EP0424772A2 - Remotely synchronizable time display - Google Patents

Abstract

A remotely synchronisable time display (25), especially configured as a time switch having an interrupter (31) for controlling a load (33), is intended to be designed for the purpose of also being operated at locations under the corrective supervision of absolute time information (13), where the long wave carrier frequency (f) of a public time-signal transmitter cannot be received without problems, such as, for example, in the basement machinery room of a building (11). For this purpose, the time display (25), which is autonomous per se, operated from a time-holding circuit (27) and can be corrected if required periodically via a comparator (23) in accordance with the current absolute time information (13), is equipped with a display receiver (20) for the carrier-frequency converted transmission of the absolute time information (13), this being performed via a local transmission section (17) in the form of the AC in-house network (32) and/or of a short wave channel. This local transmission section (17) is fed in, or in the vicinity of, the building(s) (11) from a converter/receiver (14), positioned favourably in terms of reception, for the long wave carrier frequency (f) of the absolute information (13), which is received from a public time-signal transmitter, the local transmission section (17) being fed with a local transmission frequency (F) increased by a frequency converter (16). …<IMAGE>…

Description

The invention relates to a time display according to the preamble of claim 1.

Such a time display is known from US Pat. No. 3,881,310 as a clock which can be synchronized wirelessly by means of a low-frequency AC network, in particular the house power supply network, in which the AC frequency is increased and transmitted as an AC field to a receiver which transmits a corresponding pulse sequence for advancing the Time display delivers. If this advance pulse train fails or deviates too much from a specified nominal pulse repetition frequency, the display advance is switched over to an internal pulse generator. However, the size of the false indication that has occurred due to the incorrect switching frequency of the wirelessly transmitted pulses cannot be determined or corrected.

A momentary mistake in the time display (for example, due to equipment malfunctions or due to a recent summer / winter time change) can only be determined and corrected in comparison to an absolute time information, such as that from the long-wave transmitter DCF 77 as coded information about the current hour and Minute is delivered in the current date, with a Second information can be derived from the periodicity of the carrier frequency amplitude modulation for binary coding of the absolute time information; as described in more detail, for example, in US Pat. No. 4,650,344 for a so-called autonomous radio clock. There the problem has also been dealt with, which stems from the fact that at the installation site of such a radio clock there are not necessarily sufficient long-wave reception possibilities. This is particularly the case if the radio-correctable time display is to be operated in internal or low-lying installation rooms of reinforced concrete buildings, such as in the case of the configuration preferably considered here as a time switch, which can be used for tariff-dependent load control or in one in the area of house feed-in and energy distribution, for example Boiler room for hot water supply depending on the time of day. This can be an electromechanical or an electronic timer, cf. such as the representation in DE-PS 35 41 651 or in FUNKSCHAU 2/1982, page 112.

In recognition of these circumstances, the invention is based on the object of designing a time display (which is to be understood in the context of the present description in terms of apparatus, that is to say not as a form of representation) of a generic type in such a way that it also operates at a location which is unfavorable for the reception of time transmitters and thereby nevertheless can be checked periodically, for example, in accordance with the absolute time information that can be transmitted by radio and corrected if necessary.

This object is essentially achieved in that the generic time display is designed according to the characterizing part of claim 1.

According to this solution, an evaluation circuit equipped with the time display, and possibly a load circuit switching path that can be controlled therefrom, does not immediately receive the absolute time information, which is usually long-wave amplitude-modulated very distant time transmitter; Instead, their display receiver is fed with frequency-converted absolute time information via a local transmission link, which is transmitted to the display receiver by a local converter receiver with frequency converter via the home network or via a short-wave radio link. It is therefore only necessary to arrange a converter receiver with a long-wave antenna in a position suitable for radio communication, for example under the roof of a building, in order to send the carrier frequency-converted absolute time information from there, preferably via the building's energy supply network to transmit any evaluation points - even in rooms that are inaccessible by radio technology. In this case, a coordinated coupling stage between the house network and the conversion receiver or between the house network and the display receivers can be designed such that it can be integrated directly into the network connection for operating the conversion receiver or for operating the time switches. If, on the other hand, the absolute time information is transmitted via a short-wave channel, evaluation circuits equipped with corresponding antennas can also be supplied with the absolute time information outside the building, where its energy supply network is not available.

• Fig. 1 in symbolischer Darstellung eine Haus-Verteilung einer absoluten Zeitinformation aus einem zentralen Umsetzer-Emp­fänger und
• Fig. 2 im vereinfachten Blockschaltbild das Zusammenwirken des universellen zentralen Umsetzer-Empfängers mit unterschied­lichen Auswertestationen.

Additional alternatives and further developments as well as further features and advantages of the invention result from the further claims and, also taking into account the explanations in the summary, from the following description of two preferred implementation examples for the solution according to the invention, which are sketched in a highly abstracted manner and restricted to the essentials. It shows:

• Fig. 1 in a symbolic representation of a house distribution of an absolute time information from a central converter receiver and
• Fig. 2 in the simplified block diagram the interaction of the universal central converter receiver with different evaluation stations.

The clock system sketched in the drawing has a converter 12 for an absolute coded time information 13 installed in a building 11 at a location with good radio reception conditions, for example under the roof structure. In it, a receiver 14 that is permanently tuned to a time transmitter is equipped with a (for example a ferrite) long-wave antenna 15, which preferably has an approximate all-round reception characteristic, in order not to have to align it separately according to the relative transmitter location; as described in more detail in EP-OS 242 717. However, this converter receiver 14 is now constantly receiving, or at least periodically over substantially longer periods of time than the display receiver 20 supplied by it (cf. below).

At least one frequency converter 16 is connected downstream of the converter receiver 14, possibly via amplifiers, in order to convert the received coded time information 13 into a different and preferably higher frequency range for the local transmission; in order to avoid interference, the local transmission frequency F is not an integral multiple of the carrier frequency f of the time transmitter. Depending on the selected transmission frequency F, the local transmission link 17 is preferably the power supply network 17.1 already present in the building 11; or instead or in parallel to this, a frequency converter 16 is provided for feeding a local transmission antenna 18, so that the transmission link 17 is a radio link 17.2 in a frequency band released for such local services below the FM radio frequencies.

The transmission link 17 thus carries - on a higher-frequency carrier - the same amplitude-modulated time information 13 as is received via the long-wave antenna 15. This carrier-frequency-converted time information 13 is received in evaluation stations 19 by a display receiver 20 for controlling an evaluation circuit 21, which is fixed to the transmission carrier frequency of 120 kHz or 40.7 MHz, for example, in accordance with the selected transmission path 17.

In this a demodulator 22 supplies the currently received time information 13 to a comparator 23 which, on the other hand, is fed with the current display information 24 in accordance with the current position of the time display 25 (such as pointers in front of the minute line of a dial). If the time display 25 has a mistake in relation to the radio-received absolute time information, the time display 25 is switched on via a gate 26 until the display information 24 matches the current absolute time information 13 and the comparator 23 or the receiver demodulator 20-22 again is deactivated until the next circuit-specific check point in time; as further described in U.S. Patent No. 4,645,357. The time-keeping operation of the time display 25 takes place from a time-keeping circuit 27, preferably a quartz-stabilized oscillating circuit, which supplies step-up pulses 28 to a switching mechanism 29. In the case of an electromechanical time display 25 (for example with drop flaps, number rollers or revolving pointers), this is a stepping mechanism or a synchronous motor, whereas in the case of an optronic time display 25 it is a display segment control.

The evaluation circuit 21 with time display 25 can simply be a (display) clock, as illustrated in FIG. 1 by the clock symbol on the first floor on the right and on the first floor on the left. However, it is preferably a switching clock, the switching times of which can be preselected in a manner known per se via a manual control input 30. If the current position of the time display 25 corresponds to a preselected point in time, a switching path 31, for example a heavy current contactor, is opened or closed for the operation of a load 33 fed from the network 32.

Like the central local converter 12, the Evaluation stations 19 operated from the network 32, which serves as a local transmission link 17 for the carrier-implemented time information 13. A coupling stage 34 with a resonant circuit 35 tuned to the carrier frequency F behind the frequency converter 16 is used for coupling and decoupling this information 13, which is transformer-coupled to an inductor 36 at the output of the frequency converter 16 or at the input of the control receiver 20.

At installation locations for the evaluation stations 19 (whether they are used only as simple time displays 25 or as time switches, i.e. with time-controlled switching paths 31), at which the power supply network 32 of the building 11 is not available or is not available without interference, the converter is equipped 12 with transmitting antenna 18, a radio link 17.2 for transmission to, for example, evaluation stations 19 operated independently from batteries 37, each of which is equipped with a short-wave receiving antenna 38, as outlined in the example of a battery-operated outdoor lighting in FIG. 1 on the right.

In Fig. 2 top left is taken into account that it is readily possible in terms of equipment, the coupling stage 34 to or from the energy supply house network 32 into a power plug 39 for operating supply of the converter receiver 14 or the display receiver connected to this house network 32 20 to integrate.

If the local transmission link is disturbed, the display receiver 20 cannot record the absolute time information 13. However, since such local disturbances are usually only of a temporary nature, the receiver 20 is then switched off again and the time display 25 continues to operate independently from its own time-keeping circuit 27 until the periodic switch-on of the receiver once again utilizable information 13 for a possibly required display. Correction.

Claims (7)

1. Remotely synchronizable time display (25), in particular with time switch path (31) for controlling a load (33),
characterized,
that it is equipped with a display receiver (20) for carrier-frequency-converted absolute coded time information (13) which can be recorded via local transmission links (17) for correcting the time display (25) operated autonomously in an evaluation station (19). 2. Time display according to claim 1,
characterized,
that the evaluation station (19) is preceded by a coupling stage (34) for the inductive connection of the display receiver (20) to a local AC network (32). 3. Time display according to claim 2,
characterized,
that the coupling stage (34) has a resonant circuit (35) tuned to the local transmission frequency (F) with transformer coupling. 4. Time display according to claim 1,
characterized,
that the evaluation station (19) is equipped with a short-wave receiving antenna (38) for the carrier frequency-converted absolute time information (13). 5. Time display according to one of the preceding claims,
characterized,
that the local transmission link (17) is fed from a converter (12) with a receiver (14) for the carrier frequency (f) of absolute time information (13), to which at least one frequency converter (16) for feeding in the frequency-converted coded time information (13 ) is connected downstream in the local transmission link (17). 6. Time display according to one of the preceding claims,
characterized,
that a load supply network (17.1, 32) is provided between a converter coupling stage (34) and display coupling stages (34) as a local transmission link (17) for the increased carrier frequency (F) of the absolute time information (13). 7. time display according to claim 6,
characterized,
that the coupling stages (34) are combined with power plugs (39).

Images