EP0692107B1 - Process and device for recognizing the position of indicator elements - Google Patents

Abstract

A process and device are disclosed for directly recognizing the position of analogical indicator elements of a clock, in particular the pointers (4a, 4b) of a radio clock. The optical signal (9) emitted by an optical transmission element (1) is reflected and/or refracted by functional areas (41, 42) of the pointers (4a, 4b) in such a way that the signals are received by an optical reception element (2) only when the pointers (4a, 4b) are in a defined position.

Description

The invention relates to a method and a device for position detection of analog display elements of a clock using opto-electronic components.

Areas of application of the invention are, for example, the analog time display, in particular by means of a radio clock.

It is known to carry out the position detection of analog display elements in an indirect way. The position of the gears in the drive mechanism of the display elements is monitored by means of a light barrier. A signal is triggered via additionally arranged detection wheels at defined positions of these wheels via passage or reflection light barriers. Such a device is described in EP 0 082 821 A1. Disadvantages of this solution are the additional expenditure on gear technology, the additional assembly, adjustment and testing expenditure and the relatively high space requirement for the additional detection wheels.

EP 0 180 880 B1 describes a detection device for the position of the hands of an analog clock, in which the position of the hands is also queried via a light barrier inside the existing gear train, but without the need for additional gear parts. The circuit board for the light barrier takes on both a mechanical and an electronic function in that it serves on the one hand as an axial movement limitation of the wheels and on the other hand accommodates the light barrier circuit and the radio clock circuit. The disadvantage of this solution is that it can only be used with a clockwork specially developed for the purpose of pointer position detection.

The production of this type of clockwork is much more complex and expensive than the assembly of conventional quartz clockworks. Furthermore, when assembling the watch, especially when putting on the hands, the current position of the gears is important in order to achieve a clear association between the position of the hands and the gear. This also requires a significantly increased production and testing effort when assembling the watch.

Detection devices with reflection light barriers are also known, in which the shadowing of the optoelectronic system by the display elements leads to the triggering of the signal. The disadvantage of these solutions is that an accurate and reproducible signal triggering is very difficult to achieve and different dimensions of the display elements lead to different signal triggering times.

Furthermore, an arrangement is known from GB-A-2 197 968 in which light is emitted by means of an optical transmitter, which light is reflected from the respective rear side of the individual pointers. At least one pointer has a light-reflecting part.

The invention has for its object to provide a method for detecting the position of the hands of a watch and to provide a device which, when using conventional watch movements, allows the position to be precisely and inexpensively recognized using simple means.

This object is achieved by the method specified in claim 1. A device for solving the problem is specified in claim 3. Advantageous embodiments of the method and the device are characterized in the subclaims.

An important advantage of the invention is that the position detection of the analog display elements is carried out directly by the display elements, in that the display elements themselves or their functional areas interact with an optical transmission element and an optical reception element Trigger signal. The active signal triggering results from the fact that the impact of the optical signal on the optical receiving element causes the signal triggering.

In the system according to GB-A-2 197 968, a representative signal triggering is difficult to achieve because the evaluation of the speed of the pointers in a certain passage area inevitably leads to a less precise signal than is possible with a system according to the invention.

Here there is a reflection and / or refraction of the optical signals emitted by the optical transmitter element on the display elements such that the multiply reflected or refracted optical signals are received by the optical receiver element only when all display elements are in a defined position. For this purpose, the display elements have functional areas which serve for reflection and / or refraction of the signal. The functional areas can be designed as reflection surfaces inclined to the beam path or perpendicular reflection surfaces or also as a transparent, prismatic component of the display element. Furthermore, the functional areas can be flat or inclined light entry or exit surfaces of light guides. The optical transmission elements and the optical reception elements can be arranged on or in the housing which surrounds the display elements. If the optical transmitting and receiving elements are arranged on a housing, it is possible to arrange them, side by side as well as one behind the other, as seen in the direction of viewing the scale. If the optical transmitting and receiving elements are arranged within the housing, they can be arranged behind the scale, the scale having transparent areas or openings for the passage of the optical signals.

The optical transmission and reception elements preferably operate in the radiation spectrum beyond visible light, it being possible for the optical transmission elements to be embodied as infrared luminescence diodes and the optical reception elements as infrared photodiodes or infrared phototransistors.

Another advantage of the invention is that the course of the beam path between the transmitting and receiving elements largely eliminates the effects of stray light, which can lead to falsification of the position detection. According to the invention, an additional measure for this is to provide the optical receiving element with a narrow-band optical filter which transmits only the wavelength of the optical transmitting element. In addition, a material can be used to cover the scale, which is transparent in the visible wave range, but opaque in the wavelength range of the optical receiving element.

In order to counteract reflections on the cover of the scale, the cover can have a suitable geometry and / or be processed appropriately. The geometrical arrangement of the optical transmission and reception elements in relation to the display elements, the spacing of the display elements from one another and from other components, the boards of the display elements etc. are also important for optimizing the position detection and avoiding the influence of scatter.

With the application of the invention to a radio clock, it is possible to use at least the mechanical part of a conventional quartz clockwork in unchanged form. The position of the gearwheels when mounting the pointers is irrelevant for the correct function of the position detection.

Fig.1

eine Vorderansicht einer Funkuhr mit Detaildarstellung der nebeneinander angeordneten Sende- und Empfangselemente,

Fig.2

eine schematische Seitenansicht zu Fig.1 mit Detaildarstellung der Reflexionsflächen,

Fig.3

eine Vorderansicht einer Detaildarstellung einer Variante einer Funkuhr mit hintereinander angeordneten Sende- und Empfangselementen,

Fig.4

eine Detailseitenansicht zu Fig.3 mit Darstellung der Reflexionsflächen,

Fig.5

eine Detailseitenansicht einer Funkuhr mit Anordnung der Sende- und Empfangselemente hinter dem Zifferblatt und

Fig.6

eine Seitenansicht einer Funkuhr gemäß Figur 3 mit einer Positionserkennung unter Verwendung von Lichtleitern als Zeiger.

The invention is described in more detail below with reference to exemplary embodiments which are shown in the drawing. Show it:

Fig. 1

1 shows a front view of a radio clock with a detailed representation of the transmitting and receiving elements arranged next to one another,

Fig. 2

1 shows a schematic side view of FIG. 1 with a detailed representation of the reflection surfaces,

Fig. 3

2 shows a front view of a detailed representation of a variant of a radio clock with transmission and reception elements arranged one behind the other,

Fig. 4

3 shows a detailed side view of FIG. 3 with representation of the reflection surfaces,

Fig. 5

a detailed side view of a radio clock with the arrangement of the transmitting and receiving elements behind the dial and

Fig. 6

a side view of a radio clock according to Figure 3 with position detection using optical fibers as a pointer.

In order to be able to automatically set the time for an analog clock, it is necessary for the electronics of the clock to recognize the position of the hands in a certain position. In the following exemplary embodiments, this position is the 12 o'clock position of the hour and minute hands on a radio clock.

According to FIG. 1, an optical transmitting element 1 is arranged next to an optical receiving element 2 on a housing 3 of a radio clock above the dial 5. Openings 6, 7 in the housing 3 form passages for an optical signal 9. The opening 6 to the receiving element 2 is toothed to shield stray light. The transmitting element 1 is an infrared luminescent diode, the receiving element 2 is an infrared phototransistor.

In the illustrated exactly 12:00 o'clock position of the hands 4a and 4b, the optical signal 9 emitted by the transmitting element 1, as can be seen in FIGS. 1 and 2, strikes the inclined reflection surface 41 of the pointer at an angle of approximately 45 ° 4a, is reflected from there at an angle of approximately 90 ° and strikes the reflection surface 42 of the pointer 4b perpendicularly. From here, the optical signal 9 is reflected back onto the inclined reflection surface 41 of the pointer 4a and, after being reflected again, hits the receiving element 2 at the reflection surface 41 and triggers a further processable electrical signal there.

Due to the fact that the optical signal 9 in the 12 o'clock position of the hands 4a and 4b forms an angle with their direction due to the spatial attachment of the transmission element 1, the optical signal 9 coincides with the reflection surface 41 after its reflection at a different angle from 90 ° onto the second reflection surface 42 of the pointer 4b and is also thrown back again at the same angle from the reflection surface 42 onto the inclined reflection surface 41. In this way, the displacement of the optical signal 9 along the inclined reflection surface 41, denoted by reference symbol v in FIG. 1, occurs. The extent of the displacement depends on the angle between the pointer direction and the optical signal 9, the arrangement of the transmitting element 1 and the receiving element 2 is symmetrical with respect to the direction of the hands at 12 o'clock.

If one of the two pointers 4a or 4b is not exactly in the pointer position to be detected, the optical signal 9 does not reach the receiving element 2.

In order to suppress the effects of scattered light, the geometry of the beam path is due to the spatial arrangement of the transmitting element 1, the receiving element 2, the pointers 4a and 4b and the diameter of the openings 6, 7 optimized for the light entry of the transmitting element 1 and the light exit of the receiving element 2. The position of the reflection surface 41 on the back of the pointer 4b also advantageously contributes to this, since it is shielded against direct incidence of light. In addition, a narrow-band optical filter, not shown, can be arranged in front of the optical receiving element 2 and transmits only the wavelength of the optical transmitting element 1. The dial 5 is covered by a transparent cover plate 8, which is transparent in the visible wave range of the light, but is opaque in the wave range of the optical receiving element 2. In addition, the cover plate 8 is suitably machined, at least partially, to avoid interference signals due to unwanted reflections.

FIGS. 3 and 4 show an exemplary embodiment of the invention, in which the optical transmission element 1 is arranged behind the optical reception element 2 in the direction of view of the dial 5. In the exact 12:00 o'clock position of the hands 4a and 4b, the beam path of the optical signal 9 runs from the transmission element 1 to the inclined reflection surface 41 of the pointer 4a, from there it is at an angle of 90 ° to the diametrically inclined reflection surface 43 of the Pointer 4b reflects and is reflected there again at an angle of 90 ° to the receiving element 2. Since the hand 4b as a minute hand must be longer than the hand 4a as an hour hand, the reflection surface 43 of the hand 4b is followed by an area 4c with a reduced cross section.

In contrast to the first exemplary embodiment, there is no displacement of the optical signal 9 along the inclined reflection surface 41, since the optical signal 9 in the 12 o'clock position of the hands 4a and 4b corresponds to their direction.

FIG. 5 shows an exemplary embodiment in which the optical transmission element 1 and the optical reception element 2 are arranged next to one another behind the dial 5, the optical reception element 2 lying closely behind the optical transmission element 1 according to FIG. An opening 10 is provided in the dial for the beam passage of the optical signal 9. The beam path runs in the exact 12:00 o'clock position from the transmission element 1 to the functional area 44 of the pointer 4a. This functional area 44 is designed as a transparent prism and is inclined on the side facing away from the transmitting element 1 and the receiving element 2. As a result, the optical signal 9 emanating from the optical transmission element 1 is refracted in the functional area 44 and directed onto an inclined reflection surface 45 of the pointer 4b, from where the optical signal 9 reflects back to the functional area 44, and directed to the optical receiving element 2 by refraction again becomes.

By means of a corresponding inclination of the reflection surface 45 also with respect to the plane of the drawing, it can be achieved that the optical signal 9 is reflected backwards, not in itself but in relation to the plane of the drawing, so that it is reflected on the receiving element located behind the transmitting element 1 2 hits.

FIG. 6 shows an exemplary embodiment in which the pointers 4a, 4b are designed as light guides, the optical receiving element 2 being arranged behind the optical transmitting element 1 in the viewing direction of the dial 5. In the exactly 12 o'clock position of the pointers 4a and 4b, the optical signal 9 emanating from the optical transmission element 1 arrives at a light entry surface 46 perpendicular to the beam path and from there is guided in the pointer 4b to an inclined reflection surface 47 which transmits the signal reflected at an angle of 90 ° to a light exit surface 48 of the pointer 4b. The optical passes from the light exit surface 48 Signal to a light entry surface 49 of the pointer 4a and is directed from there after reflection at an angle of 90 ° on a reflection surface 50 in the longitudinal direction of the pointer 4a designed as a light guide. The optical signal 9 exits at a flat light exit surface 51 perpendicular to the beam path and reaches the optical receiving element 2. This light path is only open if both pointers 4a and 4b are in the correct pointer position. Instead of designing the pointers 4a and 4b as light guides, it is also possible to provide conventional pointers with light guides.

The invention is not restricted to the exemplary embodiments described here; rather, further variants of the beam path are possible, even when using more than two hands in a clock.

Claims (15)

1. A process for detecting the position of analog indicator elements of a clock, utilizing optoelectronic components,
   characterized in that the optical signal (9) emitted by at least one optical transmit element (1) is reflected and/or refracted by the indicator elements (4a, 4b) such that said optical signal (9) is received by at least one optical receive element (2) only if all of the indicator elements (4a, 4b) occupy a defined position, whereby an electronic signal suitable for further processing is released.
2. The process as claimed in claim 1,
   characterized in that an optical signal (9) is emitted by an optical transmit element (1), that said optical signal (9) impinges on the functional area (41, 44, 47) of a first indicator element (4a) when it reaches a defined position, where said signal is reflected and/or refracted, that said optical signal (9), after being reflected and/or refracted a first time, impinges on the functional area (42, 43, 45, 50) of a second indicator element (4b) when it reaches a defined position, where it is again reflected and/or refracted, and that said twice reflected and/or refracted optical signal (9) impinges on an optical receive element (2), actively effecting a signal release, such impingement occurring either directly or by means of a back-reflection and/or back-refraction by the functional area (41, 44) of the first indicator element (4a) or another reflection and/or refraction by the functional areas of further indicator elements only during the period of time when all of the indicator elements occupy their respective defined positions.
3. A device for detecting the position of analog indicator elements of a clock, utilizing optoelectronic components,
   characterized in that at least one optical transmit element (1) and at least one optical receive element (2) are spatially arranged such that only at a defined position of the indicator elements (4a, 4b) does the beam path of an optical signal (9) extend from the transmit element (1) through functional areas (41 to 45, 47, 50) of the indicator elements (4a, 4b) to the receive element (2).
4. The device as claimed in claim 3,
   characterized in that the optical transmit element (1) and the optical receive element (2) are provided in side-by-side arrangement or in succession, when viewed in the direction of the dial, on the periphery of a dial (5) adjacent to the indicator elements (4a, 4b).
5. The device as claimed in claim 3,
   characterized in that the optical transmit element (1) and the optical receive element (2) are arranged on the side of the dial (5) facing away from the indicator elements (4a, 4b), and that the dial (5) is transparent in the area of the transmit element (1) and the receive element (2) for passage of the optical signal.
6. The device as claimed in claim 3,
   characterized in that the functional area of the indicator element (4a) is a reflecting surface (41) inclined relative to the beam path, and the functional area of the indicator element (4b) is a reflecting surface (42) normal to the beam path.
7. The device as claimed in claim 3,
   characterized in that the functional areas of the indicator elements (4a, 4b) are diametrically inclined reflecting surfaces (41, 43).
8. The device as claimed in claim 3,
   characterized in that an indicator element (4a) adjacent to the transmit and receive element has its functional area (44) configured as a transparent prism, and that the functional area of the other indicator element (4b) includes a sloping reflecting surface (45) normal to the beam path on the side close to the optical transmit element (1) and the optical receive element (2).
9. The device as claimed in claim 3,
   characterized in that the indicator elements (4a, 4b) are configured as optical waveguides, or are provided with optical waveguides.
10. The device as claimed in claim 9,
    characterized in that the ends of the indicator elements (4a, 4b) lying opposite the transmit element (1) and the receive element (2) in their respective defined positions include light entrance surfaces (46, 49) normal to the beam path, and that the opposite ends of the indicator elements (4a, 4b) have light exit surfaces (48, 51) facing each other.
11. The device as claimed in claim 10,
    characterized in that the ends of the indicator elements (4a, 4b) remote from the light entrance surfaces (46, 49) have reflecting surfaces (47, 50) inclined relative to the longitudinal axis of the indicator elements (4a, 4b).
12. The device as claimed in claim 3,
    characterized in that the optical receive element (2) has associated to it a narrow-band optical filter transmitting only the wavelength of the optical transmit element (1).
13. The device as claimed in claim 4,
    characterized in that the dial (5) and the indicator elements (4a, 4b) are covered by a cover plate (8) that is transparent in the visible waveband, is opaque in the waveband of the optical transmit element (1), and is configured such as to avoid reflection and thus the occurrence of interference signals.
14. The device as claimed in claim 3,
    characterized in that the optical transmit elements (1) are infrared luminescent diodes, and the optical receive elements (2) are infrared photodiodes or infrared phototransistors.
15. The device as claimed in any one of the claims 3 to 14,
    characterized in that the indicator elements (4a, 4b) are the hands of a radio-calibrated clock.

Images