SE532508C2 - Safety timer - Google Patents

Description

10 20 25 30 532 5GB Like a standard timer, you set a time during which the safety timer must be allowed to let power through. The safety turner is then activated each time the electrical appliance is switched on with its standard switch, and is switched off if the set time is exceeded.

If a fault occurs on the electrical appliance, for example so that the appliance draws more or less current than the corresponding dry-set threshold value, the safety turner switches off the power completely. Likewise if the device, e.g. a coffee maker or an Iron left and forgotten on. The inventive safety turner is particularly advantageous to use as a monitoring device for devices controlled by any type of sensor. For example, a pressure switch that controls a pump, a thermostat that controls an iron, a candlestick that turns on a headlight or a timer that controls a motor. Typical of such devices is that if there is a fault in the sensor, or some arm fault occurs, it can have serious consequences such as, water damage, fire or engine failure etc. With the safe safety timer connected to such devices, the risk of injury can be significantly reduced.

Fig. 1 - Fig. 10 show examples of teaching methods of the invention. In connection with the figures, the following ear cues are used.

AC = Alternating Current ADC = Analog Digital Converter C = Capacitor CS = Current Sensor BL = Switch for Load D = Detector F = Phase Ht) = Function of Time FB = SwitchFunction GND = Electrical Reference Ground 0 Volt (GrouND ) i (t) = current, time dependent K = comparator L = Load MC = MicroController (built-in microcomputer) 10 20 25 30 532 508 MMI = Man-Machine Interface (buttons, LEDs, display) N = Neutral (in 220 VAC voltage supply system) NC = Closed Normally Closed NO = Normally Open RE = Relay R = Resistance R RD = Relay Driver RST = Reset Button (ReSeT) SF = Statistics Function SP = Control Program ST = Safety Timer tn = time, n = 0, l, 2 , ...

T = Timer / Time timer range TF = TimerFunctions u = voltage u (t) = voltage, time dependent V = Volt VC = AC to DC converter (Voltage Converter) VDD = Positive DC voltage, drive of electronics ZL = Load impedance {D, M, T , S} is the identifier for SP data in Figure 9 Figure 1 shows an embodiment of a first simple realization of a safety timer ST, where the safety turner ST is connected to a 220 VAC wall socket and an electrical appliance L is connected to the safety timer ST. It is mainly intended for static loads, ie. the device L is switched on and after a certain time it is finished with its task. L does not contain a function that varies with external circumstances during the task. An example of this is a kettle.

The safety turner ST contains an AC / DC converter VC for power supply of the unit, which supplies input components with a drive voltage VDD. A built-in microcoder MC is equipped with a control program SP, bLa. including a number of timers in a program module TF which monitors times that are set and expire.

The user can interact with the device, e.g. set times and functions, read data 10 15 20 25 30 532 508 etc., via a user interface MMI, which can include buttons, LEDs and / or displays, including a reset button RST.

The microcomputer is active, continuous or wakes up from a power saving mode at the appropriate interval, and measures / monitors the output voltage u from a detector D. Detector D is described in more detail in connection with Figure 2. The output voltage u is connected to an analog-to-digital converter ADC, or a grain comparator K i rnikrodatorn MC.

If the connected device L is at rest (ie not used), the switch BL is open and the connected device has a very high electrical resistance, ie. interruption. When the relay RE is idle, the contacts are in the NC (Normaly Connected) position, which causes the device to be connected to the detector D and the microcomputer MC detects interruptions.

The switch BL can be activated manually, through a switch function FB, Lex belonging to the device. a switch that triggers the timing. It may also be the case that a timer is simply started by connecting the device / load L to (plugged into) the timer.

The function is now described using the time diagram in Figure 7: If the device L is activated (switched on), e.g. by closing the switch BL, the detector D and the microcomputer MC will register this and can then pull the relay RE via the relay driver RD so that the 220 VAC line is connected to the device and the detector D is disconnected. At the same time, a timing is started at t0 which is set to the appropriate time T = t2-t0.

If the device L is finished with its task at tl, ie. before the time t2, the 220 VAC line continues to be connected before being disconnected at 12. This means that the device cannot continue to draw power if it should have gone wrong or if it has been forgotten. A new time cycle can be started by switching on the appliance.

If, on the other hand, the 220 VAC line is interrupted, by the relay RE at t2, before the device L is ready, which is detected by D and MC in such a way that L does not interrupt, this event is stored by the control program SP in the microcomputer memory. To reconnect the load, BL must be broken and closed again, this is detected in D and a new time cycle can start again. Fig. 2 shows an embodiment of the detector D which is based on the principle of voltage division. In Fig. 2, the lower half of the fi clock, the relationship u = VDD ((ZL + R) / (ZL + 2R)) - ~ VDD (R / 2R) = 1 / ZVDD, if ZL is small (10-1009) and R is large (100k Q).

When the switch BL is open (interrupt), the load ZL is "infinite" and the voltage u becomes equal to VDD. When the switch BL is closed, the load ZL is connected to the detector D and the voltage u becomes dependent on the voltage distribution and the selected resistors R. In the example in Figure 2, the voltage u becomes approx. 0.5VDD which can be easily detected by ADC / K in the microcoder MC.

Fig. 3 shows a further embodiment of the safety timer, suitable for certain devices L which may contain a capacitor blocking for direct current C. The detector according to the embodiments in Figure 2 will then always detect interruptions. To get around this, the microcomputer MC can drive another embodiment of the detector D with a time-dependent alternating signal. In its simplest form, f (t) can be a square wave generated with the microcomputer MC.

This alternative embodiment of the detector D is also based on the principle of voltage division, but is fed by a time-dependent alternating signal, Uin (t), see Figure 4.

At ñg 4, the lower half of the uren clock, the relationship u (t) = fUin (t) in Uin (t) applies. When the switch BL is open (interrupt), the load ZL is "infinite" and the voltage U (t) becomes equal to Uin (t). When the switch BL is closed, the load ZL is connected to the detector D and the voltage U (t) becomes a function f [Uin (t)] which is different from Uin (t) and can be distinguished by ADC / K in the microcomputer MC.

Figure 6 shows how ST with e.g. a Halleicect sensor such as CS provides good safety between the live conductor and the sensor and the rest of the low current electronics through galvanic isolation.

If a current sensor is used, the 220 VAC line can be continuously measured and dynamic / pulsating devices and loads L can then be monitored in addition to static L.

Figure 8 shows an example where a pulsating load is shown, the break function FB can be dynamic and dependent on external circumstances that vary, Lex. temperature, pressure, 10 15 20 25 30 532 5GB speed and consists of a thermostat, pressure sensor or similar sensors, which control the switch BL.

During the total time monitoring T, e.g. t2-t0 in figure 7, data and times about pulse, pause and pulse-pause cycles can be retrieved and stored in MC, e.g. minimum and maximum times.

From this data, a characteristic and / or a “signatuñ k (L), for the device / load can then be calculated. k (L) can tex. be time, but also other quantities such as current, voltage, power, energy, etc. can be calculated and used for this purpose. Furthermore, there may be mean values, median values, dispersion measures and other statistical variables and properties, both over short and long time periods, e.g. time period T, or fl your such time periods are included.

Characteristics and signatures can then be compiled from a collection of several calculated and composite data.

From these collected, calculated and of higher order properties, different profiles of devices and loads can then be established, e.g. for irons, pumps, etc., in order to then be able to be matched with different modes of the control program SP, which can then use appropriate rules to control and control the 220 VAC line.

An example of this could be the following: in order to automatically reset ST to start a new time monitoring cycle T at a pulsating load, a certain time, t [k (L)], must have ñr fl expired after a time trip T. One can then say that the safety timer ST is self-learning with respect to which load is connected and behaviors that are acceptable. This is a great advantage as the behavior of dynamic / pulsating irregular loads can be very difficult to predict.

It is also possible to manually set ST in a mode where it only learns - "records" - the behavior during a certain period of use.

The ST is also equipped with a manual reset button RST for those cases in which the user manually wishes to restart the device / timer.

If the tirner ST is also equipped with components to measure the line voltage connected to another ADC channel (not shown), power and energy consumption can be calculated.

Such calculated values are presented via the MMI interface. 10 15 20 25 30 532 508 Figure 9 shows a dried-out flow diagram of the control program SP. The control program starts after ST has been connected to the 220 VAC line and MC has undergone its start-up phase, PON (Power ON). SP initiates its working memory, among other things ensures that the relay is in its idle state, that all timing registers and variables are reset, as well as the line state that is set to be connected, ie. synchronous with the relay.

After this, the control program SP begins to carry out its actual task, that depending on the input data from the current sensor CS, the man-machine interface MMI, the timing functions TF (timers) or the statistics function SF, which can also perform collections, storage, calculations, comparisons and rnatch narrgs. These tasks are performed at different intervals depending on the priority they have, e.g. Measurement data and time changes should be taken care of quickly and often, while calculations and interaction with the user can take place less often and when free time in the MC is taken into account.

Once these tasks have been performed, the rules must be reviewed so that the right decision can be made.

The condition information of the line must also be reflected in the memory of the MMC. In the same way, a condition must be maintained in TF whether time measurement is in progress or not.

This condition information is then used when the decision rules are applied to check if the 220 VAC line needs to be remedied, ie. broken or closed.

ST can be used with means for communication via the ZZOVAC line so that interaction settings, data and statistics can be presented on a Greek user interface, e.g. using a web browser. Then a simple web server is built into ST, as well as components for communication, e.g. X10 and a mains (ZZO VAC) modern The device may also have a battery for backup needs and to operate a real-time clock.

The invention is shown here for a 1-phase power supply line but can of course be generalized, e.g. to a 3-phase electrical system.

ST is not limited to being a separate unit, but the principle can be integrated directly into a device, e.g. coffee maker, iron, etc. 10 15 20 25 30 532 5GB A very big advantage with the simple formulations in fi g. 1-4 is that they do not need a current sensor which is a relatively expensive component and the production cost can be kept down. Of course, ST can then also be used with dynamic / pulsating loads, but when the time T has elapsed, ST must be reset manually with the reset button RST, or ST can be reset automatically or for a certain, relatively long, time.

Alternative embodiments can realize the functionality of ST entirely in hardware, ie. without (built-in) rnikrodator. Time measurement can be performed with IC circuits such as the well-known timer 555. Such embodiments will be described in more detail in connection with Figure 10. They are intended to control and direct both static and dynamic loads.

Fig. 10 describes further embodiments. The present heating refers to a device for electrically connected devices for shielding and switching off and on, when the switch-off time or switch-on time exceeds those for the set values of a time unit.

In the home and at work today, there are several different electrical appliances and electrically connected functions. Faults can occur in all electrical functions, often unwanted damage can occur, such as fire, flood overheating and breakdowns. There are currently different timers that are intended to switch off various connected electrical appliances after a certain set time.

The disadvantage of these timers is that you always have to activate the timer again to be able to start the connected devices. This often becomes an annoyance because it then easily happens that the device is switched on in the belief that it should start, but if the timer is not also activated then nothing happens. This often results in you simply finding it too annoying and then refraining from using the timer.

The present invention is intended to solve this problem in a simple manner, while at the same time solving additional problems which are not currently solved, for example the following water pump problems.

An ordinary water pump, in an individual house, normally pumps up a pressure in the water line and when the right pressure is reached, the pump switches off. The pump then restarts when the water pressure has dropped to the set value on the pressure switch. If you forget that e.g. closing a water tap 10 15 20 25 30 532 593 or if a leak occurs, it results in the pump running too often and for a long time, which can cause water damage etc. In another typical case, the pump will also start and stop in a run, if the hydrophore or the pressure switch has lost too much air pressure, which will damage the pump and it will draw unnecessarily much electricity and it will result in a worse water fate.

The present invention aims to reduce the risks that such accidents may occur through a time-monitoring programmable function, above all of the time that the device is not switched on. This monitoring should not normally affect the operation of the pump or the connected devices, nor should any other consideration or setting be required to use the pump or the connected devices just as usual after the initial programming has been set by the time units 4 and 6.

Similarly, the invention can monitor and connect to other types of uses of, for example, an iron, a toaster, an element or a coffee maker. For all these examples, it applies that they are controlled by sensors that can disconnect or on the device, but here errors can occur that can cause a fire and for these types of functions the solution is used according to the above example.

Another example of use is whether the invention should monitor e.g. a Kettle.

One should boil the water to then turn off the power to the boiler when the water has reached the correct temperature. These types of devices are often involved in accidents due to. of tex.

Dry cooking and overheating because the thermostat has not switched off properly, etc.

The heating in question can also be used for this type of appliance, where stoves can also be mentioned as these account for about 40% of all fires. Here you set the time that the device can be switched on, e.g. the time it takes to boil up a full cooker, with the addition of a few minutes. If this time is exceeded, the monitoring switch turns off. If the time is not exceeded before the kettle or stove is switched off, the time unit in the unit is reset and the next time you can switch on the kettle or stove again without making any settings of the monitoring switch as this will give a new time with the original setting for as long everything works as it should. 10 15 20 25 30 532 SUS 10 Another simple example of use is the invention as a monitor of an ordinary lamp. Here, the heating can be used as a monitor of the time that the lamp is allowed to illuminate and then switch off the power to the lamp after a period of intermittent power supply. The lamp can then be switched on again with the normal switch after the switch has been switched off and then switched on again, provided that a new full-time lighting is obtained without any new setting having to be made in the unit. The invention has another very unique and practical feature, namely that the safety timer itself when connected to a new device can measure the time that the device has been connected and how much current the device draws and draws during the connected time. The time that the device has been switched on can be read on a display and with the help of this time it is easy to set the timer to a suitable time for how long it should allow a continuous connection of one or more of your devices. On the timer, you can also read how long the minimum time that dares to fl spent between switching on and off. In this way you can easily set this time where required, as in the example with the pump. This ktion function can also be used for irons and other thermostat-controlled appliances, then with additions also for the number of additions and 'friction strokes that have occurred during a certain period, e.g. half an hour, also the number of on and off is registered on the display. If you then want the iron to be switched on for a maximum of half an hour, you only accept what is on the display, after which the iron will switch off after the achieved time, because every som switch made by the thermostat does not count as a zero cause of the total time.

The invention has another peculiarity, namely that in its embodiment it is designed so that smaller currents originating from various forms of small lamps, which are there to indicate that an appliance is switched on, are allowed to pass, but the reset function will nevertheless be eliminated. This can be illustrated with a coffee maker that is set to be connected e.g. half an hour, with the following taking place. The water boils and coffee is brewed, then the power is turned off to this part of the appliance, but a hot plate with an associated LED lamp continues to draw power controlled by a thermostat, which switches the power to the hot plate on and off. After switching on the safety timer for the first time and accepting the values of a half-hour switch-on, the coffee maker will switch off after half an hour. If this happens, the safety timer must be restarted and then the old values will be returned without further adjustment. If, on the other hand, the café brewer is switched off before the time has elapsed, a new time will automatically occur with a half-hour connection without any setting.

All these tasks are solved by the entry in accordance with the characterizing part of claim 1. Advantageous further developments appear from the subclaims. An external example of the entry shall now be described in more detail in connection with the accompanying drawing in fi g. 1 which schematically shows a wiring diagram for the device according to the invention in a practical embodiment.

As can be seen from Figure 10, a supply voltage enters via the lines 7 in a unit 8 here, two units 1 and 2 measure whether a current passes depending on whether a consuming device 3 is connected or not. When the apparatus 3 is switched on, one of the units 1 and 2 measures this and then a time unit 4 is started when the apparatus 3 is switched off, the units 1 and 2 feel this, when this happens the time unit 6 starts when the relay 9 closes. If the set time for the time unit 6 has time to elapse before the apparatus 3 is switched off, this will result in the time unit 6 resetting the time unit 4, whereby a new full time is obtained the next time the apparatus 3 is started. If the apparatus 3 is switched on before the time unit 6 reaches its set value, the time unit 4 will continue its counting at the same time as the time unit 6 is reset at the switch-on. If none of the pauses of the apparatus 3 will be longer than the set time of the time unit 6, the time in the time unit 4 will eventually run out, whereby the current to the apparatus 3 is cut off via the relay 5. If any of the pauses exceeds the time that the time unit 6 is set to, a reset of the time unit 4 will take place with a new full time.

To illustrate how this form of operation is intended to work if it were to be switched on in order, as mentioned earlier in the introduction, to be switched on to control a water pump whose on and off switch is controlled by a pressure switch.

When the pump starts (corresponding to the device 3) the time unit 4 starts when the pump stops the time unit 6 starts if the pump is stationary longer than what the time unit 6 is set for, the time unit 4 is reset and you can drain water for another fi ill time period e.g. 10 minutes. If the pause of the pump during this whole time would never exceed the time set on the time unit (6), it will never reset the time unit 4 which then switches off the pump after a few more sequences to be described in more detail. follows.

In order to easily curl the pump to restart if it has been switched on in the river, (which may be desirable if, for example, you stand and shower or water a flowerbed when the water is switched off) for this event, unit 8 is equipped with a function that can restart the pump as follows. Before a definite shutdown takes place, the unit ll will switch off and on the pump (device 3) an adjustable number of times. The person who showers notices when the water stops flowing and he can then close the water taps, then the pressure will rise again in the water pipes and then the pump motor (apparatus 3) will also start, in which case the time unit 6 starts counting again and if the apparatus 3 is not switched on before the time circuit 6 has expired, this will reset the time unit 4, whereby a new time can be obtained.

If the device 3 (the pump) is switched off by the time unit 4 and it is due to a leakage causing this, the test funnel 11 will, just as above, switch the device 3 on and off an adjustable number of times before the power is completely cut off to the device 3, in this case the water pressure will not return to the water line and the pump (device 3) will not stand still for as long as is required for the time unit 6 to have time to exit. If it were instead a very small water leak, a restart could take place, but then an additional time unit 12 can detect if it has occurred for an adjustable number of times that the time units 4 and 6 have performed the same process for a certain adjustable time. If this has happened, an indicator lamp 14 will appear, at the same time, if desired, via a switch 16, this signal can be activated to activate the shut-off function of the time unit 4. And then a restart must take place via the reset function 10.

In the introductory text it is also mentioned that you can use the call to monitor e.g. An ordinary lamp in a room if you do not want it to be lit more than for a certain time or under certain conditions. In such an example, the unit 8 could be connected after a standard switch 13. When the switch 13 is turned on, the lamp (apparatus 3) lights up at the same time as the time unit 4 starts when the switch 13 is turned off, the lamp goes out and the time unit 4 is reset. Should the lamp (apparatus 3) not be switched on by the switch (13) after the set time of the time unit 4, the power to the apparatus 3 is switched off, the test function 11 as a warning will switch off and on the lamp (apparatus 3) a number of adjustable times before the power to the appliance is completely cut off 3. During this time, one can easily cause the time unit 4 to be reset for a new full time period of power to the apparatus 3 by simply turning off the switch 13 to turn on the switch 13 again, the time unit 4 and the time unit 6 will be reset and a new In some situations it may be desirable not to be able to restart the apparatus 3 immediately without some knowledge, this is achieved in such a way that an adjustable counting unit 15 is connected and in order to restart the time unit 4 a certain number of and from signals come from the connector 13.

Yet another reset option is found in the reset button 10, which can be used if it is desired that it should not be possible to reset after a power failure to the unit 8, whereby a switch 18 in the unit 8 is switched on in advance so that this can be achieved and no reset can take place without that the reset button 10 is activated.

Detailed description of Figure 10 follows below A device for overflow sensing and shutting down of electrical devices between an incoming electrical line (7) and a connected device (3) which is controlled by various current sensing means (1) and (2) and to these connected time circuits (6) and (4) as well as counting units (11) and (14) which are pre-programmed to carry out the desired processes, dare to cut off the power to connected devices if the set values are exceeded, while a new full time is obtained if the power is broken at the connected devices (3) before the set time, in terms of maximum time, my time, if the residence time between switching on and fi year is less, an adjustable number of times. The device is characterized by a current sensing device (1) and (2) which senses when and how much current is consumed by an apparatus (3) above a certain lowest value, a time unit (4) starting, when then the current to the apparatus (3) is cut off. , via some form of means, pressure monitor, thermostat etc. starts a time circuit (6), which monitors the length of the pause of the apparatus (3), if the set value in the time unit (6) is exceeded, the time unit (6) will reset the time unit (4 ), which then again, gives a real time to the device (3). If the pause of the device (3) should be less than the set value, the time unit (6), the time in the time circuit (4) will not be reset. The time unit (4) then continues to run until the time this is set to expires, whereby the device (3) is switched on in the river, via a switch (5). This is registered in a counting unit (15), as well as a time unit (16), which switches the power on and off x number of times, to the apparatus (3), at certain intervals, if the unit (3) then , during this trial period, is switched off, for a longer time than the mining time in unit (6) is set to, a time unit (4) will be reset, and a new full time of current to the apparatus (3) will take place. There is an additional counting unit (17) for the unit, which registers the number of additions and additions that have occurred during a certain time that the apparatus (3) has been connected. If the appliance is controlled by a thermostat, the reset function can ignore the switch on the thermostat, which this year is considered completely natural, the user can therefore in such cases, choose to accept these switches for a certain set time, whereby the safety timer can still work as usual, ie. if the device is switched on within the set time, the time unit (4) will be reset, dare to give a new full time again, the next time the device (3) is switched on If the device (3) is switched off or switched off before the time unit (4) expires the time unit (6) when this time expires will reset the time circuit (4) whereby a new full time can be obtained as soon as the apparatus (3) is switched on again. To ensure that a thermostat is not on for a longer time than it should be, which could result in overheating, a time unit (18) can be activated in cases where a thermostat is switched on, this unit is set in a very short time depending on what the connected device (3) is shown on the safety turret display. Each time the thermostat cuts off the power to the appliance (3), the time unit (18) will be reset to zero, should the thermostat not break within the set time, the time unit (18) will continue until the set time is exceeded. Whereby the time unit (18) switches off the power to the device (3) via the switch (S). If the device (3) is switched off before the time unit (4) has expired, the time unit (6) will then reset the time unit (4) at that time, whereby a new full time can be obtained for the device (3) as soon as it is switched on again, which then detected by the units (1) and (2).

If the supply via the incoming line (7) to the unit (8) were to be interrupted, then turn on again, the time unit (4) is reset, whereby a new full time is obtained. However, this does not happen if switch (20) were to be activated because in this case a restart could only take place by activating the zero button (10).

Since in such cases restart can only be done by the reset button (10) has a test function (1 1) which is switched on after the time unit (4) has expired, whereby the test function (1 1) breaks and shuts off the power. to the apparatus (3) an adjustable number of times, the time unit (6) registers if the apparatus (3) is switched off and no longer consumes current through current sensing devices (1) and (2), if this does not happen, the time unit (6) is reset and starts counting, if the power to the device (3) is not consumed during the time that the time unit (6) is set to the time unit (4) which can thereby give a new full time to the device (4) if the process ia, b, c, d were to repeat a a certain number of times without interruption, this is registered in a time and counter unit (15) which, after an adjustable number of times, can warn via a lamp (14) and report the number of times, and or interrupt the current via the time means (4).

An additional form of exhaust with a device that is connected to ST and which in turn is regulated via a thermostat. for example. a coffee maker with a warning plate, or an Iron is now described using 10 gur 10.

The iron is connected to ST and now it takes quite a long time for the iron to get hot, so the power is switched on quite a long time before the heat has risen so much that the thermostat switches off. But from now on, the iron will only be switched on at short intervals between the on and off of the thermostat.

If we now assume that we set the time 4 to turn off the power to the iron after 30 min. and that we then set the time 6 to set the time 4 after the iron has been switched off for 2 minutes. 1 a: Such a failure should fi sijanae When the srrykjämet is switched on a sr starts the time 4 When the iron is hot the thermostat switches off and relay 9 shuts off the power to the time 6 which then starts, after a certain time maybe 10 seconds the thermostat switches on again and then O time 6 again, then the same process occurs, over and over again, until time 4 expires after in this case 30 minutes. When this happens, relay 5 disconnects the power to the iron (load) (3).

To get power back to the iron, you must now either turn off the power to ST or press the 0 setting button. 10 15 20 25 30 532 5GB 16 If the iron were to be disconnected from ST before time 4 has elapsed, time 6 will expire after its set time of 2 minutes, whereby time 4 will be reset and the next time the iron is switched on a new time of 30 minutes.

If you then would like to plug in an extra safety function that will cut off the power in the event that there is a fault in the thermostat, so that it stays on for far too long, you can imagine that you do it this way.

It is decided that the power must not be switched on for a distance longer than e.g. 5 minutes later, the power to the load must be cut off. This function could then be handled by another time unit called protection time 20.

This time circuit should only be in operation when appliances with a thermostat are connected, for e.g. a kettle, it is not relevant to use this function which must then be able to be switched off.

If, on the other hand, an Iron is switched on, the safety time 20 must be switched on, one could then imagine that the time 6 starts the safety time 20 when the time 6 is reset (the time 6 starts after the load has been switched off for the first time, then the time 6 is reset when the load is switched on again, in connection with this O-setting of the time 6, the safety time 20 can now also be started when the thermostat then switches off the power again, the time 6 is started at the same time as the time 20 is set to 0) If the thermostat to the iron hooks up and does not close of takes place the following. The time 20 is started when the load is switched on, if the load is not interrupted within the set time, the safety time 20 dries, the time 20 interrupts the current via relay 5. To the load 3.

If it should instead be a kettle that is connected to ST, the following time 4 starts when the kettle is turned on and if nothing abnormal happens, the thermostat will turn off the kettle after the water has boiled. When this happens, the time 6 will start and after its set time O- set the time 4. Since the time 6 is never O ~ set because the load is not switched on, nothing more happens.

In this way you could get the function that you have a built-in guard for faulty thermostats or other time functions that should not be exceeded without you actually having to think about whether you have an appliance that is to be connected to ST that has a thermostat or not.

The invention is not limited to any of the embodiments shown, but they can of course be combined with each other in different ways.

Such a combination is shown in Figure 11 where both the detector D and the current sensor CS can be connected to the MC. The output signals u] (t) and u2 (t), respectively, can then e.g. connected to their respective analog-to-digital converter channels, ADCI and ADCZ respectively.

An advantage will be e.g. that the safety tower ST can be reset with an on-off cycle on the switch BL belonging to the device L without the need to reset the RST button on ST.

Claims (1)

A security timer (1), comprising: a first connection connector arranged for connection to a power source; a second connection connector arranged for connection to an electrical apparatus; a switch arranged to close or break a galvanic coupling arranged between said first and second connection contacts; characterized by a current sensor arranged to detect and emit a detector signal in response to a circuit being closed by an electrical device connected to said second connection contact; and by a control device arranged to control said switch to close said galvanic coupling in dependence on a detector signal from the current sensor. . The safety timer according to the preceding claim, further arranged to keep the galvanic coupling closed for a presettable time and to break it if the set time is exceeded. . The safety timer according to any one of the preceding claims, wherein the control device is further arranged to control said switch to break said galvanic coupling in dependence on the apparatus drawing more or less current than a corresponding dry-set threshold value. . Safety timer according to one of the preceding claims, wherein the switch (RE) is connected to the sensor (D) in a first-year contact position; the sensor (D) is connected with a detector signal output to a microcomputer (MC); the sensor (D) is arranged to output a detector signal to the microcomputer when a circuit through an electrical apparatus connected to said second connection socket is closed; the microcomputer (MC) is arranged to, in response to the detector signal, for a preset time, control the switch (RE) to a second contact position which closes the galvanic connection between said first aisle connection contact to a current source and said second connection contact to a electrical appliance. . The safety timer according to the preceding claim 4, wherein the sensor (D) is arranged to be supplied with a time-dependent alternating signal Uin (t); and the sensor (D) is arranged to emit a time-dependent detector signal U (t) which is a function of Uin (t) (f [Uin (t)]) which is different from Uin (t) to the microcomputer when a circuit through a to said second connection plug connected electrical appliance is closed. . The safety timer according to any one of the preceding claims, wherein a sensor (CS) is arranged to measure the magnitude of the current through a circuit through an electrical apparatus connected to said second connection contact and emit a detector signal in response to said circuit being closed; the sensor (D) is connected with a detector signal output to a microcoder (MC); the microcomputer (MC) is arranged to, in response to the detector signal, for a preset time, control the switch (RE) to a second contact position which closes the galvanic connection between said first connection contact to a current source and said second connection contact to an electrical apparatus; the sensor (CS) is arranged to continuously measure the magnitude of the current through said galvanic connection between said first connection terminal to a current source and said second connection contact to an electrical apparatus. . The safety turner according to the preceding claim 6, wherein the microcomputer is arranged to store statistical data over the measured current and to calculate a characteristic of a connected device; the microcomputer is arranged to control the safety turner according to rules depending on said characteristics. 532 š fi ß 20 The safety timer according to any one of the preceding claims, further arranged for measuring line voltage across the galvanic coupling.