DE202023102682U1 - Display device, human-machine interaction system and household appliance - Google Patents

Abstract

Display device, characterized in that the display device comprises:
a first display unit (1);
a second display unit (2);
a first prism (3), which is designed as an isosceles right-angled triangular prism;
a second prism (4), which is designed as a straight parallelepiped prism, an isosceles trapezoidal prism or an isosceles right-angled triangular prism; and
two layers with both transmission and reflection effects, the first prism (3) and the second prism (4) being joined together to form a straight square prism with a bottom surface in the form of a right-angled trapezoid, with a first layer (5) with both transmission as well as reflection effect is arranged between the first prism (3) and the second prism (4) and a second layer (6) with both transmission and reflection effect is arranged on a slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid, and the first display unit (1) and the second display unit (2) are arranged vertically next to each other on the first prism (3) and the second prism (4), so that the light emitted by the first display unit (1) and the light emitted by the second display unit (2) is rectified after being reflected by the second layer (6) with both transmission and reflection effects.

Description

The present utility model relates to a display device, a human-machine interaction system and a household appliance.

Nowadays, industrial products, especially household appliances, often have a variety of functions and states. Regarding display devices for displaying these functions and conditions to the user, manufacturers are increasingly seeking a new, unconventional appearance, particularly a substantially transparent appearance. Some attempts have been made to this end in the prior art. For example, semi-transparent OLED display screens are used, but this is still very expensive these days; or a display solution is used that involves projecting onto a glass or translucent film, but this introduces many limitations in both application scenarios and installation settings; Another example is hologram projection technology, which is not yet mature for use in industrial products, especially household appliances.

There is therefore a need for a display device that can display display content using a substantially transparent medium and can display the largest possible number of display content on a limited size with low manufacturing costs.

The object of the present invention is to provide a display device, a human-machine interaction system and a household appliance which display display content using a substantially transparent medium and can display the largest possible number of display content on a limited area with low manufacturing costs.

This object is achieved by a display device according to the present utility model, a human-machine interaction system according to the present utility model and a household appliance according to the present utility model.

A first aspect of the invention relates to a display device comprising: a first display unit; a second display unit; a first prism formed as an isosceles right triangle prism; a second prism formed as a straight parallelepiped prism, an isosceles trapezoidal prism or an isosceles right triangle prism; and two layers with both transmission and reflection effects, the first prism and the second prism being assembled into a straight square prism with a bottom surface in the form of a rectangular trapezoid, with a first layer having both transmission and reflection effects between the first prism and the second prism is arranged and a second layer with both transmission and reflection effects is arranged on an incline of the straight square prism with a bottom surface in the form of a right-angled trapezoid, and the first display unit and the second display unit are each vertically next to one another on the first prism and the second prism are arranged so that the light emitted from the first display unit and the light emitted from the second display unit are rectified after being reflected by the second layer with both transmission and reflection effects.

In the context of the present utility model, a prism is understood to be a polyhedron made of transparent material. A first prism, which is designed as an isosceles right-angled triangular prism, is understood to mean a transparent straight triangular prism which has a bottom surface in the form of an isosceles right-angled triangle, i.e. a straight triangular prism whose bottom surface is a right-angled triangle with two angles of 45°. With regard to the second prism, a straight parallelepiped prism is understood to mean a transparent, straight square prism with a parallelogram-shaped bottom surface; An isosceles trapezoidal prism is understood to mean a transparent, straight square prism with a bottom surface in the form of an isosceles trapezoid. Furthermore, a second prism, which is designed as an isosceles right-angled triangular prism, is also understood to mean a transparent right-angled triangular prism with a base surface in the form of an isosceles right-angled triangle, i.e. a right-angled triangular prism which has a base surface in the form of an isosceles right-angled triangle with two angles of 45°.

According to the invention, the first prism and the second prism, which is designed as a straight parallelepiped prism, an isosceles trapezoidal prism or an isosceles right-angled triangular prism, are joined together to form a straight square prism, the bottom surface of which is a right-angled trapezoid. This means that in the bottom surface of the first prism and the second prism, the hypotenuse of the isosceles right triangle is connected to one side of the parallelogram and to one of the two legs of the isosceles trapezoid or to one of the two legs of the other isosceles right angle Triangle should coincide and one leg of the isosceles right triangle is collinear with another side of the parallelogram and isosceles trapezoid to form a total right angled trapezoid. This requires an acute angle of the parallelogram of 45° or a base angle of the isosceles trapezoid of 45°, while at the same time a base angle of the resulting rectangular trapezoid should also be 45°. Here the plane in which the leg of the right-angled trapezoid lies is called the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid.

A first layer with both transmission and reflection effects is arranged between the first prism and the second prism and a second layer with both transmission and reflection effects is arranged on a slope of the straight square prism with a bottom surface in the form of a rectangular trapezoid. The two layers with both transmission and reflection effects are understood to be layers that enable the transmission of light and the reflection of light. It should be noted here that the two layers with both transmission and reflection effects can simultaneously realize the light transmission effect and the light reflection effect, i.e. incident light is partially transmitted and partially reflected through the layer with both transmission and reflection effects. An example can be a semi-transmissive and semi-reflective layer. Without being limited thereto, the layer having both transmission and reflection effects may also be a layer which achieves the light transmission effect and/or light reflection effect in its various states. An example can be an electrochromic film that achieves the effect of total reflection, full transmission or partial transmission and partial reflection at different applied voltages. Thus, the first prism, the second prism and the two layers with both transmission and reflection effects can be considered together as an optical component.

It is proposed that the first display unit and the second display unit are arranged vertically next to each other on the first prism and the second prism, respectively, so that the light emitted by the first display unit and the light emitted by the second display unit is rectified after reflecting through the second layer with both transmission and reflection effects. For this purpose, one of the first display unit and the second display unit should be arranged on the rectangular surface of the first prism opposite the slope of the straight square prism with a bottom surface in the form of a rectangular trapezoid, while the other of the first display unit and the second display unit should be arranged on the second prism opposite Incline of the first prism should be arranged. This allows light emitted from one of the first and second display units to be transmitted through the first layer with both transmission and reflection effects and reflected on the second layer with both transmission and reflection effects, while light emitted from the other of the first and second display units can be reflected on the first layer with both transmission and reflection effects and on the second layer with both transmission and reflection effects. As a result, light emitted by both the first display unit and the second display unit can be reflected from the second prism on the second layer with both transmission and reflection effects, so that the user can see the display contents of the first display unit and / or the second display unit on the im Essentially transparent medium can be viewed. For this purpose, the slanted area is considered opposite to the existing reflection direction, in which the second layer with both transmission and reflection effects is located. In particular, it should be mentioned that when viewing the slant area against the reflection direction present here, the user can only see a part of the transparent second prism together with the second layer with both transmission and reflection effects on the slant, with the display content in the essentially transparent Medium is displayed and the user can at least partially see the scene behind it through the slanted area, making it possible to create an approximately transparent effect. Especially in this bevel area, a crystal clear display effect is also presented, which can be similar to a visual effect of holographic projection using holographic projection glasses or a visual effect of laser glass internal engraving, which also offers the user a brilliant visual experience and a visual impression of intelligent and modern products can.

Further, according to the present invention, in the case of using the two layers having both transmission and reflection effects, a user can view display contents of the first display unit opposite to the final reflection direction when only the first display unit is illuminated. The user can view display contents of the second display unit against the final reflection direction if only the second display unit is illuminated. Will the If the first display unit and the second display unit are illuminated at the same time, the user can still view the display contents of the first display unit and the second display unit against the final reflection direction on the second layer with both transmission and reflection effects simultaneously. In this way, the present invention achieves the technical effect of displaying as much display content as possible in the limited area with lower manufacturing cost, thereby balancing a contradiction between the diversity of the display content and the simplicity of the display interface.

It should also be noted that the first prism and the second prism, in addition to being used as a transmission medium for light in a display device, are also used as supporting or applying means for the two layers having both transmission and reflection effects in order to reduce the refractive loss of light between different media, in particular at an air-solid interface or a solid-air interface and to enable the two layers with both transmission and reflection effects to be placed flat and stationary in the display device, while the stability and strength of the display device against mechanical stress and vibration is improved. In addition, the first prism and the second prism can also prevent dust and water from entering the display device.

According to an embodiment of the present utility model, the first display unit and the second display unit each comprise one or more of an illuminable icon display, a digital tube display or a dot matrix display screen. According to the present utility model, the first display unit and the second display unit can each be designed as an illuminable icon display, as a digital tube display or as a dot matrix display screen, and the first display unit and the second display unit can also each be a combination of the aforementioned be ads. For example, an illuminable icon display and a digital tube display, or an illuminable icon display and a dot matrix display screen, or a digital tube display and a dot matrix display screen can be integrated into a display unit. It is also possible to integrate an illuminable icon display, a digital tube display and a dot matrix display screen into one display unit. A dot matrix display screen is understood to mean a screen consisting of regularly arranged pixels that is capable of displaying a dynamic and/or graphic representation. In the present utility model, two display units can be implemented in several ways. In particular, the particularly dynamic and/or graphic display effect can be enriched by different types of displays, in particular combinations thereof.

According to one embodiment of the invention, the illuminable icon display has a circuit board with integrated LED elements, a display film with the display icons and a frame between the circuit board and the display film. Here, one or both of the first display unit and the second display unit can be implemented in a simple and cost-effective manner, i.e. by illuminating the display icons on the display film using the LED elements, so that the user can see the illuminated display icons in the opposite direction to the final one Reflection direction can be viewed through a display device to obtain the relevant function or state and the like. The display icon may be formed as a transparent area or hollow area that corresponds to the display content. Preferably, the display icon is printed on the display film by screen printing or inkjet printing. Here, the transparent region means a region which is transparently formed on the substrate of the display film and may also be formed with colors, while the hollow region is a region which is hollowed out in the substrate of the display film. The transparent area or the hollow area can transmit light from the LED elements and display icons that correspond to the display content and can include, for example, text, numbers, patterns, symbols, etc. In order to sufficiently scatter the light emitted by the point light sources of the LED element into flat light and to achieve a uniform lighting effect, it is also conceivable to integrate a light diffusion layer into the display film or to print a light diffusion color onto the display film. However, separate light diffusion films can also be used, which can be overlaid with the display film, in particular by connecting the light diffusion films to the display film, for example by gluing them.

According to an embodiment of the present utility model, the frame includes a plurality of cavities, each cavity receiving at least one of the LED elements to illuminate a display icon arranged on the display film corresponding to the cavities. In this embodiment, the plurality of LED elements may be arranged spaced apart on the circuit board, with the LED elements each being divided into several groups by the frame and its plurality of cavities. Each group of LED elements can contain one or more LED elements. A Display icon can be arranged on the display film corresponding to each cavity. In the case of illuminating a group of LED elements, a display icon can be illuminated via the cavity through a cavity that runs through the frame from top to bottom. Advantageously, in the case that a group of LED elements has a large number of LED elements, only one or some of the LED elements can be illuminated. For example, if four LED elements are accommodated in a cavity, one, two, three, or four LED elements can be illuminated respectively, and thus information can be conveyed to a user with the brightness of the illuminated icons. It is also possible to illuminate the individual LED elements in the group of LED elements in a specific order, for example, to illuminate a row of LED elements in a row lighting mode, a plurality of LED elements in a periodic arrangement in a row lighting mode to illuminate or illuminate a variety of LED elements in a breathing light mode. It is also possible for the multiple LED elements to each have different colors and be illuminated individually or in combination as required.

According to an embodiment of the present utility model, the digital tube display is a segmented LED digital tube, and/or the dot matrix display screen is a TFT display screen, an OLED display screen or a dot matrix LED display screen. Compared to the icon display described above, more extensive dynamic information, in particular graphical display content, can therefore be made available to the user.

According to one embodiment of the present utility model, an area serves as a display surface on which the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid reflects to its adjacent side. The slope can be reflected onto a part of a surface on which the base of a right-angled trapezoid lies on the bottom surface of the straight square prism. This part serves as the display area of the display device. In order to better represent the essentially transparent appearance of the display device according to the present utility model, the first display unit and the second display unit can preferably be accommodated in a housing, in particular in a housing of a household appliance with a display device according to the present utility model. That is, it is possible to arrange only the aforementioned substantially transparent slope portion and the display surface uncovered to the outside of the housing, while hiding parts of the display device that are not transparent by the first display unit and the second display unit.

According to one embodiment of the present utility model, a third prism designed as an isosceles right-angled triangular prism is additionally arranged on the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid in such a way that the first prism, the second prism and the third prism together form a cuboid are put together. In this way, the entire display device is given a square appearance. Furthermore, a sharp, sensitive weak edge is avoided.

According to an embodiment of the present utility model, the first layer with both transmission and reflection effects and the second layer with both transmission and reflection effects are each a semi-transmissive and semi-reflective layer or an electrochromic film. In a cost-effective solution, a semi-transmissive and semi-reflective layer is used for partial transmission and partial reflection of light. Furthermore, it is also conceivable to use an electrochromic film that can be adjusted by applying a voltage. The electrochromic film comprises an electrochromic material selected from the group consisting of tungsten trioxide, polythiophene and derivatives thereof, ultraviolet, tetrathiafulvalene and the like. The electrochromic film can have different light transmittances under two-way voltage control, making the intensity of the reflected light adjustable. For example, the electrochromic film can achieve a total reflection effect and a total transmission effect with or without applied voltage, and the ratio of the transmission and reflection components can be adjusted by adjusting the applied voltage. In particular, the total reflection effect and the total transmission effect can also be achieved while reducing the light loss and increasing the brightness of the display.

According to an embodiment of the present utility model, the semitransmissive and semireflective layer is a semitransmissive and semireflective film, a semitransmissive and semireflective plating or a semitransmissive and semireflective coating. The semitransmissive and semireflective film can be glued to the slope of one of the prisms. The semitransmissive and semireflective film can also be set up with an adhesive force on the two sides, so that the joining of the first prism and the second prism is simplified and ensured ensure that they do not come loose during operation of the display device. It is also preferably conceivable to apply the semitransmissive and semireflective layer as a plating or coating to the slope of the prism, thereby reducing the difficulty of assembly.

According to one embodiment of the present utility model, the semitransmissive and semireflective layer can have a transmittance between 35% and 65%, preferably between 40% and 60%, particularly preferably 50%. Accordingly, the transmittance stated above means that the reflectance of the semi-transmissive and semi-reflective layer can be between 35% and 65%, preferably between 40% and 60%, particularly preferably 50%, neglecting absorption losses. In other words, the beam splitting ratio of the semitransmissive and semireflective layer is between 7:13 and 13:7, preferably between 2:3 and 3:2, particularly preferably 1:1.

According to an embodiment of the present utility model, the first display unit and the second display unit are formed in one piece. Here, for example, a prefabricated housing can be used, in which the first display unit and the second display unit are each mounted in recesses in the housing so that the first display unit and the second display unit are stably mounted perpendicular to one another.

According to an embodiment of the present utility model, the first prism and the second prism each consist of inorganic glass, transparent plastic, transparent ceramic, natural crystal or synthetic crystal. Inorganic glass herein means amorphous solids based on silicate non-metal materials as the main materials. Transparent plastic means a plastic that is highly permeable to visible light, for example acrylic glass (i.e. polymethyl methacrylate, PMMA, as generally acrylic), polycarbonate (PC), polystyrene (PS), transparent acrylonitrile-butadiene-styrene copolymer (ABS), styrene-methyl methacrylate -Copolymer (MS), poly-4-methyl-1-pentene, transparent polyvinyl chloride (PVC), polysulfone, polyethylene terephthalate, transparent epoxy resin and the like. The transparent ceramics may include transparent magnesia ceramics, transparent alumina ceramics, transparent beryllia ceramics and the like. It is also possible to choose the refractive indices of the first prism, the second prism and, if necessary, the third prism as required.

According to an embodiment of the present utility model, one or both of the first display unit and the second display unit is/are displayed at a time. By illuminating the first display unit and/or the second display unit alone or in combination, the display content can be presented to the user in a diversified manner in order to efficiently meet the display requirements of industrial products, in particular household appliances.

A second aspect of the present invention relates to a human-machine interaction system, which comprises a display device according to the present utility model and at least one infrared operating unit for detecting an operation by a user, wherein the at least one infrared operating unit in a first display unit and / or is arranged in a second display unit of the display device. Through the human-machine interaction system according to the present utility model, a user's operation can advantageously be detected based on the principle of infrared reflection in addition to the technical advantages of the display device according to the present utility model. The infrared operating unit can be integrated into one or both of the first display unit and the second display unit and the infrared radiation emitted by the infrared operating unit can take place via the same beam path as the light beam emitted by the respective display unit in the direction of the display surface, while the reflected infrared radiation is due to of the reversible beam path in the display unit returns to the infrared control unit when it is reflected by a user, in particular his hand. The human-machine interaction system can thus recognize an operation by a user. The wavelength of the infrared radiation can be between 770 nm and 1 mm, in particular between 820 nm and 950 nm, preferably 850 nm or 940 nm. For this purpose, the display device, in particular its first prism and second prism, should be designed to be infrared permeable, while the two layers with both transmission and reflection effects can also transmit and reflect infrared radiation.

By way of example, the display film should be configured so that it is hollowed out or infrared permeable in the area of the infrared operating unit if the display unit is designed in such a way that it contains the circuit board with the integrated LED elements, the display film with the display icons and includes the frame between the circuit board and the display film.

Through the human-machine interaction system according to the present invention, the user not only receives a brilliant visual experience and a good visual impression, but can also be targeted directly on the human-machine interaction system or on the surface of the display device, in particular based on its display content operate so that the user can receive an intuitively convenient interaction with an optimized user experience. At the same time, the human-machine interaction system according to the present utility model can avoid the costly arrangement of keys or buttons around the surface of the display device, thereby improving the integration of the system and providing a simple appearance of the human-machine interaction system.

Further, in the human-machine interaction system according to the present utility model, in a case where the first display unit and the second display unit are provided with infrared operation units, the two infrared operation units can be operated simultaneously without affecting each other in a sensible arrangement. For example, the infrared rays emitted by the two infrared operation units in the first display unit and the second display unit and the reflected infrared rays can be separated into different optical paths so as not to interfere with each other.

According to one embodiment of the present utility model, at least one infrared operating unit is designed as a gesture operating unit and/or as a touch operating unit. Here the infrared control unit can be designed in a variety of ways. For example, in a human-machine interaction system, only the gesture operation unit or only the touch operation unit or both the gesture operation unit and the touch operation unit may be provided, and further, an infrared operation unit having a gesture operation and touch operation function may also be provided. Here, the user can perform a touch operation by touching a position on the display surface of the display device in a touch manner; and/or the user can make non-contact gestures in front of a display area of the display device. The gesture may include, for example, sliding, swiping, hovering, tapping, lifting, and the like. By using non-contact gestures, the human-machine interaction system can be kept clean and hygienic and contamination can be avoided.

According to one embodiment of the present utility model, each infrared operating unit comprises at least two infrared transmitting tubes, at least one infrared receiving tube, a control circuit which alternately switches the infrared transmitting tubes and/or the infrared receiving tube on and off, and a signal processor which receives and processes the signal generated by the infrared receiving tubes. For an exemplary embodiment of the infrared operating unit, reference is made here, for example, to the technical content contained in the CN111487878A and CN113495615A of the applicant is disclosed.

According to an embodiment of the present utility model, the plurality of infrared transmitting tubes and a plurality of infrared receiving tubes are arranged alternately along an extension direction of the display unit in which the infrared operating unit is located.

Specifically, in the simplest embodiment variant, the infrared control unit can comprise two infrared transmitter tubes, an infrared receiver tube, a control circuit and a signal processor, with the two infrared transmitter tubes and the infrared receiver tube running along the extension direction of the display unit in which the infrared Control unit is located, alternately arranged at a distance from each other. Here, the respective infrared elements can be arranged along the longitudinal direction of the display device in the order of an infrared transmitter tube behind an infrared receiver tube behind an infrared transmitter tube. During operation, the control circuit turns on the two infrared transmitting tubes one after the other to emit the infrared rays, and when the user's hand approaches, the infrared rays can be reflected and return to the infrared receiving tube arranged between them. The infrared transmitting tubes can be infrared light-emitting diodes, and the infrared receiving tube can be designed as a light-sensitive infrared diode or as a light-sensitive infrared transistor. The signal processor may process and analyze the signal generated when the infrared receiving tube receives the reflected infrared rays to detect a gesture and/or a touch of the user. The signal processor may include a signal processing circuit of the infrared receiving tube and a microprocessor unit for analyzing the signal. For example, by analyzing the timing and signal amplitude of the reflected infrared rays, it can be detected that the user's hand first appears over one of the infrared emitting tubes and then immediately appears over the other of the infrared emitting tubes, thereby making it possible to determine that the user's hand over a Infrared transmitter tube was directed or swung towards another infrared transmitter tube.

In a further, more complex embodiment variant, the infrared operating unit comprises a plurality of infrared transmitting tubes, a plurality of infrared receiving tubes, a control circuit and a signal processor, the plurality of infrared transmitting tubes and the plurality of infrared receiving tubes being positioned along an extension direction of the display unit in which the infrared -Control unit is located, are arranged alternately at a distance from each other and the control circuit serves to control the switching on and off of the respective infrared transmitting tube and the respective infrared receiving tube, and the signal processor serves to control the signals generated by the several infrared receiving tubes to receive and process and to determine the coordinate position of a user's hand in the direction of extension above the infrared control unit. In particular, the control circuit controls the switching on and off of each infrared transmitting tube and each infrared receiving tube in the time division multiplex manner. For example, the control circuit may turn on all infrared receiving tubes simultaneously and turn on each infrared transmitting tube in turn. Alternatively, one or more infrared transmitting and receiving groups are/are switched on one after the other, with each infrared transmitting and receiving group having at least one infrared transmitting tube and at least one infrared receiving tube adjacent thereto. Alternatively, several non-adjacent infrared transmitting and receiving groups are switched on with a time delay, each infrared transmitting and receiving group comprising at least one infrared transmitting tube and at least one adjacent infrared receiving tube.

In particular, in the present embodiment, it is possible to control whether the infrared operation unit is a gesture operation unit or a touch operation unit by setting or adjusting the light emission intensity of the infrared emitter tube. Since infrared rays need to cause refraction loss twice at the solid-air interface in gesture operation detection, it is necessary for the infrared transmitting tube to provide a sufficiently high light emission intensity so that the infrared receiving tube receives the returned infrared rays, and therefore a large driving current for the infrared -Transmitting tube is supplied. On the other hand, if the infrared control unit only detects a touch operation, only a lower light emission intensity is required, so that a lower drive current is required. It is also advantageous to operate the infrared transmitter tube with different currents at different times. It is particularly advantageous to record both touch operation and gesture operation of the same infrared control unit in a time division multiplex manner.

It should be noted that the at least two infrared transmitting tubes and the at least one infrared receiving tube are not necessarily arranged parallel to the edge or along a straight line of the display unit, nor are they necessarily arranged alternately. These infrared transmitting tubes and the infrared receiving tube are preferably arranged alternately in the order of an infrared transmitting tube behind an infrared receiving tube. This means that the infrared transmitting tube and the infrared receiving tube may be positioned on a straight line parallel to a long side of the display unit, on a straight line along a diagonal line of the display unit, or on a multiple line. These infrared transmitting tubes and the infrared receiving tube can be flexibly arranged according to the specific design of the display unit. The distance between the infrared transmitting tube and the infrared receiving tube is preferably 5 mm to 50 mm.

According to an embodiment of the present utility model, the human-machine interaction system issues control commands and changes the display of the display device depending on an operation detected by the infrared operating unit. The human-machine interaction system can serve as an input and output device of an industrial product, in particular a household appliance, display the functions and the status of the industrial product, in particular the household appliance, to the user and, depending on one, detected by an infrared control unit Actuation, such as a gesture operation or a touch operation, which provide control commands from the user to the industrial products, in particular household appliances. In addition, the display of the display device can be changed according to an operation detected by the infrared operation unit. For example, a swipe gesture switches it from the display of the first display unit to the display of the second display unit, and vice versa.

A third aspect of the present invention relates to a household appliance comprising a display device according to the present utility model or a human-machine interaction system according to the present utility model, wherein the first display unit and the second display unit of the display device are accommodated in an interior of a housing of the household appliance. In this way, the user only has the outside of the household appliance that protrudes beyond the housing of the household appliance, essentially transparent part of the display device is observed, and the display contents appear in the essentially transparent medium and the user can at least partially see the scene behind it through the slanted area, which can result in an almost transparent effect. From the user's perspective, the display unit is, as it were, attached to a surface of the household appliance, so that the appearance of the household appliance is newly defined and an impression of intelligent and modern products is created.

According to an embodiment of the present utility model, the household appliance is an air conditioner, an extractor hood, a hob, a refrigerator, an oven, a dishwasher, a food processor, a washing machine, a dryer, an audio device, a television, a smart faucet or a smart toilet.

Further features of the present utility model emerge from the figures and the exemplary embodiments. All features and feature combinations mentioned in the description as well as the features and feature combinations mentioned in the exemplary embodiments and/or shown alone in the figures can be used not only in the combination specified in each case, but also in other combinations or on their own.

• 1 eine Schnittansicht einer Anzeigevorrichtung gemäß einer ersten Ausführungsform der vorliegenden Erfindung;
• 2 eine Schnittansicht einer Anzeigevorrichtung gemäß einer zweiten Ausführungsform der vorliegenden Erfindung;
• 3 eine Schnittansicht einer Anzeigevorrichtung gemäß einer dritten Ausführungsform der vorliegenden Erfindung;
• 4 eine Zerlegungsansicht einer Anzeigevorrichtung gemäß einer ersten Ausführungsform der vorliegenden Erfindung;
• 5 eine Schnittansicht einer Anzeigevorrichtung gemäß einer vierten Ausführungsform der vorliegenden Erfindung;
• 6 eine Explosionsansicht einer Anzeigevorrichtung gemäß einer ersten Ausführungsform der vorliegenden Erfindung;
• 7 eine Explosionsansicht einer Anzeigevorrichtung gemäß einer zweiten Ausführungsform der vorliegenden Erfindung;
• 8 eine schematische Darstellung eines Mensch-Maschine-Interaktionssystems gemäß einer ersten Ausführungsform der vorliegenden Erfindung;
• 9 eine Zerlegungsansicht eines Mensch-Maschine-Interaktionssystems gemäß einer ersten Ausführungsform der vorliegenden Erfindung;
• 10 eine Anordnung einer Infrarot-Bedieneinheit auf der Anzeigeeinheit in einem Mensch-Maschine-Interaktionssystem gemäß der vorliegenden Erfindung;
• 11 eine Anordnung einer Infrarot-Bedieneinheit auf der Anzeigeeinheit in einem Mensch-Maschine-Interaktionssystem gemäß der vorliegenden Erfindung;
• 12 eine Anordnung einer Infrarot-Bedieneinheit auf der Anzeigeeinheit in einem Mensch-Maschine-Interaktionssystem gemäß der vorliegenden Erfindung;
• 13 eine Anordnung einer Infrarot-Bedieneinheit auf der Anzeigeeinheit in einem Mensch-Maschine-Interaktionssystem gemäß der vorliegenden Erfindung;
• 14 eine Anordnung einer Infrarot-Bedieneinheit auf der Anzeigeeinheit in einem Mensch-Maschine-Interaktionssystem gemäß der vorliegenden Erfindung;
• 15 eine Zerlegungsansicht eines Mensch-Maschine-Interaktionssystems gemäß einer zweiten Ausführungsform der vorliegenden Erfindung;
• 16 eine Schnittansicht eines Mensch-Maschine-Interaktionssystems gemäß einer zweiten Ausführungsform der vorliegenden Erfindung;
• 17 ein Haushaltsgerät, an dem eine Anzeigevorrichtung oder ein Mensch-Maschine-Interaktionssystem gemäß der vorliegenden Erfindung angebracht ist.

Several exemplary embodiments are explained in more detail using the following description and the drawing. It shows:

• 1 a sectional view of a display device according to a first embodiment of the present invention;
• 2 a sectional view of a display device according to a second embodiment of the present invention;
• 3 a sectional view of a display device according to a third embodiment of the present invention;
• 4 a disassembled view of a display device according to a first embodiment of the present invention;
• 5 a sectional view of a display device according to a fourth embodiment of the present invention;
• 6 an exploded view of a display device according to a first embodiment of the present invention;
• 7 an exploded view of a display device according to a second embodiment of the present invention;
• 8th a schematic representation of a human-machine interaction system according to a first embodiment of the present invention;
• 9 a disassembled view of a human-machine interaction system according to a first embodiment of the present invention;
• 10 an arrangement of an infrared operating unit on the display unit in a human-machine interaction system according to the present invention;
• 11 an arrangement of an infrared operating unit on the display unit in a human-machine interaction system according to the present invention;
• 12 an arrangement of an infrared operating unit on the display unit in a human-machine interaction system according to the present invention;
• 13 an arrangement of an infrared operating unit on the display unit in a human-machine interaction system according to the present invention;
• 14 an arrangement of an infrared operating unit on the display unit in a human-machine interaction system according to the present invention;
• 15 a disassembled view of a human-machine interaction system according to a second embodiment of the present invention;
• 16 a sectional view of a human-machine interaction system according to a second embodiment of the present invention;
• 17 a household appliance to which a display device or a human-machine interaction system according to the present invention is attached.

In the differently described exemplary embodiments, the same elements have the same reference numerals or the same element names, whereby the disclosures contained in the entire description can be transferred analogously to elements with the same reference numerals or the same element names. Additionally, the number, implementation, and/or arrangement of elements in various embodiments is not limited to the illustrated examples, and other numbers, implementations, and/or arrangements may be selected based on actual needs.

1 shows a sectional view of a display device according to a first embodiment of the present utility model. The display device includes: a first display unit 1; a second display unit 2; a first prism 3 formed as an isosceles right-angle triangular prism; a second prism 4, which is designed as a straight parallelepiped prism; and two layers with both transmission and reflection effects, the first prism 3 and the second prism 4 being assembled into a straight square prism with a bottom surface in the form of a right-angled trapezoid, with a first layer 5 with both transmission and reflection effects between the first prism 3 and the second prism 4 is arranged and a second layer 6 with both transmission and reflection effects is arranged on a slope of the straight square prism with a bottom surface in the form of a rectangular trapezoid, and the first display unit 1 and the second display unit 2 respectively on the first prism 3 and the second prism 4 are arranged vertically next to each other, so that the light that is emitted by the first display unit 1 and the light that is emitted by the second display unit 2 are reflected by the second layer 6 after being reflected both transmission and reflection effects are aligned.

To the in 1 In the embodiment shown, the first prism 3 and the second prism 4, which is designed as a straight parallelepiped prism, should be joined together to form a straight square prism whose bottom surface is a right-angled trapezoid 1 shown sectional view, ie in the bottom surface of the first prism 3 and the second prism 4 the hypotenuse of the isosceles right triangle coincide with one side of the parallelogram and a leg of the isosceles right triangle be collinear with another side of the parallelogram to form a right angled trapezoid overall form. This requires an acute angle of the parallelogram of 45°, while at the same time a base angle of the resulting rectangular trapezoid should also be 45°. Here the plane in which the leg of the right-angled trapezoid lies is called the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid.

A first layer 5 with both transmission and reflection effects is arranged between the first prism 3 and the second prism 4. A second layer 6 with both transmission and reflection effects is arranged on a slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid. The two layers with both transmission and reflection effects are layers that enable transmission of light and reflection of light. It should be noted here that the two layers with both transmission and reflection effects can simultaneously realize the light transmission effect and the light reflection effect, i.e. incident light is partially transmitted through the layer with both transmission and reflection effects and partially reflected thereby. An example of this can be a semi-transmissive and semi-reflective layer. Without being limited thereto, the layer having both transmission and reflection effects may also be a layer which achieves the light transmission effect and/or the light reflection effect in its various states, and an example thereof may be an electrochromic film.

As in 1 As shown, the first display unit 1 and the second display unit 2 are arranged vertically next to each other on the first prism 3 and the second prism 4, respectively, so that the light emitted by the first display unit 1 and the light emitted by the second display unit 2 is emitted, after reflecting through the second layer 6, is rectified with both transmission and reflection effects. The main light path of the first display unit 1 is in 1 drawn schematically with dashed lines. The main light path of the second display unit 2 is drawn schematically with a dash-dot line. The light emitted by the first display unit 1 first penetrates the first layer 5 with both transmission and reflection effects and then reaches the second layer 6 with both transmission and reflection effects on the slope of a straight square prism with a bottom surface in the form of a right-angled trapezoid, where it reflects and finally towards the top of 1 is broadcast. The light emitted by the second display unit 2 is first reflected at the first layer 5 with both transmission and reflection effects, and then reaches the second layer 6 with both transmission and reflection effects on the slope of a straight square prism with a bottom surface in the form of a rectangular trapezoid, where it is reflected again and also towards the top of 1 is broadcast. As a result, light emitted by both the first display unit 1 and the second display unit 2 can be reflected on the second layer 6 with both transmission and reflection effects from the second prism 4, so that the user can view the display contents of the first display unit 1 and/or the second display unit 2 can view on the essentially transparent medium, when viewing the slanted area contrary to the one here Direction of reflection (i.e. in the direction of the hollow arrow in 1 ), in which the second layer 6 is located with both transmission and reflection effects. This bevel area 8 is in 1 marked as an example with a dotted box. When viewing the bevel area 8 in the direction of the hollow arrow in 1 the user sees only a part of the transparent second prism 4 together with the second layer with both transmission and reflection effects on the slope. In the slant area 8, the display content is displayed in the substantially transparent medium and the user can at least partially see the scene behind through the slant area 8, making it possible to create an almost transparent effect.

Furthermore, in the case of appropriate use of the two layers having both transmission and reflection effects, a user can view display contents of the first display unit 1 in the direction of the hollow arrow in the slant region 8 when only the first display unit 1 is illuminated. The user can view display contents of the second display unit 2 in the direction of the hollow arrow in the slant area 8 when only the second display unit 2 is illuminated. And the user can still view the display contents of the first display unit 1 and the second display unit 2 in the direction of the hollow arrow in the slant area 8 at the same time when the first display unit 1 and the second display unit 2 are illuminated at the same time. In this way, the present utility model achieves the technical effect of displaying as much display content as possible in the limited area with lower manufacturing cost, thereby reconciling a contradiction between the diversity of the display content and the simplicity of the display interface. And in particular, the color of the displayed light is not limited by the display device according to the present utility model, which can meet the needs of visual design.

2 shows a sectional view of a display device according to a second embodiment of the present utility model. The difference to in 1 The first embodiment shown is that the second prism 4 'is designed as an isosceles trapezoidal prism.

To be in the in 2 In the embodiment shown, the first prism 3 and the second prism 4 ', which is designed as an isosceles trapezoidal prism, should be joined together to form a straight square prism, the bottom surface of which is a right-angled trapezoid, should be in the in 2 shown sectional view, ie in the bottom surface of the first prism 3 and the second prism 4 ', the hypotenuse of the isosceles right triangle coincides with one of the two legs of the isosceles trapezoid and a leg of the isosceles right triangle is collinear with an upper base of the isosceles trapezoid overall to form a right-angled trapezoid. The two base angles of the isosceles trapezoid are 45°. Here the plane in which the leg of the right-angled trapezoid lies is also referred to as the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid.

As in 2 is shown, the first display unit 1 and the second display unit 2 are each arranged vertically next to each other on the first prism 3 and the second prism 4 ', so that the light emitted by the first display unit 1 and the light emitted by the second Display unit 2 is emitted after reflection by the second layer 6 with both transmission and reflection effects are rectified. The main light path of the first display unit 1 and the main light path of the first display unit 1 are in 2 drawn schematically with dashed lines and with dash-dot lines. The light emitted by the first display unit 1 first penetrates the first layer 5 with both transmission and reflection effects and then reaches the second layer 6 with both transmission and reflection effects on the slope of a straight square prism with a bottom surface in the form of a right-angled trapezoid, where it reflects and finally towards the bottom of 2 is broadcast. However, the light emitted by the second display unit 2 is first reflected at the first layer 5 with both transmission and reflection effects, and then reaches the second layer 6 with both transmission and reflection effects on the slope of a straight square prism with a bottom surface in shape of a rectangular trapezoid, where it is reflected again, also towards the bottom of 2 is broadcast. As a result, light emitted by both the first display unit 1 and the second display unit 2 can be reflected on the second layer 6 with both transmission and reflection effects by the second prism 4 ', so that the user can view the display contents of the first display unit 1 and/or the second display unit 2 can view on the essentially transparent medium, when viewing the slanted area counter to the reflection direction present here (ie in the direction of the hollow arrow in 2 ), in which the second layer 6 is located with both transmission and reflection effects. Similar to in 1 this slope area 8 is marked with a dotted box. When looking of the bevel area 8 in the direction of the hollow arrow in 2 the user only sees a part of the transparent second prism 4' together with the second layer with both transmission and reflection effects on the slope. In the slant area 8, the display content is displayed in the substantially transparent medium and the user can at least partially see the scene behind through the slant area 8, making it possible to create an almost transparent effect.

A display surface 9 of the display device is in 2 additionally marked by a box with an oblique underline. The display surface is an area on which the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid is reflected to its adjacent side, that is, a surface formed by the projection of the oblique leg of a right-angled trapezoid, here in the bottom surface, onto its lower one base is formed. When viewing the slanted area in the direction of the hollow arrow, the user sees the display contents of the first display unit 1 and/or the second display unit 2 on this display surface 9. It should be noted in particular that preferably the first display unit 1 and the second display unit 2 are in one housing , in particular in a housing of a household appliance with a display device according to the present utility model, in order to better represent the essentially transparent appearance of the display device according to the present utility model. That is, it is possible to exclude only the aforementioned substantially transparent slope portion 8 and the display surface 9 to the outside of the housing, while hiding parts of the display device that are not transparent by the first display unit 1 and the second display unit 2 .

3 shows a sectional view of a display device according to a third embodiment of the present utility model. The difference to the in 1 and 2 The first and second embodiments shown are that the second prism 4" is designed as an isosceles right-angled triangular prism.

To be in the in 3 In the embodiment shown, the first prism 3 and the second prism 4" designed as an isosceles right-angled triangular prism to form a straight square prism, the bottom surface of which is a right-angled trapezoid, should be in the in 3 shown sectional view, ie in the bottom surface of the first prism 3 and the second prism 4 ", the hypotenuse of the isosceles right-angled triangle of the first prism coincide with a cath of the isosceles right-angled triangle of the second prism to form a total of a right-angled trapezoid. Here the plane , in which the leg of the right-angled trapezoid lies, also referred to as the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid.

4 shows an exploded view of a display device according to a first embodiment of the present utility model. 4 shows separately a first display unit 1, a second display unit 2, a first prism 3, which is designed as an isosceles right-angled triangular prism; a second prism 4, which is designed as a straight parallelepiped prism; and a first layer 5 and a second layer 6 with both transmission and reflection effects. The first prism 3 and the second prism 4 can join together to form a straight square prism with a bottom surface in the form of a right-angled trapezoid. The first layer 5 with both transmission and reflection effects is arranged between the first prism 3 and the second prism 4. As in 4 is shown, the first layer 5 with both transmission and reflection effects is arranged between the slope 33 of the first prism and the slope 44 of the second prism. The second layer 6 with both transmission and reflection effects is on the slope 55 of the assembled straight square prism with a bottom surface in the form of a right-angled trapezoid.

For example, the first layer 5 with both transmission and reflection effects and the second layer 6 with both transmission and reflection effects are a semitransmissive and semireflective layer or an electrochromic film. The semitransmissive and semireflective layer is preferably a semitransmissive and semireflective film, a semitransmissive and semireflective plating or a semitransmissive and semireflective coating. For example, the semitransmissive and semireflective film can be glued to the slope of any prism or two prisms. In particular, the semitransmissive and semireflective layer can have a transmittance between 35% and 65%, preferably between 40% and 60%, particularly preferably 50%. In addition, when using an electrochromic film, the electrochromic film can achieve the effect of total reflection, full transmission and partial transmission and partial reflection, for example at different applied voltages. Furthermore, the ratio of the transmission and reflection components can advantageously be adjusted by varying the applied voltage. It is advantageously possible through the use Application of the electrochromic film to reduce light loss and increase the brightness of the display when total reflection and total transmission are achieved. By means of the adjustable ratio of the transmission and reflection components, however, the display effects, in particular different lighting effects when the two display units are superimposed, can be represented in a diversified manner.

The first prism 3 and the second prism 4 can each be made of inorganic glass, transparent plastic, transparent ceramic, natural quartz or synthetic quartz.

Without being limited to this, it is also conceivable that the first display unit and the second display unit are formed in one piece. Here, for example, a prefabricated housing can be used, in which the first display unit and the second display unit are each mounted in recesses in the housing.

5 shows a sectional view of a display device according to a fourth embodiment of the present utility model. The difference to in 1 The first embodiment shown is that a third prism 10 designed as an isosceles right-angled triangular prism is additionally provided on the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid, so that the first prism 3, the second prism 4 and the third prism 10 are joined together to form a cuboid. In the in 5 In the section plane shown, that is, in the bottom surface of the first prism 3, the second prism 4 and the third prism 10, the hypotenuse of the isosceles right triangle of the third prism 10 should coincide with one side of the parallelogram and one leg of the isosceles right triangle of the third prism 10 be collinear with the other side of the parallelogram to form an overall rectangle. In this way, the entire display device is given a square appearance and a sharp, delicate weak edge is avoided.

Without on the in 5 To be limited to the case shown, the third prism 10 can also be used in the second and third embodiments according to 2 and 3 be provided. Therefore, in these embodiments, the first prism 3, the second prism 4 and the third prism 10 can be joined together to form a cuboid.

6 shows an exploded view of a display device according to a first embodiment of the present utility model. In 6 a possible structure of the first display unit 1 and the second display unit 2 is shown in detail. The first display unit 1 and the second display unit 2 are each designed as an illuminable icon display. The first display unit 1 and the second display unit 2 each include a circuit board 11 with integrated LED elements 14, a display film 13 with display icons 16 and a frame 12 between the circuit board 11 and the display film 13. Here, the first display unit 1 and the second display unit 2 can be implemented in a simple and cost-effective manner, that is, by illuminating the display icons 16 on the display film 13 using the LED elements 14. In the first display unit 1, the display icons 16 illuminated by the LED elements 14 can pass through the first prism 3, the first layer 5 with both transmission and reflection effects and the second prism 4 from the second layer 6 with both transmission and reflection effects are reflected from the top of the second prism 4. In the second display unit 2, the display icons 16 illuminated by the LED elements 14 can also be seen through the second prism 4 and the first layer 5 with both transmission and reflection effects and finally from the second layer 6 with both transmission and reflection effects the top of the second prism 4 are reflected.

The display icon 16 can be designed as a transparent area or hollow area that corresponds to the display content. The transparent area or hollow area may transmit light from the LED element 14 and display icons that correspond to the display content and may include, for example, text, numbers, patterns, symbols, etc. In order to sufficiently scatter the light emitted by the point light sources of the LED element 14 into flat light and to achieve a uniform lighting effect, it is also conceivable to integrate a light diffusion layer into the display film or to print a light diffusion color onto the display film 13. However, separate light diffusion films can also be used, which can be overlaid with the display film, in particular by connecting the light diffusion films to the display film, for example by gluing them.

The frame 12, as shown in 6 , comprises a plurality of, here four, cavities 15, with four LED elements 14 being accommodated in each cavity 15 in order to illuminate display icons 16, which are arranged on the display film 13 corresponding to the cavity 15. A total of 16 LED elements are arranged spaced apart on a circuit board 11, the LED elements 14 each being divided into four groups by a frame 12 and its several cavities 15, each group of LED elements contains four LED elements. A display icon 16 is arranged on the display film 13 corresponding to each cavity 15. In the case of illuminating a group of LED elements, a display icon 16 can be illuminated via the cavity 15 through a cavity 15 that runs through the frame 12 from top to bottom.

Advantageously, when displaying using the display device, the display is simultaneously carried out by only one of the first display unit 1 and the second display unit 2. That is, only one of the first display unit 1 and the second display unit 2 lights up at the same time, while the other display unit remains off. If necessary, the lighted display unit can be deleted and another display unit can light up at the next time. The first display unit 1 and the second display unit 2 can also be used to be displayed simultaneously. Here, the simultaneous display described here is broadly understood, and for example, all display icons 16 of the first display unit 1 and the second display unit 2 are illuminated so that overlapping icons are viewed. However, simultaneous display can also be understood as lighting up a part of the display icon 16 on the first display unit 1 and a part of the display icon 16 on the second display unit 2, for example lighting up a first and third display icon on the first display unit 1 and lighting up a second and fourth display icon on the second display unit 2, so that display icons from different display units are displayed on a display area.

If the display is made using the in 6 shown display device is carried out, it is also conceivable with regard to a cavity 15 in the display unit that only one or more LED elements 14 accommodated therein are illuminated accordingly. In that case the 6 For example, one, two, three or four LED elements can be illuminated, so that the brightness of the first display unit 1 and/or the second display unit 2 can be adjusted in order to provide the user with information about the brightness of the illuminated icons. It is also possible to individually illuminate the individual LED elements of a group of LED elements in a specific order, for example four in a row light mode or a breathing light mode. The LED elements 14 on the circuit board can also each have different colors and the LED elements 14 of different colors can be illuminated individually as required.

7 shows an exploded view of a second embodiment of the display device according to the present utility model. In 7 There is a digital tube display 17 on the circuit board 11 in the first display unit 1 in addition to the two groups of LED elements 14. Here the digital tube display is a three-digit, segmented LED digital tube that can display various numbers between 000 and 999. For this purpose, a larger cavity 18 is provided in the frame 12 and a digital display icon 19 in the form of 888 is correspondingly provided on the display film 13, so that the first display unit 1, in addition to the two icons, also has three digits to display digital information, such as power, temperature , running time, remaining time, etc. In the 7 The second display unit 2 shown is configured as a dot matrix display screen. The dot matrix display screen can be a TFT display screen, an OLED display screen or a dot matrix LED display screen. The user can thus be provided with a larger amount of dynamic information, in particular graphical display content, in addition to a display of icons.

In this second embodiment of the display device, only the case is shown as an example in which two types of displays are integrated in a display unit. Without being limited thereto, the illuminable icon display may be integrated with the dot matrix display screen in a display unit, or the digital tube display may be integrated with a dot matrix display screen in a display unit, or an illuminable icon display, a digital tube Display and a dot matrix display screen may be integrated in a display unit.

It is further noted that for display using the display device according to the present utility model, it is advantageous to use one of the first display unit 1 and the second display unit 2 to display a boot interface. The in. is preferred 6 or. 7 shown first display unit 1 with integrated LED element for displaying a boot interface.

8th shows a schematic representation of a human-machine interaction system according to a first embodiment of the present utility model. The human-machine interaction system not only includes the first embodiment of the display device shown above, as exemplified in 8th shown, but also an infrared operating unit 20 for detecting user operations, which is integrated in the first display unit 1 of the display device. This is in addition to the technical advantage len, the display device according to the present utility model, possible to detect an operation by a user based on the principle of infrared reflection. Likewise, the infrared radiation emitted by the infrared operating unit 20 can travel via the same beam path as the light beam emitted by the first display unit 1 through the first prism 3 and the first layer 5 with both transmission and reflection effects and the second prism 4 on the second layer 6 with both transmission and reflection effects upwards 7 be reflected. If the emitted infrared beam is reflected by the user, in particular his hand, the reflected infrared beam returns to the infrared operating unit 20 due to the reversible beam path in the human-machine interaction system or the display device, whereby the human-machine interaction system can be operated of the user can capture. Through the human-machine interaction system, the user can not only receive a brilliant visual experience and a good visual impression, but the user can also conveniently operate the human-machine interaction system or directly on and/or above the surface of the display device, so that the user can get an intuitive and convenient interaction with an optimized user experience. At the same time, the human-machine interaction system can avoid the costly arrangement of keys or buttons around the surface of the display device, thereby improving the integration of the system and providing a simple appearance of the human-machine interaction system.

The wavelength of the infrared radiation can be between 770 nm and 1 mm, in particular between 820 nm and 950 nm, preferably 850 nm or 940 nm. For this purpose, the display device, in particular its first prism 3 and second prism 4, should be designed to be infrared permeable, while the two layers with both transmission and reflection effects can also transmit and reflect infrared radiation.

The infrared operating unit 20 can be integrated into the first display unit 1 of the display device, ie it can be designed as part of the first display unit 1. In 8th the infrared control unit 20 is not shown to scale. The infrared operating unit 20 can only occupy a small space in the first display unit 1 in order to be displayed in the largest possible area, as shown in the following figures.

In the human-machine interaction system, the infrared operating unit 20 can be designed as a gesture operating unit and/or as a touch operating unit. This means that the infrared control unit 20 is designed as a gesture control unit only, a touch control unit only or as an infrared control unit with a gesture control and touch control function. Furthermore, in a human-machine interaction system, the gesture control unit and the touch control unit can be provided at the same time. The touch operation unit can detect a touch operation by a user by touching a position on the display surface 9 of the display device in a touch manner. And the gesture control unit can be a non-contact gesture made by the user in front of the display area 9 (above, as in 8th shown) is made to the display device. The gesture may include, for example, sliding, swiping, hovering, tapping, lifting, and the like.

9 shows an exploded view of a first embodiment of a human-machine interaction system according to the present utility model. This figure shows a simple exemplary embodiment of an infrared operating unit. The infrared operating unit can be integrated in the first display unit 1 or second display unit 2 of the display device, as in 6 shown. Here, the first display unit 1 comprises a circuit board 11 with integrated LED elements 14, a display film 13 with display icons 16 and a frame 12 between the circuit board 11 and the display film 13. Here, the infrared operating unit provided in the first display unit 1 comprises two infrared transmitting tubes 21, an infrared receiving tube 22, a control circuit (not shown) which can switch the two infrared transmitting tubes 21 and/or the infrared receiving tube 22 on and off alternately, and a signal processor which is one of the infrared Receiving tube 22 receives and processes the signal generated. The infrared transmitting tube 21 and the plurality of infrared receiving tubes 22 are arranged alternately along the extension direction of the display unit 1 in which the infrared operating unit is located. For an exemplary embodiment of the infrared operating unit, reference is made here, for example, to the technical content contained in the CN111487878A is disclosed to the applicant. As in 9 shown, it is preferred that an infrared operating unit is mounted on a circuit board 11 with integrated LED elements 14 of the first display unit 1. An infrared transmitting tube 21, an infrared receiving tube 22 and an infrared transmitting tube 21 are arranged in the order shown along the longitudinal side direction of the first display unit 1. For example, during operation, the control circuit sequentially switches on the two infrared transmitting tubes 21, which emit infrared radiation. In order to emit infrared radiation at least onto the display surface 9 in the display device, fer ner cavities 23 are provided for the infrared transmitting tubes 21 and for the infrared receiving tube 22. As in 9 shown, the three cavities 23 are hollow cylinders to each accommodate a corresponding infrared element. It is particularly advantageous that a light limiting structure for the infrared transmitting tubes 21 and the infrared receiving tube 22 can be formed in the frame 12, so that a light leak from the infrared transmitting tubes 21 to the infrared receiving tube 22 can be isolated by the light limiting structure and the Transmission and reception angles are limited to reduce interference with ambient light. Preferably, the height of the light limiting structure can be equal to or greater than the height of the tip of the infrared transmitting tubes 21 and the infrared receiving tube 22. Accordingly, the display film 13 is also in the area of the infrared operating unit, in particular on the infrared transmitting tubes 21 and Infrared receiving tubes 22 corresponding locations are provided with hollowed out or infrared-permeable portions 24. Furthermore, the first prism 3 and the second prism 4 in the display device are also designed to be infrared permeable, while the layer 5 with both transmission and reflection effects and the layer 6 with both transmission and reflection effects also transmit and reflect infrared radiation. Infrared radiation emitted by the infrared operating unit can therefore be reflected or transmitted at least onto the display surface 9 of the display unit and, in particular, can be emitted from the display surface 9. When a user's hand approaches, it can be reflected and received along the opposite beam path by the centrally arranged infrared receiving tube 22. The infrared transmitting tubes 21 can be infrared light-emitting diodes, and the infrared receiving tube 22 can be designed as a light-sensitive infrared diode or as a light-sensitive infrared transistor. The signal processor may process and analyze the signal generated when the infrared receiving tube receives the reflected infrared rays to detect a gesture and/or a touch of the user. The signal processor may include a signal processing circuit of the infrared receiving tube and a microprocessor unit for analyzing the signal. For example, by analyzing the timing and signal amplitude of the reflected infrared rays, it can be detected that the user's hand first appears over one of the infrared emitting tubes and then immediately appears over another of the infrared emitting tubes. Therefore, it can be determined that the user's hand was passed or swung over one infrared emitter tube onto another infrared emitter tube. The infrared control unit is in 9 preferably used as a gesture control unit, since the infrared control unit can only detect the position of the user's hand in relation to the four display icons 16 formed on the icon display to a limited extent.

10 until 14 show five arrangements for an infrared operating unit on a display unit in a human-machine interaction system according to the present invention. The display unit here can be both the first display unit 1 and the second display unit 2. Starting from the in 6 In the embodiment shown of the first display unit 1 and the second display unit 2, arrangements of the infrared operating unit on the display unit are shown here, which are viewed via display film 13 with four display icons 16. For clarification, infrared transmitting tubes 21 are designated T and infrared receiving tubes 22 are designated R in the figures.

10 shows five infrared elements arranged in the order of transmitting tube-receiving tube-transmitting tube-receiving tube-transmitting tube. The five infrared elements are each arranged at the two upper corners of the four display icons 16. In order to distinguish the operation of each display icon 16, for example, two infrared receiving tubes 22 can always be switched on and three infrared transmitting tubes 21 can be switched on 10 can be turned on one at a time and the cycle can be repeated. It is also possible to switch on the first and third infrared transmitter tubes 21 first and then switch on the second infrared transmitter tube 21 and repeat the cycle. Consequently, when the infrared receiving tubes 22 receive the reflection signal, in combination with which infrared transmitting tube 21 emits the infrared radiation, it can be determined on which display icon 16 the user's hand is present.

11 shows five infrared elements arranged in the order of receiving tube-transmitting tube-receiving tube-transmitting tube-receiving tube. The five infrared elements are each arranged at the two upper corners of the four display icons 16. For example, three infrared receiving tubes 22 can always be switched on and two infrared transmitting tubes 21 in 11 can be turned on one at a time and the cycle can be repeated. Consequently, when the infrared receiving tubes 22 receive the reflection signal, in combination with which infrared transmitting tube 21 emits the infrared radiation, it can be determined on which display icon 16 the user's hand is present.

12 shows an arrangement in which the five infrared elements are on both sides of the four Display icons 16 are arranged at half the height of a display icon. In the figure, the type of infrared element is not marked. On the one hand, the five infrared elements can be in the in 10 shown order of transmitting tube-receiving tube-transmitting tube-receiving tube-transmitting tube, and on the other hand in the in 11 shown order of receiving tube-transmitting tube-receiving tube-transmitting tube-receiving tube.

13 shows an arrangement in which the five infrared elements are each arranged at two opposite corners of each of the four display icons 16. In the figure, the type of infrared element is not marked. On the one hand, the five infrared elements can be in the in 10 shown order of transmitting tube-receiving tube-transmitting tube-receiving tube-transmitting tube, and on the other hand in the in 11 shown order of receiving tube-transmitting tube-receiving tube-transmitting tube-receiving tube.

14 shows an arrangement in which five infrared elements are each arranged along the diagonal of the rectangle covered by the four display icons 16. The type of infrared element is also not marked in the figure. On the one hand, the five infrared elements can be in the in 10 shown order of transmitting tube-receiving tube-transmitting tube-receiving tube-transmitting tube, and on the other hand in the in 11 shown order of receiving tube-transmitting tube-receiving tube-transmitting tube-receiving tube.

Like in the 10 until 14 shown, the number of display icons 16 does not have to be exactly equal to the number of pairs of infrared transmitting tubes 21 and infrared receiving tubes 22. The detection of the infrared operation is achieved as long as a pair of the infrared transmitting tubes 21 and the infrared receiving tubes 22 are arranged around each display icon 16. And the infrared transmitting tube 21 and/or infrared receiving tube 22 of the infrared transmitting tube and infrared receiving tube pair can be multiplexed onto the adjacent display icons 16. Furthermore, the connecting lines of the infrared transmitting tubes 21 to the infrared receiving tubes 22 do not need to be arranged parallel to a long side of a display unit, and the infrared transmitting tubes 21 and infrared receiving tubes 22 do not need to be arranged in a straight line. With those in the 10 until 14 In the embodiments shown, it is only necessary that the infrared transmitting tubes and infrared receiving tubes are arranged alternately in this order of an infrared transmitting tube and an infrared receiving tube.

It should be further specified that in the present utility model it is possible to control whether the infrared operating unit is designed as a gesture operating unit or as a touch operating unit by setting or adjusting the light emission intensity of the infrared transmitting tubes 21. Since infrared rays need to cause refractive loss twice at the solid-air interface in gesture operation detection, it is necessary that the infrared transmitting tubes provide a sufficiently high light emission intensity so that the infrared receiving tubes 22 receives the returned infrared rays when a large driving current for the infrared -Transmitting tubes 21 should be delivered. On the other hand, if the infrared control unit only detects a touch operation, only a lower light emission intensity is required, so that a lower drive current is required. It is also advantageous to operate the infrared transmitter tubes 21 with different currents at different times. It is particularly advantageous to record both touch operation and gesture operation of the same infrared control unit in a time division multiplex manner.

15 shows an exploded view of a human-machine interaction system according to a second embodiment of the present utility model. In addition to the in 9 First infrared operating unit shown, which is arranged in the first display unit 1, a second infrared operating unit is also arranged in the second display unit 2. For an exemplary embodiment of the second infrared operating unit, reference is made here, for example, to the technical content contained in the CN113495615A is disclosed to the applicant. The infrared operating unit here includes four infrared transmitting tubes 21, four infrared receiving tubes 22 as well as a control circuit (not shown) and a signal processor. The four infrared transmitter tubes 21 and the four infrared receiver tubes 22 can be arranged at a distance from one another along the long side of the second display unit 2, whereby the control circuit can be used to control the switching on and off of each infrared transmitter tube 21 and each infrared receiver tube 22 , and the signal processor can receive and process the signals generated by the plurality of infrared transmitter tubes 22 and in particular can determine a coordinate position of the user's hand in the direction of extension above the infrared operating unit 2. Preferably, the control circuit controls turning on and off each infrared transmitter tube 21 and each infrared receiver tube 22 in the time division multiplex manner. 15 also shows that in the frame 12 cavities 23 are provided for the infrared transmitting tubes 21 and for the infrared receiving tubes 22, which also serve as a light limiting structure for the infrared transmitting tubes 21 and for which infrared receiving tubes 22 can be designed. The display film 13 is also provided with hollowed-out or infrared-permeable partial areas 24 at the points corresponding to the infrared transmitting tubes 21 and the infrared receiving tubes 22.

In the 15 The second infrared operation unit shown can well grasp the operation of each of the display icons by the user, compared with the case of the first infrared operation unit, since there is a pair of infrared transmitter tube 21 and infrared reception tube 22 in the area of the display icon 16 is arranged. In the in 15 In the case shown, an infrared transmitter tube 21 and an infrared receiver tube 22 are arranged above the four LED elements 14, which are assigned to a display icon 16. In this way, the presence of the user's hand in the area of each display icon 16 can be accurately detected, and thus the user's operation on the display icon 16 can be detected. Although the markings in 15 in such an alternating order as an infrared transmitting tube 21 and an infrared receiving tube 22, the arrangement order of the infrared transmitting tube 21 and the infrared receiving tube 22 in each infrared transmitting-receiving group can be set arbitrarily since an infrared transmitting tube 21 and an infrared receiving tube 22, which are arranged corresponding to each display icon, are arranged close to each other.

In order for the user to operate with the in 15 To detect the infrared control unit shown, the control circuit and the signal processor can be adapted, for example, in the following several ways. The control circuit can simultaneously turn on all infrared receiving tubes 22 and turn on each infrared transmitting tube 21 one after the other; alternatively, one or more infrared transmitting and receiving groups are switched on one after the other, each infrared transmitting and receiving group having an infrared transmitting tube 21 and an infrared receiving tube 22 adjacent thereto; alternatively, several non-adjacent infrared transmitting and receiving groups are switched on with a time delay, each infrared transmitting and receiving group comprising an infrared transmitting tube 21 and an adjacent infrared receiving tube 22. In the latter two cases, an infrared transmitting tube 21 and an infrared receiving tube 22, which are arranged corresponding to a display icon 16, are designed as an infrared transmitting and receiving group for temporally and spatially resolved detection. On the one hand, the first, second, third and fourth infrared transmitting and receiving groups can be activated one after the other in the infrared operating unit 15 be turned on and the cycle repeats itself in this way. On the other hand, in the infrared control unit, first the first and third infrared transmitting and receiving groups and then the second and fourth infrared transmitting and receiving groups can be switched on at a different time, and the cycle repeats itself in this way.

In this case, an infrared operating unit provided in the first display unit 1 is advantageously used as a gesture operating unit and an infrared operating unit provided in the second display unit 2 is used as a touch operating unit. Thus, it is possible to accurately detect both a touch operation of the user's hand by touching the display area 9 on each of the display icons 16 and a gesture operation of the user's hand in front of (i.e. above) the display area 9, such as a leftward movement. Swipe, a right swipe, a hover, and the like. Such a human-machine interaction system can provide the user with extensive operating options in addition to the brilliant visual experience and good optical impression that the display device according to the present utility model provides.

16 shows a sectional view of a human-machine interaction system according to a second embodiment of the present utility model. This figure shows the installation of a human-machine interaction system in a household appliance. The first display unit 1 and the second display unit 2 are accommodated in an interior of a housing 25 of the household appliance. In this way, the user only sees the essentially transparent part of the display device which protrudes beyond the housing 25 of the household appliance on the outside of the household appliance, and the display contents appear in the essentially transparent medium and the user can look through the hollow arrow in the observation direction You can at least partially see the scene behind it through the sloping area, which can create almost perspective effects. From the user's perspective, the human-machine interaction system or the display unit is, as it were, attached to a surface of the household appliance, so that the appearance of the household appliance is newly developed and an impression of intelligent and modern products is offered.

Like from the 16 It can also be seen that the first infrared operating unit arranged on the top of the first display unit 1 and the second infrared operating unit arranged on the inside of the second display unit 2 do not interfere with each other with regard to the beam path of the infrared radiation and the beam path of the reflection. Thus, the first infrared control unit and the The second infrared control unit can be operated simultaneously without influencing each other.

Not only the LED elements 14, but also infrared transmitting tubes 21 and infrared receiving tubes 22 are arranged on the circuit board 11 in the first display unit 1 and in the second display unit 2. Accordingly, 12 cavities 15 for the LED elements 14 and cavities 23 are provided in the frame for the infrared transmitting tube 21 and for the infrared receiving tube 22, respectively. The cavities are each provided as hollow areas with funnels. However, without being limited to this, the cavities may have a uniform cross section. Furthermore, the cavities 23 for the infrared transmitting tubes 21 and for the infrared receiving tubes 22 are designed as a light limiting structure. It can also advantageously be provided that a cross section of the infrared transmitting tube 21 and/or the infrared receiving tube 22 occupies 40% to 90% of the cross section of the cavities 23. Preferably, the height of the cavities 23 projects beyond the tip of the infrared transmitting tube 21 and/or the infrared receiving tube 22 to enable limitation of the emission/reception angle thereof, thereby making the infrared transmitting tubes 21 and the infrared receiving tubes 22 more cost-effective but with larger transmission and reception angles can be used.

16 also shows the infrared radiation emitted by the infrared transmitting tubes 21 and the infrared radiation received by the infrared receiving tubes 22. The beam path of the infrared light emitted by the infrared transmitter tubes 21 is shown in straight lines with small continuous arrows. Upon a touch operation or gesture operation by the user, the infrared radiation reflected by the user's hand returns to the adjacent infrared receiving tubes 22 along the opposite optical path, as shown by the small hollow arrow line in Fig. 16.

17 shows a household appliance to which a display device or a human-machine interaction system according to the present utility model is attached. An example of an air conditioning system 26 is shown, which is designed as a room air conditioning unit. A display device or a human-machine interaction system according to the present utility model may be partially installed in an air conditioner 26 through an opening under the air conditioner 26 so that the first display unit 1 and the second display unit 2 of the display device are accommodated in an interior of a housing of the air conditioner 26 are, while only part of a second prism 4 of the display device protrudes from the housing. In other words, only the slope area 8 of the display device is exposed outside the housing of the air conditioning system 26. As a result, when viewing the slope area 8 from the front of the air conditioning system 26, the user only sees a part of the transparent second prism 4 together with the second layer 6 with both transmission and reflection effects on the slope. The display content is displayed in the substantially transparent medium and the user can at least partially see the scene behind it through the bevel area 8, making it possible to create an almost transparent effect. The display device or the human-machine interaction system according to the present utility model is, as it were, attached to a lower surface of the air conditioner 26 from the user's perspective, so that the appearance of the household appliance is newly pronounced and an impression of intelligent and modern products is offered.

In 17 It is also shown that the display contents of the first display unit 1 and/or the second display unit 2 are visible on the display surface 9. As an example, a snowflake pattern signaling cooling is shown here on the display surface 9 with a number “25” signaling the temperature setting. These display contents can each be displayed by an illuminable icon display or digital tube display arranged in the same display unit or in different display units. Without being limited to this, the use of a dot matrix display screen is also conceivable.

When installing the human-machine interaction system on the air conditioning system 26, additional user operations, for example touch operations on the surface of the display area 9 and/or gesture operations in front of the display area 9, can be recorded with the help of the infrared operating unit located therein, so that the user receives intuitive and convenient interaction to optimize the user experience. At the same time, a complex provision of keys or buttons around the surface of the display device can also be avoided. Preferably, the human-machine interaction system can further issue control commands and/or change the display of the display device depending on user operation detected by the infrared operating unit.

The present utility model is not limited to the illustrated embodiments, but includes or extends to all technical equivalents which may fall within the scope of the appended claims. The location information chosen in the description, such as “top”, “bottom”, “left”, “right etc.” is also on the directly described and shown figure and can be transferred accordingly to the new position if the position changes.

The features disclosed in the application documents can be important and implemented not only individually, but also in any combination for the realization of an exemplary embodiment in their various configurations.

Although the present utility model has been disclosed above using the preferred embodiments, these embodiments are not intended to limit the present utility model. Possible changes and modifications to the technical solutions of the present utility model can be carried out by those skilled in the art using the technical content described above, without departing from the spirit and scope of the present utility model. Therefore, all simple modifications, equivalents and modifications made to the above-described embodiments in accordance with the technical substance of the present utility model are within the scope of the present utility model without departing from the technical teachings of the present utility model.

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

• CN 111487878 A [0030, 0071]
• CN 113495615 A [0030, 0080]

Claims (21)

Display device, characterized in that the display device comprises: a first display unit (1); a second display unit (2); a first prism (3), which is designed as an isosceles right-angled triangular prism; a second prism (4), which is designed as a straight parallelepiped prism, an isosceles trapezoidal prism or an isosceles right-angled triangular prism; and two layers with both transmission and reflection effects, the first prism (3) and the second prism (4) being joined together to form a straight square prism with a bottom surface in the form of a right-angled trapezoid, a first layer (5) with both transmissions - as well as reflection effect is arranged between the first prism (3) and the second prism (4) and a second layer (6) with both transmission and reflection effect is arranged on a slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid , and the first display unit (1) and the second display unit (2) are each arranged vertically next to one another on the first prism (3) and the second prism (4), so that the light emitted by the first display unit (1), and the light emitted from the second display unit (2) is rectified after being reflected by the second layer (6) with both transmission and reflection effects. display device Claim 1 , characterized in that the first display unit (1) and the second display unit (2) each comprise one or more of an illuminable icon display, a digital tube display and a dot matrix display screen. display device Claim 2 , characterized in that the illuminable icon display has a circuit board (11) with integrated LED elements (14), a display film (13) with display icons (16) and a frame (12) between the circuit board (11) and the Display film (13) includes. display device Claim 3 , characterized in that the frame (12) comprises a plurality of cavities (15), at least one of the LED elements (14) being accommodated in each cavity (15) in order to illuminate display icons (16) which appear on the display film (13) are arranged according to the cavities. display device Claim 2 , characterized in that the digital tube display is a segmented LED digital tube, and/or the dot matrix display screen is a TFT display screen, an OLED display screen or a dot matrix LED display screen. Display device according to one of the Claims 1 until 5 , characterized in that an area on which the slope of the straight square prism with a bottom surface of a right-angled trapezoid reflects to its adjacent side serves as a display surface. Display device according to one of the Claims 1 until 5 , characterized in that a third prism (10) designed as an isosceles right-angled triangular prism is additionally provided on the slope of the straight square prism with a bottom surface in the form of a right-angled trapezoid, so that the first prism (3), the second prism (4) and the third prism (10) is assembled into a cuboid. Display device according to one of the Claims 1 until 5 , characterized in that the first layer (5) with both transmission and reflection effects and the second layer (6) with both transmission and reflection effects are a semi-transmissive and semi-reflective layer or an electrochromic film. display device Claim 8 , characterized in that the semitransmissive and semireflective layer is a semitransmissive and semireflective film, a semitransmissive and semireflective plating or a semitransmissive and semireflective coating. display device Claim 9 , characterized in that the semitransmissive and semireflective layer has a transmittance between 35% and 65%. display device Claim 10 , characterized in that the semitransmissive and semireflective layer has a transmittance between 40% and 60%. display device Claim 11 , characterized in that the semitransmissive and semireflective layer has a transmittance of 50%. Display device according to one of the Claims 1 until 5 , characterized in that the first display unit (1) and the second display unit (2) are formed in one piece and / or the first prism (3) and the second prism (4) are each made of inorganic glass, transparent plastic, transparent ceramic, natural quartz or synthetic quartz. Display device according to one of the Claims 1 until 5 , characterized in that one or both of the first display unit (1) and the second display unit (2) is/are displayed at a time. Human-machine interaction system, characterized in that the human-machine interaction system has a display device according to one of the Claims 1 until 14 and at least one infrared operating unit (20) for detecting an operation by a user, wherein the at least one infrared operating unit (20) is arranged in a first display unit (1) and/or in a second display unit (2) of the display device. Human-machine interaction system Claim 15 , characterized in that at least one infrared operating unit (20) is designed as a gesture operating unit and/or as a touch operating unit. Human-machine interaction system Claim 16 , characterized in that each infrared operating unit has two infrared transmitting tubes (21), at least one infrared receiving tube (22), a control circuit which alternately activates the two infrared transmitting tubes (21) and/or the infrared receiving tube (22). - and switches off, and a signal processor that receives and processes a signal generated by the infrared receiving tube (22). Human-machine interaction system Claim 17 , characterized in that the infrared transmitting tubes (21) and a plurality of infrared receiving tubes (22) are arranged alternately along the direction of extension of the display unit in which the infrared operating unit is located. Human-machine interaction system according to one of the Claims 15 until 18 , characterized in that depending on a user operation detected by the infrared operating unit, the human-machine interaction system issues control commands and / or changes the display of the display device. Household appliance, characterized in that the household appliance has a display device according to one of the Claims 1 until 13 or a human-machine interaction system according to one of the Claims 15 until 19 comprises, wherein the first display unit (1) and the second display unit (2) of the display device are accommodated in an interior of a housing of the household appliance. household appliance Claim 20 , characterized in that the household appliance is an air conditioner, an extractor hood, a hob, a refrigerator, an oven, a dishwasher, a food processor, a washing machine, a dryer, an audio device, a television, a smart faucet or a smart toilet.

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