzen lässt.
• Aus DE 31 34 356 A1 ist eine mechanische Anzeigeeinheit bekannt, welche Anzeigeobjekte mittels Bandschleifen transportiert, auf einer Matrix anordnet und dadurch eine Information darstellt. Dabei ist die Position der Anzeigeobjekte jedoch auf die Matrixanordnung beschränkt. Der Transport der Anzeigeobjekte erfolgt mittels Bandschleifen, weshalb sich die Anzeigeobjekte nicht auf einer Anzeigefläche bewegen und sich die Information ausschließlich durch die relative Position der Anzeigeobjekte zueinander ergibt.
• Aus DE 10 2013 206 906 B3 ist außerdem ein Display bekannt, das die elektronisch gesteuerte Darstellung von Informationen mit einer mechanischen Darstellung von Informationen durch Zettel oder Magnete verbindet. Jedoch wird hier die variable Information nicht durch die mechanische Darstellung wiedergegeben.

Various solutions are already known for reducing the energy consumption of a display device in the idle state:

• Out of US 3,668,106 A display is known that can be used universally and only consumes energy when the information displayed is changed. To do this, it uses particles with different reflection properties, which can be aligned differently by applying voltage. This solution thus offers a comparable alternative with regard to the behavior of energy consumption, but uses a fundamentally different technical implementation, which can, however, be used advantageously in conjunction with the present invention.
• Out of DE 31 34 356 A1 A mechanical display unit is known which transports display objects using belt loops, arranges them on a matrix and thereby displays information. However, the position of the display objects is limited to the matrix arrangement. The display objects are transported using belt loops, which is why the display objects do not move on a display surface and the information only results from the relative position of the display objects to one another.
• Out of DE 10 2013 206 906 B3 A display is also known that combines the electronically controlled representation of information with a mechanical representation of information using pieces of paper or magnets. However, here the variable information is not represented by the mechanical representation.

Advantages of the invention

The present technical solution fulfills two tasks in equal measure: It makes changeable, digital information visually accessible to people and at the same time achieves high energy efficiency, which only depends on the update interval of the underlying information. To do this, it uses at least one display object, which corresponds to an objective element whose position on at least one display surface conveys the information to be displayed to the viewer. To make this possible, the at least one display object is connected to at least one connection device behind the display surface. The at least one connection device is in turn mechanically connected to at least one drive device, which is controlled by at least one control device such that the drive device shifts the position of the connection device and thus that of the display object on the display surface. At least one holding device ensures that the position of the display object is maintained even without energy supply. This means that the information can be read even if energy supply is not possible, or energy supply can be dispensed with as long as the information displayed does not change. For this reason, the energy consumption of the display device described here depends on the interval in which the information displayed is changed. The longer the interval, the lower the energy consumption. For this reason, this display device is particularly suitable for information that does not change permanently in short intervals, that is, for example, for displaying a weather/temperature forecast, an air, water or body temperature, a date or day of the week, or a charging power or a charge level in a vehicle's battery that slowly discharges again after being charged quickly. However, permanently and/or rapidly changing information can also be displayed, such as the time, the number of messages in an inbox, the number of interactions in social media or the price of foreign currencies or securities. All of the above Information is provided as examples for illustrative purposes only. Due to its structure consisting of at least one display object and at least one display area, the display device enables a high degree of variability in the display options and thus also in the usability for displaying different information. In comparison to a conventional 7-segment display, other values than numerical values can be displayed if necessary. For the example of the weather situation, the display can be done, for example, using generally understandable symbols for sun, rain, clouds, fog, etc. on the display surface (cf. exemplary embodiment in 17 ).

A further advantage of the present technical solution is the possibility of displaying continuous values for changeable information, in that the display object or objects do not have to occupy discrete positions on the display surface, but rather continuously reach any position in the range of movement of the respective drive device through the drive device. When using a digital control device, the position is only limited by the digital resolution and thus by the step size of the control device. However, with conventional methods, the step size can be made sufficiently small so that the viewer sees a quasi-continuous movement of the display object and the positioning does not appear discrete. Preferably, the step size, i.e. the distance with which the display object must be moved at least per step in the case of discrete control, should be chosen to be at most so large that it corresponds to the largest extent of the display object. The flexibility, which is achieved by the non-discrete positioning of the display object or objects on the display surface, also increases the readability and recognition of symbolic information, since it does not have to be laid out in a fixed grid (cf. embodiment in 19 , 21 , 22 ).

A further advantage of the invention is used in an exemplary embodiment in which the display surface can be replaced by the user himself. This means that different information can be displayed, even if, for example, their range of values differs. This embodiment can also be used to vary the design effect of the display area (for example through different colors) or to choose between different language variants. The interchangeability of the display surface is preferably implemented by an easily detachable connection between the display surface and the other mechanics of the display device. For example, a connection is used in which the display surface is equipped with magnets that hold on to iron-containing counterparts on the mechanism. Furthermore, a connection can be implemented, for example, using snap fasteners and/or Velcro and/or a clip connection, which enables the display surface to be easily replaced by the user. It is also possible to create and disconnect the connection using a rotary movement. For this purpose, for example, a bayonet lock or a screw connection, preferably using a knurled screw, can be used. The advantage of the interchangeable display area used in this exemplary embodiment is preferably supplemented by adapted display objects, which can be used in accordance with the display area used. In addition to providing creative freedom, this can also serve to ensure good readability, for example through a high color contrast between the display area and the display object(s). In addition, it enables the display object to clarify the information presented and thereby make it intuitively comprehensible (cf. 8th with stars as display objects on a display area for the sidereal time).

A preferred embodiment of the invention is based on a display surface which is made of a non-magnetic material such as plastic, wood, stone, glass, carbon, solid surface material, concrete, brass, stainless steel or aluminum. This has the advantage that high-quality product design can be achieved based on a closed display area. In this embodiment, the display object is held on the display surface by a magnetic force, which is caused by the fact that either the display object and/or the connecting device are completely or partially magnetic. When the connecting device is relocated, the display object also shifts on the display surface. Preferably, the magnetic force is chosen to be so strong that the display object is held by it, regardless of how the display device is oriented (for example vertically, horizontally or “upside down”).

A further embodiment combines the properties of the invention with a screen display in order to be able to change the representations on the display area. Similar to the user-replaceable display area, this allows, for example, value ranges and/or design of the display area to be variably adapted to the information displayed. For this purpose, a screen display is integrated into the display area, so that the display object is either on this screen display itself or on a surrounding surface can be moved. For this purpose, the connecting device is preferably placed behind the screen display and/or the surrounding surface and holds the display object by a magnetic force which acts through the screen display itself and/or the surrounding surface. In this embodiment, a screen display is preferably used which has little or no power consumption in the idle state. In one embodiment of this embodiment, a glass plate is used as the display surface, which is painted on the back and has recesses in this paint. Behind the glass plate, at the location of the recess in the paint, there is a screen display with electronic paper (cf. US 3,668,106 ) attached, the contents of which are visible to the front through the glass plate. The display object is a metal ball on the glass plate, which is held in a connecting device by a magnet. The connecting device is held on stainless steel rods via plain bearings and connected to the drive device via a trapezoidal spindle. The drive device receives the necessary signals from the control device in order to move the connecting device and thus ultimately move the display object to a defined position. On the other hand, it receives the necessary signals to control the screen display according to the information shown. For example, the displayed scale can be changed or the display area can be supplemented with symbols or text. This can be advantageous, for example, when displaying security prices if the values of the securities displayed differ greatly. A suitable scale can be shown on the screen and supplemented by the alphanumeric abbreviation of the security whose value is currently being displayed as information.

A further exemplary embodiment has the special feature that the drive device and the holding device are integrated with the connecting device in one component and move with it without using a shaft or a toothed belt, for example. This increases the flexibility of positioning, especially if there is more than one connection device for more than one display object. In this embodiment, the connecting device contains neodymium magnets, which hold the display object made of nickel-plated steel through their magnetic force. In this case, the energy supply can take place, for example, via two plates and/or grids made of an electrically conductive but non-magnetic material, such as aluminum, copper, stainless steel and/or brass, between which the connecting device moves and with which it is connected via current collectors (“auto-scooter” principle). The plates are at different electrical potentials. By using electrically conductive but non-magnetic materials, on the one hand the electrical supply to the drive and holding device is made possible, and on the other hand the magnetic force to which the connection device and display object are connected is not disturbed.

Further advantages and improvements result from the features of the dependent patent claims.

drawings

Exemplary embodiments of the invention are shown in the drawings and explained in more detail in the following description.

Figure list

• 1 shows schematically the structure of a first exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 2 shows schematically the structure of a first exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 3 shows schematically the structure of a second exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 4 shows schematically the structure of a second exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 5 shows schematically the structure of a second exemplary embodiment of the present invention in side view
• 6 shows schematically the structure of a third exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 7 shows schematically the structure of a third exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 8th shows schematically the structure of a fourth exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 9 shows schematically the structure of a fourth exemplary embodiment of the present ing invention in the rear view orthogonal to the display surface
• 10 shows schematically the structure of a fifth exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 11 shows schematically the structure of a fifth exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 12 shows schematically the structure of a sixth exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 13 shows schematically the structure of a sixth exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 14 shows schematically the structure of a sixth exemplary embodiment of the present invention in side view
• 15 shows schematically the structure of a seventh exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 16 shows schematically the structure of a seventh exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 17 shows schematically the structure of an eighth exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 18 shows schematically the structure of an eighth exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 19 shows schematically the structure of a ninth exemplary embodiment of the present invention in the front view orthogonal to the display surface with a first exemplary positioning of the display objects
• 20 shows schematically the structure of a ninth exemplary embodiment of the present invention in a perspective view with a first exemplary positioning of the display objects
• 21 shows schematically the structure of a ninth exemplary embodiment of the present invention in the front view orthogonal to the display surface with a second exemplary positioning of the display objects
• 22 shows schematically the structure of a ninth exemplary embodiment of the present invention in the front view orthogonal to the display surface with a third exemplary positioning of the display objects
• 23 shows schematically the structure of a tenth exemplary embodiment of the present invention in the front view orthogonal to the display surface
• 24 shows schematically the structure of a tenth exemplary embodiment of the present invention in the rear view orthogonal to the display surface
• 25 shows schematically the structure of an eleventh exemplary embodiment of the present invention in side view
• 26 shows schematically the structure of an eleventh exemplary embodiment of the present invention in the front view orthogonal to the display area with a first exemplary display area
• 27 shows schematically the structure of an eleventh exemplary embodiment of the present invention in the rear view orthogonal to the display area with a second exemplary display area

Description

1 and 2 show schematically the structure of a first exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 1 ) and the opposite direction ( 2 ). In this embodiment, the display device consists of a display surface (11), a display object (12), a drive device (13), a control device (14), a holding device (15) and a connecting device (16). In this embodiment, the display object (12) is designed as a steel ball that moves on a display surface (11) made of aluminum. The force is transmitted from the connecting device (16) to the display object (12) by a magnet (19) which is attached to the connecting device (16). In this embodiment, the drive device (13) is connected to the connecting device (16) with a belt (18) guided over a deflection roller (17). As a result, the display object (12) is moved by the drive device (13). The control device (14) generates the necessary signals according to the position of the display object required to display the information. In this exemplary embodiment, it receives the necessary data via a wireless communication interface (20). The holding device (15) blocks the belt (18) when stationary was such that the connecting device (16) and thus also the display object (12) remained in the previously reached position without energy supply. The user can read the current information on the display using the scale (21).

3 , 4 and 5 show schematically the structure of a further second exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 3 ), the opposite direction ( 4 ) and the side view ( 5 ). In this embodiment, the display device consists of a display surface (31), a display object (32), a drive device (33), a control device (34) and a connection device (35). In this embodiment, the display object (32) is designed as a steel ball that moves on a display surface (31) made of wood material. The force is transmitted from the connecting device (35) to the display object (32) by a magnetic disk (36) which is attached to the connecting device (35). In this embodiment, the drive device (33) is connected to the connecting device (35) via a self-locking trapezoidal spindle (37) and a bevel gear (38) with a suitable transmission. As a result, the display object (32) is moved by the drive device (33). The control device (34) generates the necessary signals in accordance with the position of the display object (32) required to display the information. The self-locking of the trapezoidal spindle holds the connecting device (35) and thus also the display object (32) in the respective position even without energy supply. The current information on the display can be read by the user based on the position of the steel ball (32) on the display surface (31).

6 and 7 show schematically the structure of a further third exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 6 ) and the opposite direction ( 7 ). In this embodiment, the display device consists of a display surface (41), a display object (42), two drive devices (43) (44), a connection device (45) and a control device (46). In this embodiment, the display object (42) is designed as a magnetic ball that moves on a display surface (41) made of coated glass. The force is transmitted from the connecting device (45) to the display object (42) via a magnetic disk (47) which is attached to the connecting device (45). The two drive devices (43) (44) enable the connecting device (45) and thus the display object (42) to be moved in two dimensions. For this purpose, in this embodiment, the connecting device (45) is connected to the drive device (44) via a ball screw (48), these components being carried by a horizontally aligned linear rail (49). The linear rail (49) is in turn connected at its ends to two vertical linear rails (50) (51), which control the movement of the entire horizontal unit consisting of the display object (42), drive device (44), connecting device (45), magnetic disk (47), ball screw (48), linear rail (49) in the vertical direction. This movement takes place via the drive unit (43), which is connected to the horizontal unit via a ball screw (52) in a vertical orientation and a ball nut (53). The control device (46) generates the necessary signals for vertical and horizontal positioning according to the position of the display object required to display the information. In this embodiment, the holding device (54) prevents the vertically aligned ball screw (52) from moving when at rest. It only releases the ball screw (52) via an electromagnet following a signal from the control device (46) when the display object (42) is to be moved to a new position. In the horizontal direction, the holding device is realized by the self-locking of the ball screw (48). The display object (42) thus remains in the position previously reached without any energy supply. The current information on the display can be read by the user using the scales in the vertical direction (55) and horizontal direction (56).

8th and 9 show schematically the structure of a further fourth exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 8th ) and the opposite direction ( 9 ). In this embodiment, the display device consists of a display surface (61), several display objects (62) (63) (64) (65), several drive devices (66) (67) (68) (69), several connection devices (70) (71 ) (72) (73) and a control device (74). In this embodiment, the display objects (62) (63) (64) (65) are designed as plastic parts into which a sheet steel disk is inserted and which are attached to a display surface (61) made of plastic. The power is transmitted from one of the connecting devices (70) (71) (72) (73) to one of the display objects (62) (63) (64) (65) through a magnetic disk (75) (76) (77) (78), which is attached to the respective connecting device (70) (71) (72) (73). In this embodiment, the respective drive device (66) (67) (68) (69) has a self-locking trapezoidal spindle (78) (79) (80) (81) and a bevel gear (82) (83) (84) ( 85) to the respective connecting device (70) (71) (72) (73). the. As a result, the respective display object (62) (63) (64) (65) is moved by the associated drive device (66) (67) (68) (69), the movement of a display object (62) (63) (64) (65) can be carried out independently of the movement of the other display objects (62) (63) (64) (65). The control device (74) generates the necessary signals in accordance with the position of the respective display object (62) (63) (64) (65) required to display the information. The pitch of the trapezoidal spindles is chosen so that their self-locking keeps the respective connecting device (70) (71) (72) (73) and thus the respective display object (62) (63) (64) (65) at the respective position even without energy supply holds. The current information on the display can be read by the user based on the positions of the display objects (62) (63) (64) (65) on the display surface (61) using the given scale (86). In this exemplary embodiment, the user receives the information about the current sidereal time displayed in four digits, with one of the display objects (62) (63) (64) (65) each representing a digit between zero and nine. In the 8th For example, the information shown corresponds to 1639.

10 and 11 show schematically the structure of a further fifth exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 10 ) and the opposite direction ( 11 ). In this embodiment, the display device consists of a display surface made of wood (91), 14 display objects in the form of steel balls, which are shown as a circle (92) as an example, as well as an associated drive device, shown as an example (93), and a connecting device, shown as an example (94), as well as a common control device (95). The display objects are held on the respective connecting device by the magnetic force of a magnetic disk, shown as an example (96). In this embodiment, the respective drive device is connected to the respective connecting device via a self-locking trapezoidal spindle, shown as an example (97). The connecting device is held on a linear rail, shown as an example (98). As a result, the movement of the respective display object is carried out by the associated drive device, whereby the movement of an individual display object can be carried out independently of the movement of the other display objects. The control device (95) generates the necessary signals according to the position of the respective display object required to display the information. The pitch of the trapezoidal spindles is chosen so that their self-locking holds the respective connecting device and thus the respective display object in the respective position even without energy supply. In this exemplary embodiment, the current value can be displayed as information on the display, for example the air temperature or a security price, based on the position of one of the display objects, for example on the left edge (92) or for example on the right edge (98) or, for example, in the middle area (99) read. In the exemplary embodiment, the current value is highlighted by another different coloring of the display object (99). The scale (100) on the display surface makes it easier to read the value. The independently controllable further display objects on the display surface allow, in addition to the current value, the display of past values (preferably to the left of the display object for the current value) or values predicted for the future (preferably to the right of the display object for the current value) and thereby provide information about the course of the values shown.

12 , 13 and 14 show schematically the structure of a further sixth exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 12 ), the opposite direction ( 13 ) and the side view ( 14 ). In this embodiment, the display device consists of a display surface (111), a display object (112), a drive device (113), a control device (114) and a connection device (115). In this embodiment, the display object (112) is designed as a figure of a motor vehicle that moves on a display surface (111) made of aluminum. The power is transmitted from the connecting device (115) to the display object (112) by two magnetic disks (116) (117) which are attached to the connecting device (115). In this embodiment, the drive device (113) is connected to the connecting device (115) via a self-locking trapezoidal spindle (118) and a spur gear (119) with a suitable transmission. The connecting device (115) is guided by a linear guide (121), with the display object (112) being moved by the drive device (113). The control device (114) generates the necessary signals in accordance with the position of the display object (112) required to display the information. In this exemplary embodiment, it receives the necessary data via a wireless communication interface (120). The self-locking of the trapezoidal spindle holds the connecting device (115) and thus also the display object (112) in the respective position even without energy supply. The current information on the display can be read by the user based on the position of the display object (112) on the display surface (111). The scale (122) supports the user in reading the current len position, wherein the position of the display object (112) in this exemplary embodiment represents information about the charge status of the battery in the motor vehicle.

15 and 16 show schematically the structure of a further seventh exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 15 ) and the opposite direction ( 16 ). In this embodiment, the display device consists of a display surface (131), two display objects (132) (133), two drive devices (134) (135), a control device (136) and two connection devices (137) (138). In this embodiment, the display objects (132) (133) are designed as cuboids made of neodymium magnets that move on a display surface (131) made of plastic. The power transmission from the connecting devices (137) (138) to the respective display object (132) (133) takes place via a steel plate (139) (140) which is mounted on the respective connecting device. In this embodiment, the drive device (134) is connected to the connecting device (138) via a ball spindle (141) and a bevel gear (142) with a suitable transmission. The connecting device (138) is guided by a linear guide (143), with the display object (133) being moved by the drive device (134). In this embodiment, the drive device (135) is also connected to the connecting device (137) via a ball spindle (144) and a bevel gear (145) with a suitable transmission. The connecting device (137) is guided by a linear guide (143), with the display object (132) being moved by the drive device (135). In the idle state, in this exemplary embodiment, a holding device (146) (147) prevents the rotation of the ball spindle and thus the movement of the display objects (132) (133) via a spring force, even without energy supply. When one of the display objects (132) (133) is repositioned, the respective holding device (146) (147) is released by an electromagnet so that the movement of the respective ball spindle (141) (144) and thus the respective connecting device (137) (138) is possible is. By using the same linear guide (143) of both connecting devices (137) (138), the position of the two display objects (132) (133) is not independent of one another. In this exemplary embodiment, the connecting device (138) can never assume a position on the linear guide that is further away from the end of the linear guide facing the drive units (134) (135) than the position of the connecting device (137). However, this is not disadvantageous for the exemplary embodiment, since the information displayed consists of minimum and maximum values, such as the minimum and maximum expected air temperatures of the following days or the minimum and maximum price of a security over the course of the day. The control device (136) generates the necessary signals corresponding to the positions of the display objects (132) (133) required to display the information and ensures that the positions meet the restrictions imposed by the mechanical structure.

17 and 18 show schematically the structure of a further eighth exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 17 ) and the opposite direction ( 18 ). In this embodiment, the display device consists of a display surface (151), a display object (152), a drive device (153), a control device (154) and a connection device (155). In this embodiment, the display object (152) is designed as a steel frame that moves on a wooden display surface (151). The force is transmitted from the connecting device (155) to the display object (152) by two magnets (156) (157) which are attached to the connecting device (155). In this embodiment, the drive device (153) is connected to the connecting device (155) with a belt (160) guided over a drive roller (158) and a deflection roller (159). As a result, the display object (152) is moved by the drive device (153). The control device (154) generates the necessary signals according to the position of the display object required to display the information. In this exemplary embodiment, the current information on the display can be read by the user based on the position of the display object in relation to the symbols on the display surface (151), such as that of the snowflake (161). An explicit holding device is not required in this exemplary embodiment, since the holding force resulting from the frictional forces of the belt and the drive is sufficient if the device is used horizontally.

19 , 20 , 21 and 22 show schematically the structure of a further ninth exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 19 ) and a perspective view ( 20 ). In this embodiment, the display device consists of a display surface (171) with several display objects in the form of steel balls, for example the balls (172) (173) (174). In this embodiment, the display area (171) is optically divided into a display area (175) and a storage area (176). The display objects can be viewed on the back Move the connecting and drive devices installed horizontally. Three display objects, for example the balls (172) (173) (174), move on the same path in a horizontal direction. The information is created by the relative position of the display objects to one another, provided they are in the display area (175). If not all display objects are required to display the information to be displayed, the remaining ones move to a position in the storage area (176). In this embodiment, the arbitrary, non-discrete positioning of the display objects in the horizontal direction is particularly advantageous for displaying the information. This allows you to display a wide variety of information, such as: 21 and 22 additionally clarify with an example.

23 and 24 show schematically the structure of a further tenth exemplary embodiment of the display device. The structure is shown in the view orthogonal to the display area ( 23 ) and the opposite direction ( 24 ). In this embodiment, the display device consists of a circular display surface (181), a display object (182), two drive devices (183) (184), a control device (185) and a connection device (186). In this embodiment, the display object (182) is designed as a ball that moves on a wooden display surface (181). The power is transmitted from the connecting device (186) to the display object (182) by a magnetic disk (187) which is attached to the connecting device. In this embodiment, the drive device (183) is mounted in the middle of the display surface (181) and therefore allows the drive device (184) and the connecting device (186) and thus the display object (182) to rotate around the center of the display surface (181). In this embodiment, the drive device (184) is connected to the connecting device (186) via a trapezoidal spindle (188). The connecting device (186) is guided by a linear guide (189), whereby the connecting device (186) and thus the display object (182) are moved in the radial direction by the drive device (184). In the idle state, in this exemplary embodiment, a holding device prevents, on the one hand, the rotational movement and, on the other hand, the movement in the radial direction of the connecting device (186) and thus of the display object (182). The holding device (190) is based on an electromagnetic brake that is mounted on the drive device (183) and is released during movement by means of an electromagnet. The holding device for the movement in the radial direction is provided by the self-locking of the trapezoidal spindle (188). The control device (185) generates the signals necessary for movement for the drive devices (183) (184) in accordance with the position of the display object (182) required to display the information, which allows the display of two-dimensional information due to the two degrees of freedom of rotation and radial direction. In this exemplary embodiment, it receives the necessary data via a wireless communication interface (191). To make reading easier for the user, a corresponding scale for both directions (192) (193) is printed on the display surface (181).

25 and 26 show schematically the structure of a further eleventh exemplary embodiment of the display device. The structure is shown in a side view orthogonal to the display area ( 25 ) and the frontal view ( 26 ). In this embodiment, the display device consists of a display surface (200), a display object (201), a drive device (202), a control device (203) and a connection device (204). In this embodiment, the display object (201) is designed as a steel ball that moves on a changeable display surface (200) made of plastic. The force is transmitted from the connecting device (204) to the display object (201) by a magnetic disk (205) which is attached to the connecting device (204). In this embodiment, the drive device (202) is connected to the connecting device (204) via a self-locking trapezoidal spindle (206) and a bevel gear (207) with a suitable transmission. As a result, the display object (201) is moved by the drive device (202). The control device (203) generates the necessary signals in accordance with the position of the display object (201) required to display the information. In this exemplary embodiment, it receives the necessary data via a wireless communication interface (208). The self-locking of the trapezoidal spindle holds the connecting device (204) and thus also the display object (201) in the respective position even without energy supply. In this embodiment, the display surface (200) is attached to two fastening devices (211) (212) made of an iron-containing material with two magnets (209) (210). A wide variety of display surfaces can be attached, such as: 27 additionally illustrated by example. The current information on the display can be read by the user using the printed scale (213) (214) on the attached display surface (200).

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 3668106 [0002, 0007]
• DE 3134356 A1 [0002]
• DE 102013206906 B3 [0002]

Claims (13)

Display device for displaying at least one variable piece of information, characterized in that - at least one display surface is attached between the display object and the connection device - at least one display object represents information through its position on the display surface - at least one connection device connects at least one display object to at least one drive device - at least one control device which controls at least one drive device in such a way that it moves the display object to different positions on the display surface via the connection device - at least one holding device holds the display object in position even without energy supply. display device Claim 1 , characterized in that - the display object partially or completely consists of a magnetic and/or magnetizable material - the display surface partially or completely consists of a non-magnetic material - the display object is connected to the connecting device by a magnetic force. Display device according to one of the preceding claims, characterized in that at least one display surface is intended to be replaced by the user. display device Claim 3 , characterized in that the display surface is attached to the display device with at least one of the following elements: magnet, push button, clip, Velcro, screw, bayonet connector, clamp connector. Display device according to one of the preceding claims, characterized in that at least one screen display is integrated into at least one display area, which enables a changeable display on the display area. Display device according to one of the preceding claims, characterized in that the holding device is based on the use of gravity. Display device according to one of the preceding claims, characterized in that the drive device is connected to the connecting device by a belt and/or a chain and/or a spindle. Display device according to one of the preceding claims, characterized in that the holding device is designed by a self-locking trapezoidal spindle. Display device according to one of the preceding claims, characterized in that the drive device is designed by a stepper motor. Display device according to one of the preceding claims, characterized in that the control device communicates wirelessly with a device which provides at least one piece of information to be displayed. Display device according to one of the preceding claims, characterized in that the display object can be moved on the display surface in one and/or two dimensions by the drive device. Display device according to one of the preceding claims, characterized in that the position of the display object on the display surface represents at least one of the following information: state of charge of a battery, state of charge of a battery of an electric vehicle, charging power of a battery, fill level of a tank, distance of an object to a reference point, Speed of an object, time, elapsed time of a period of time, date, air temperature, water temperature, air quality, UV index, weather conditions, volume, body temperature, heart rate, number of messages in an inbox, number of interactions in a social media, number of people in a room, Securities price. Display device according to one of the preceding claims, characterized in that the display object corresponds to a figure which is related to the information displayed.

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