EP1451914A1 - Method for detecting a defective cooling fan and for generating an alarm signal - Google Patents

Abstract

The invention relates to a method for generating an alarm signal in a motor which comprises a rotor (50) whose effective operating speed is in a standard zone (nSoll, TSoll) and can deviate from said standard zone if defective, and is to be monitored for such a defective state. At least one alarm trigger speed (nAOn, TAOn) and at least one alarm switch-off speed (nAOff, TAOff) are determined, the latter being closer to the standard zone than the first. A hysteresis zone is defined between an associated pair of alarm trigger speed and alarm switch-off speed. If the speed to be monitored, starting from the hysteresis zone, approaches the alarm trigger speed, an alarm trigger criterion (Flag_DIR=0) is generated (Fig. 13: S178). The duration of said alarm trigger criterion is monitored (Fig. 13: S184, 192). When the duration reaches a predetermined value (tdOn), an alarm signal (ALARM) is activated (Fig. 13: S186, 194). The invention also relates to a corresponding motor.

Description

 METHOD FOR DETECTING A DEFECTIVE FAN AND FOR GENERATING AN ALARM SIGNAL

For motors for critical drive tasks, e.g. Internal combustion engines or

Electric motors, it is regularly required that the operating state of the motor is output in the form of a signal, e.g.

Drive = good, or

Drive = bad.

This enables early repair or replacement of a defective motor.

Above all, this applies to fans in mobile radio stations where it is necessary to regularly monitor whether they are rotating and, if so, whether their speed is above a predetermined limit, which ensures the cooling of the mobile radio station.

From DE 43 40 248 A1 (D183 = DE-3008) it is known to change the speed of an electric motor depending on the temperature of a sensor, so that this motor runs quickly at high sensor temperatures, e.g. at 4500 rpm, slowly at low temperatures, e.g. at 1500 rpm. In addition, this known motor monitors at regular intervals whether its speed is a predetermined alarm speed of e.g. Falls below 1000 rpm, and if so, an alarm signal is generated.

It is an object of the invention to provide a new method for generating an alarm signal and a motor for carrying out such a method.

According to the invention, this object is achieved by the subject matter of claim 1. Because the alarm switch-on speed is calculated as a function of the current speed setpoint, an alarm speed is obtained which "moves" with the speed setpoint, ie when it is hot and the speed setpoint is 4500rpm, the alarm turn-on speed is set to 4050rpm, for example, and when it is cold and the Speed setpoint is 1500 rpm, the alarm switch-on speed is set, for example, to 1350 rpm using this method, that is, in both cases, for example to a predetermined percentage of the current speed setpoint.

So if an alarm signal is generated with such a method, it is realistic and shows e.g. indicates that the speed of a rotor, which is prescribed a certain target speed nsoii, has changed so that it is outside a permissible range, e.g. has fallen below 90% of nsoii or has risen above 130%.

It is very advantageous in such a method that it can be divided into a plurality of short routines. If the commutation of an electric motor is controlled by a microprocessor or microcontroller (μC), such short routines can easily be carried out where the μP / μC is currently "underemployed", because the speed control for errors and the output of an alarm signal with faulty speed are usually not tasks that have to be carried out quickly.

Another solution to the problem arises from a method for generating an alarm signal in a motor which has a rotor, the actual speed of which is in operation in a normal zone, can deviate from this normal zone in the event of a fault, and is to be monitored for a fault condition , with the following steps: at least one alarm switch-on speed and at least one alarm switch-off speed are determined, the latter of which is closer to the normal zone than the former, with an assigned pair of alarm switch-on speed and alarm switch-off speed defining a hysteresis zone between them; when the speed to be monitored, coming from the hysteresis zone, reaches the alarm switch-on speed, an alarm switch-on criterion is generated; the duration of this alarm activation criterion is monitored from its generation; when this duration reaches a predetermined value, an alarm signal is activated. By monitoring the duration of the alarm switch-on criterion, short-lasting alarm signals can be "filtered out" that would arise from any artifacts, such as interference signals or short-term disturbances without meaning. Another solution to the problem is provided by a motor with an alarm device for monitoring a deviation of the actual speed of the motor from a normal speed zone, which motor has: a speed sensor for detecting a value characterizing the actual speed of the motor; an alarm device which is designed to compare the actual speed with a predetermined alarm switch-on speed and a different alarm switch-off speed, which speeds define a hysteresis zone between them, and to activate an alarm switch-on criterion when the alarm switch-on speed is reached; and with a timer for monitoring the alarm switch-on criterion, which timer is designed to activate an alarm signal after the alarm switch-on criterion has been activated for a predetermined period of time. The result is that the number of false alarms can be greatly reduced because such false alarms are essentially filtered out in such a motor.

Further details and advantageous developments of the invention result from the exemplary embodiments described below and shown in the drawing, which are in no way to be understood as a restriction of the invention, and from the subclaims. It shows:

1 is an illustration for explaining processes in the generation of an alarm signal,

2 is a diagram which shows how curves for an alarm switch-on limit 46 and an alarm switch-off limit 44 are calculated on the basis of a speed setpoint curve 32,

3 shows a schematic illustration of an electric motor which has a four-pole permanent magnetic rotor 50,

4 shows a schematic representation of a signal HALL, which is generated by the rotor 50 in a Hall IC 60, 5 shows the flow chart of a first embodiment of a first module of a program for generating an alarm signal when using fixed alarm limits, as shown in FIG. 1,

6 shows the flowchart of a second embodiment of a first module of a program for generating an alarm signal, when using alarm limits that are smaller than the target speed and a function of this target speed, as illustrated by an example in FIG. 2,

7 is a diagram which explains the generation of an alarm signal in the event that the actual speed of an engine becomes greater than the target speed,

8 is a flowchart of a third embodiment of the first module analogous to FIGS. 5 and 6 for the implementation of FIG. 7,

9 is a diagram which explains the generation of an alarm signal in the event that the actual speed of an engine becomes either too high or too low,

10 is a flowchart of a fourth embodiment of the first module for implementing FIG. 9.

11 is a flowchart of the second module of a preferred program for generating alarm signals,

12 is a flowchart of the third module of a preferred program for generating alarm signals,

13 shows a variant of FIG. 11, which has more functions than the simpler variant according to FIG. 11,

FIG. 14 shows an illustration analogous to FIG. 1 to explain the mode of operation of FIG. 13 and 15 shows the representation of an initialization routine.

In the following description, parts that are the same or have the same effect are designated with the same reference symbols and are usually described only once.

1 shows a speed characteristic 20, which e.g. can show the speed curve of a faulty engine during a day, an hour or a minute.

1A shows two speed limits, namely a constant alarm switch-on speed (nAOn) 22 and a constant alarm switch-off speed (nAOff) 24, which define a hysteresis zone 23 between them. The speeds nAOn and nAOff usually have a difference of at least 100 rpm, and this hysteresis zone 23 causes a switching hysteresis, i.e. only a larger speed difference .DELTA.n can cause a signal ALARM (FIG. 1C) generated after the speed to fall below the speed nAOn to be switched off again after the speed nAOff is exceeded.

At time t1, the speed 20 falls below the speed nAOff, which causes no changes. At time t2, the speed 20 also falls below the speed nAOn. This generates an alarm criterion 26, the duration of which is monitored from time t2. (In the following, a direction flag Flag_DIR is used as the alarm criterion.) If the speed 20 is again higher than the switch-on speed 22 within a period tdOn, no alarm signal is generated. If, on the other hand, the alarm criterion 26 remains active for a time which is greater than or equal to the time tdOn, an alarm signal 28 (ALARM = 1) is generated. The time tdOn is called the alarm switch-on delay.

After a while, the actual speed 20 increases again in FIG. 1 and exceeds the alarm switch-on speed nAOn at time t3. Nothing happens here due to the switching hysteresis Δn. At time t4, the actual speed 20 also exceeds the alarm shutdown speed nAOff. At this point, alarm criterion 26 is reset, but the signal ALARM = 1 persists. Only when the alarm criterion 26 has been switched off for longer than a time tdOff, is the signal 28 also switched to ALARM = 0. On the other hand, if the speed 20 falls shortly after the time t4 below the speed nAOff, the signal 28 retains the value ALARM = 1. The time tdOff is referred to as the alarm switch-off delay.

The delays tdOn and tdOff, which are mostly different, are usually in the range of 0.5 to 65 seconds, depending on the type of drive. If the time tdOn is set to ∞, an alarm that has been stored remains stored until it has been acknowledged by an operator, e.g. through a manual reset process.

Fig. 2 shows an illustration for explaining a preferred embodiment of the invention. A value Ns is plotted on the horizontal axis, which lies here between 0 and 255 and represents a standardized variable which is derived from a target value, e.g. a DC voltage, a temperature, a pressure etc. If a temperature e.g. is between 0 and 100 ° C, it is first converted into a digital value Ns, e.g. 0 ° C can correspond to a digital value of 0 and 100 ° C can correspond to a digital value of 255.

Using a saved table, these digital values are converted into the desired speeds, i.e. speed setpoints, so that e.g. the following correspondences are given in FIG. 2:

Digital value speed setpoint (rpm) * nsoii Tsoii

0 ... 49 500 120,000.0 μs

50 1000 60,000.0 μs

100 2250 26,666.7 μs

125 3000 20,000.0 μs

150 3600 16,666.7 μs

200 2500 24,000.0 μs

201 ... 255 500 120,000.0 μs ^* ) The speed setpoints are preferably stored in the form of the time Tsoii that a rotor 50 (FIG. 4) requires for the revolution at the desired speed nsoii. Since very long times are obtained for low engine speeds, for example a time of 120,000 μs for 500 rpm, times Tsoii that are> 60,000 μs (corresponding to nsoii <1,000 rpm) are interpreted as nsoii = 0, ie in In the table above, the default of 120,000 μs is interpreted as 0 rpm.

A target speed characteristic curve 32 is thus obtained, as shown in FIG. 2 and which is defined by a total of five points 34, 36, 38, 40 and 42. This nominal speed characteristic curve 32 is assigned a characteristic curve 44 which defines the alarm switch-off speed nAOff and a characteristic curve 46 which defines the alarm switch-on speed nAOn. There is a hysteresis zone 45 between the characteristic curves 44 and 46. The speeds of the characteristic curve 44 correspond to approximately 87.5% of the target speed and the speeds of the characteristic curve 46 correspond to approximately 80% of the target speed 32.

If e.g. nsoii has a value of 3600 rpm at point 40, a signal 28 ALARM = 1 is switched on if the actual speed nist falls below 2900 rpm during the time tdOn, and it is switched off again if nist during a time tdOff has risen again above 3100 rpm.

If, on the other hand, nsoii has a value of 2500 rpm at point 42, the alarm is switched on at 2000 rpm and is switched off again when nist then rises again above 2190 rpm.

In this embodiment, the alarm limits therefore "wander" with the current speed setpoint nsoii, so that the occurrence of an alarm signal is a very refined indication that an error may have occurred compared to the previous solutions. The user of such a speed monitoring consequently knows much better whether there could be a fault in his drive and can take countermeasures earlier.

The definition of speed values

Speed values can be defined in different ways. The usual Definition is in U / min (rpm) or U / s (rps).

FIG. 3 shows an electric motor 49 with a permanent magnetic rotor 50, which in this example has two north poles and two south poles, all of which have a length of 90 °. to have. In this case, it is said in the terminology of electrical engineering that the length of a pole is 180 ° el., And a Hall IC 60, which is opposite the rotor 50, generates a rectangular signal HALL when it rotates, as shown in FIG. 4 is shown.

With such a signal HALL, one can easily measure the distance THALL between two adjacent flanks 52, 53, and this time THALL corresponds to the time it takes the rotor 50 for a quarter-turn at its current speed.

example

The time THALL should be 1 ms = 0.001 s. Then the rotor needs one full revolution

4 x 0.001 = 0.004 seconds, and its speed is

1 / 0.004 = 250 rps

Since one minute has 60 seconds, the rotor turns at a speed of

(1 / 0.004) x 60 = 15,000 rpm ... (1)

Since the time for a full revolution (or even a part of a revolution) can be measured easily and with very good accuracy in an electric motor 49 with Hall IC 60, it is preferred to work with the time THALL or a multiple of it, especially for speed controllers for electric motors you, as this quantity can be used directly after its measurement and is anyway required for controlling the commutation of the motor. This time is therefore a more convenient measure of the speed in the context of an electric motor than one of the other variables such as rpm or rpm, and THALL can easily be converted into rpm if required by taking the reciprocal of the time for one Rotation of 360 ° mech. forms and multiplied by 60, i.e. n (rpm) = 60 / T360 ⁰ mech. ... (2)

The time T in seconds must be used here. As shown in FIG. 3, the electric motor 49 shown has two stator windings 33, 35. The winding 33 is in series with a MOSFET 37 between plus and ground 41, and the winding 35 is in series with a MOSFET 39.

A microcontroller (μC) 43 is used to control the MOSFETs 37, 39, to which the HALL signals are fed from the Hall IC 60. In the form of program modules, which are only indicated symbolically here, the μC 43 contains a commutation control 47 "COMM", a speed controller 48 "n-CTL", a calculation element 51 "SW-CALC" for the calculation of a speed setpoint Tsoii for the Controller 48, an alarm controller 54 for generating a signal ALARM in the event that the speed of the motor 49 becomes too high or too low, a ROM 55 for storing a program, and an alarm delay counter 56 "AVZ" which is connected to the alarm controller 54 interacts, which has an output 57 for the signal ALARM.

The setpoint calculation 51 is carried out from the outside, e.g. from an external sensor 58, a corresponding signal is supplied and converted in SW-CALC 51 into a speed setpoint nsoii or Tsoii. This is done in particular using a table that e.g. can be stored in ROM 55.

The method of operation results from the following explanations. Naturally, the motor 49 shown is only a - very simple - example for any motor - also an internal combustion engine, e.g. a marine diesel - and in no way limits the invention.

Calculation of the arm limits a) The speed setpoint is available in rpm.

The speed setpoint nsoii and a percentage value pA for the desired alarm limit are specified here. Then applies

ΠA = nsoii x pA / 100 ... (3)

Here ΠA = alarm speed.

Is nsoii (supplied by the engine speed controller 49) 4000 rpm, and pA =

80%, then is

ΠA = 4000 x 80/100 = 3200 rpm ... (4) The same applies for nsoii = 4000 rpm and pA = 120%

ΠA = 4000 x 120/100 = 4800 rpm ... (5).

In this case, an alarm is generated when the actual speed increases 20% beyond nsoii.

b) nsoii is the time Tsoii, e.g. Time per rotor rotation, before.

In this case, the formula applies to the alarm time TA

TA = Tsoiι x 100 / pA ... (6)

For example, corresponds to a target speed nsoii = 6000 U / min = 100 U / s a time Tsoii of

0.01 second = 10000 μs per rotor revolution.

If the alarm is to be triggered at a speed of 5400 rpm, i.e. at pA = 90%, the following applies

TA = 0.01 x 100/90 = 0.0111 seconds = 11100 μs ... (7)

In this case, the time TA for the alarm limit of 5000 rpm is longer than that

Time Tsoii.

If the alarm is to be triggered when 6600 rpm is reached, i.e. at pA = 110%, the following applies

TA = 0.01 x 100/110 = 0.00909 seconds ... (8), i.e. in this case TA is smaller than Tsoii.

Simplified calculation algorithm

The formula provides a particularly quick calculation

TA = Tsoii ± Tsoii / x ... (9)

The + sign applies if the alarm speed should be lower than the speed setpoint, and the sign - (minus) if the alarm speed should be higher than the speed setpoint. The number x is preferably a number from the series ..., 1/16, 1/8, 1/4, 1/2, 1, 2, 4, 8, 16 because these numbers pass easily

Left or right shifting of a stored binary value can be generated.

Positive sign (nA <nsoii)

If Tsoii = 0.01 second corresponding to a speed setpoint of 6000 rpm, and it is x = 2, so it holds

TA = 0.01 + 0.01 / 2 = 0.015 seconds ... (10)

This corresponds to an alarm speed of 4000 rpm.

For different values of x, the following values for the alarm speeds result at a speed setpoint of 6000 rpm

Alarm speed (rpm) nA / nsoii

1/16 353 1/17

1/8 666.7 1/9

1/4 1200 1/5

1/2 2000 1/3

1 3000 1/2

2 4000 2/3 4 4800 4/5 8 5333 8/9 16 5647 16/17 32 5818 32/33

With this algorithm it is very easy to determine speed ratios with the values 1/17, 1/9, 1/5, 1/3, 1/2, 2/3, 4/5, 8/9, 16/17, 32 / 33 etc. calculate.

Negative sign (nA> nsoii)

If the alarm speed ΠA should be higher than the set speed nsoii, the following applies

TA = Tsoii - Tsoii / x ... (11)

For example, for Tsoii = 0.01 seconds and x = 4

TA = 0.01 - 0.01 / 4 = 0.0075 seconds ... (12)

This corresponds to a speed of 8000 rpm.

The alarm speed ΠA in this case is 4/3 of the target speed nsoii. With the formula (11) you get - as an example - the following speed ratios: x nA / nsoiι

2 2/1

4 4/3

8 8/7

16 16/15

32 32/31

64 64/63

The program is preferably divided into short modules, the execution of which can take place in the course of the rotation of the rotor 50 at different points of this rotation, since the generation of an alarm signal or its deletion has a very low priority over other calculations in the motor 49. In addition, the calculation of the alarm limits requires that the speed setpoint is determined first. If this is determined from a temperature, the current temperature according to FIG. 2 is first converted into a digital value Ns, e.g. in Fig. 2 the value 105 on the horizontal axis. This value lies between points 36 and 38, i.e. between 2300 and 3000 rpm, i.e. interpolation must be carried out between these two speeds and a set speed nsoii of e.g. 2340 rpm. In the present case, the speed is preferably specified as the time Tsoii for a rotor revolution, which has a value of 1/39 seconds = 25,641 μs at 2340 rpm = 39 rpm.

Based on this, the times TAOn and TAOff are calculated according to equation (9). If one sets TAOn x = 2 and TAOff x = 4, one obtains times of TAOn = 25641 + 25641/2 = 38461, 5 μs ... (13)

TAOff = 25641 + 25641/4 = 32051, 25 μs ... (14).

5 shows at S80 a first embodiment of a module 1a for the alarm calculation, the fixed alarm limits being 24000 μs (= 2500 rpm) and 21428 μs (= 2800 rpm). This corresponds to the example of Fig. 1. At S82 the times TAOn and TAOff are set in the manner explained.

At S84 it is checked whether the current speed nist is less than the alarm switch-on speed nAOn. This is done by comparing the time Tist (corresponding to four times the time THALL in FIG. 4) with the time TAOn calculated in S82.

If the answer is yes, nist is too low, that is, Tist is too high, and the program goes to S86, where it is checked whether the condition Tist> TAOn is fulfilled for the first time. If yes, the alarm delay counter AVZ 56 is set to 0 in S88 and begins to count. The module then goes to step S90, where it is checked whether the time in the AVZ 56 is already greater than the time tdOn, which is shown in FIG. 1C and was explained there.

If it is determined in S86 that the condition Tist> TAOn was already determined in a previous run, the program goes directly to S90.

If it is determined in S90 that the time tdOn has not yet been reached, the program goes to step S92 (return). If it is determined in S90 that the time tdOn has been reached, ALARM = 1 is set in S94 and remains activated until the alarm is cleared again by changing the speed. Alternatively, you can provide that the alarm remains stored and can only be deleted manually, even if the speed returns to normal.

If it is determined in step S84 that the actual speed is greater than the alarm turn-on speed nAOn, the program goes to S96, where it is checked whether nist> nAOff. This is done by comparing the times Tist and TAOff. If no, the program goes directly to S92 Return. If yes, the program goes to S98 and checks there whether nest is above nAOff for the first time. If yes, the alarm delay counter AVZ 56 is initialized in S100, that is, set to zero, begins to count, and the program goes to S102. If the answer is no in S98, the AVZ 56 is already running and the program goes directly to S102, where it is checked whether the AVZ 56 has reached the value tdOff (see FIG. 1C). If no, the program goes to S92 (Return). If yes, go to S104 and clears the alarm (ALARM = 0) because nist was again in an uncritical area during the time tdOff.

FIG. 6 shows a module 1b, which is constructed completely analogously to module 1a of FIG. 5 and is used to implement the "wandering alarm limits" which have already been described in detail in connection with FIG. 2. The suffix b is used for the program steps deviating from FIG. 5, e.g. S80b, and the same reference numerals are used for the corresponding program steps as in FIG. 5, and these program steps are not described again.

In step S82b, starting from a (variable) setpoint TSoii, the two alarm times TAOn and TAOff are calculated, and these are used in the subsequent program steps that correspond to FIG. 5. This results in alarm limits that are 2/3 or 4/5 of the current target speed.

With some drives it can also happen that an alarm must be generated if the motor 49 in question runs too fast, e.g. with an elevator, or with a drive for a roller shutter. This is shown in FIG. 7 using an example analogous to FIG. 2.

A higher alarm switch-off speed 64 (nAOff) and an even higher alarm switch-on speed 66 (ΠAOΠ) are assigned to target speed 62 (nsoii). An upper hysteresis zone 68 is located between the speeds 64 and 66.

Fig. 8 shows a module 1c S80c for implementing this type of wandering alarm limits. The program steps deviating from FIG. 5 are provided with the suffix c, e.g. S80c.

In step S82c, the alarm limits are calculated, the alarm switch-on speed ΠAOΠ being twice as high as nsoii, and the alarm switch-off speed nAOff 33% greater than nsoii, cf. Equation (11) and the numerical example there. Since the alarm speeds here are greater than nsoii, the queries must be the reverse of those in FIG. 5, ie in S84c and S86c it is checked whether Tist <TAOn, and in S96c and S98c it is checked whether Tist> TAOff. The remaining steps correspond to FIG. 5, which is why reference is made to this figure. An alarm is therefore generated here when the motor 49 runs twice as fast as nsoii, and this alarm is switched off again when the speed has dropped to a range below 1.33 times nsoii.

In some cases a combination of the versions according to Fig. 2 & 6 plus Fig. 7 & 8 is required, i.e. an alarm is to be generated if the motor 49 is running too fast, but also if it is running too slowly. This is shown in Fig. 9. Such a motor has four wandering alarm limits nAOni, nAotπ, ΠAOΠ2 and nA0ff2, which are all calculated depending on the instantaneous value of the target speed nsoii 69. This is a function of the size Ns as described in Fig. 2, e.g. Function of a temperature, a voltage, or some other quantity. Below the curve 69 is the lower alarm cut-off speed 70 nAOff-i, which is 4/5 of the value of nsoii, and below the lower alarm cut-in speed 71 nAOni, which is 2/3 of the value of nsoii. A lower hysteresis zone 73 lies between the speeds 70 and 71.

Above the target speed 79 runs the upper alarm cut-off speed 74 nA0ff2, which is 33% above the speed values of the curve nsoii, and above it the upper alarm cut-in speed 75 nA0n2, the value of which is twice nsoii. An upper hysteresis zone 76 lies between curves 74 and 75.

An alarm is therefore activated when the actual speed nist - for a certain value Ns - becomes either> nA0n2 or <nAOni. For example, the current target speed of 2000 rpm, an alarm is switched on when nesting either rises above 4000 rpm or falls below 1333 rpm.

In this example, if the speed drops from 4000 rpm to 2665 rpm when the speed is too high, the "upper" alarm is switched off again. If the speed was too low, so that a lower alarm was generated and it rises again above 1600 rpm, the "lower" alarm is switched off. As described above, the specified alarm speeds can be changed within wide limits by entering the factors x accordingly. The example according to FIGS. 9 and 10 uses the factors x = 4 and x = 2.

10 shows the module 1d (S80d) for implementing this function. Again, only the parts that differ from FIG. 5 are described.

In S82d, starting from the instantaneous value of the target speed (expressed in times Tset), the various alarm speeds are calculated, given in times per 1 revolution. This has been explained in detail in the preceding description. As stated, the calculation uses the values 2 and 4 for the factor x. This is naturally only an example that corresponds to the information in FIG. 9, because an example with concrete numerical values makes it much easier to understand such a difficult invention.

In S84d it is checked whether the actual speed is either below curve 71 or above curve 75 (FIG. 9). If YES, it is checked in S86d whether this error occurs for the first time, and if YES, the AVZ 56 is set to 0 and started at S88. At S90 the value of the AVZ is monitored and when it reaches the time tdOn the alarm is turned on at S94.

If the answer is NO in S84d, it is checked in S96d whether the actual rotational speed lies either between curves 69 and 70 or between curves 69 and 74, and if this is the first time, the AVZ becomes 0 in S98d, S100 set and started. The value in AVZ 56 is monitored in S102, and when it reaches the value tdOff, the alarm is switched off in S104.

In this way, the speed can be monitored in a speed band which extends above and below the target speed 69 in FIG. 9 and whose width is a function of the current target speed. This enables excellent monitoring of an engine for faulty speeds. 11 shows the second module S110. This is executed after the first module S80.

If the rotor 50 is prevented from rotating or the user commands the rotor 50 not to rotate, both are referred to as "blocking mode" and a flag called Flag_Blocked is set to 1, e.g. in S147 of Fig. 15. Module 2 determines why the software is in blocking mode and adjusts the alarm signal accordingly.

If the program is in blocking mode, this can have the following causes: a) The user has given an appropriate command b) The engine is trying to start. c) The engine has been switched off by the program for a few seconds because its speed was previously too low. This state is called the "blocking pause". The process is here:

Motor turns very slowly or is prevented from rotating.

Blocking pause of A seconds.

After the blocking pause, try to start the engine for B seconds (Startup = start attempt).

If the attempt to start is unsuccessful, a new blocking pause of A seconds.

Etc.

If the motor 49 is blocked, this cycle is repeated continuously until the motor starts again, if necessary after a mechanical obstacle has been eliminated. For example, fans in mobile radio stations are often blocked by mice or rats, and if the mouse can free itself, the motor 49 automatically starts again when the next attempt is made to start.

In step S112, a query is made as to whether the software is in the blocking mode. If no, the program goes directly to the end S114 (return) of module 2 and leaves it.

If the answer in S112 is yes, ie the motor 49 is in the blocking mode, the program goes to S116, where the AVZ 56 is set to zero and started. It is then checked in S118 whether the engine is trying to start; then the answer is yes, and then S119 is set to Flag_Startup = 1. This flag is only reset to zero when nist has exceeded a certain value, for example 1000 rpm, that is, the program changes from blocking mode to normal mode. If the motor 49 is blocked, it cannot reach the speed of 1000 rpm within the time period of the start attempt, and after the time for the start attempt has expired, S118 is exited via the no branch and triggers the signal ALARM in S120, S122, because Flag_Startup = 1 is still. - This flag is initialized with zero. Since the timer in S118 is initially set to 0, the answer in S118 is yes after a reset, so that Flag_Startup = 1 is also set in S119.

This part of the program therefore affects the case that start attempts are unsuccessful and the signal ALARM = 1 is therefore generated directly in S122.

If the answer is no in S118, the motor is currently in a blocking pause, i.e. he is currently not receiving any electricity. This is determined using a timer that measures the length of the blocking pause. When this has expired, the motor 49 is switched on and tries to start.

If the answer at S118 is yes, ie a start attempt is determined, the program goes via S119 to S114, that is to say the end of the second module. In this state, the ALARM signal is not changed because it is not yet certain whether the attempt to start will succeed.

If the answer is no in S118, the motor is in a blocking pause (as defined above) and the Flag_Startup is checked in S120. If this has the value 1, this means that the blocking mode is not wanted (ie that the motor is blocked by external influences) and that a start attempt has already been unsuccessful. Therefore, the signal ALARM = 1 is set immediately in S122, unless it has already been set in module 3 (FIG. 12), because the motor 49 is blocked by external influences, and this is a serious reportable error. However, the motor 49 can also be stopped on purpose by giving it an nsoii or tsoii, which the software interprets as speed = 0. In this case, step S120 is issued with No, since no start attempts are made in this case, and the program goes to S124. There it is checked whether the alarm parameter "Stopped" has been activated. This parameter is set if motor 49 was stopped on purpose, but ALARM = 1 must still be set. In this case, the program goes from S124 to S126. There it is checked whether the most significant bit (MSB) in a "MotorRotation" timer is 1. The "MotorRotation" timer records the time THALL, cf. Fig. 4, that is the time for a quarter turn of the rotor 50. If THALL is so large that the most significant bit in this counter is 1, it means that the motor 49 is stopped. In this case the program goes to S128, and ALARM = 1 is set there.

If the most significant bit MSB is not set in S126, the program goes directly to step S130, likewise after S128 and also if the answer in S124 is NO, that is to say the parameter "Stopped" is not activated.

In S130, nsoii or Tsoii is monitored. If this value corresponds to a speed of 1000 rpm or less, it means that the motor 49 should be switched off, for example because cooling is not required in a mobile radio station in winter. The program then goes to S132, where it is checked whether one of the alarm parameters "Stopped" or "Store" is activated. If NO, the program goes to step S134 where the alarm is deactivated and then to S114. If the answer to S130 is YES (nsoii> 1000 rpm), or if the answer to S132 is YES, the program goes directly to S114, i.e. the end of module 2, i.e. the signal ALARM = 1 remains stored.

12 shows module 3 (S140), in which the transition from normal mode to blocking mode is monitored. It is checked in S142 whether Flag_Blocked has the value 0, that is to say the engine is running normally. If NO, the program goes directly to S144 (Return), ie the end of this module.

If the answer in S142 is YES, the program goes to S146 where it is checked whether the reverberation time THALL (Fig. 4) is greater than 30 ms. THALL corresponds to time for a quarter turn, and consequently 0.12 seconds are needed for a full turn in this case. According to equation (2), this means a speed of 60 / 0.12 = 500 rpm. Thus, if a value greater than 30 ms is measured in S146, this means that nist is less than 500 rpm, and therefore the Flag_Blocked is subsequently set to 1 in S147 to indicate that nist is too low. Then the program goes to S148. There it is checked whether nsoii> 1000 U / min. This means that motor 49 should rotate at nsoii, but does not according to S146. Therefore, the alarm is activated directly in S150.

If it is determined in S146 that the value is less than or equal to 30 ms, the program goes directly to S144, likewise if nsoii <1000 rpm, because the software then interprets this so that the speed 0 is specified ,

13 shows, as a variant of FIG. 5 or 6, an expanded module 1E with additional functions. This is designated S170. First, the alarm limits TAOn, TAOff are calculated or entered in the manner described in S172. Then three conditions are checked in S174, namely whether the actual speed is greater than 500 rpm, whether the actual speed is less than the alarm switch-on speed nAOn, and finally whether a Flag_SpeedLow is set. The latter is set when the motor 49 is in the blocking mode, which has already been described.

If the module 1E leaves the step S174 via the YES branch, the preconditions for setting the signal ALARM are met.

In step S176, it is checked whether a flag called Flag_DIR is set. This shows the tendency in which the speed changes, i.e. whether it decreases or increases.

1 shows how the speed nact changes between t1 and t2 in the direction of the speed nAOn. At t2, this speed falls below ΠAOΠ for the first time, and therefore the flag_DIR is set to zero when this "limit violation".

In contrast, the speed ratio is the same as in time period t3 to t4 in FIG. 1 it rises towards nAOff. At time t4, it exceeds nAOff and Flag_DIR = 1 is set when this limit is exceeded.

This flag is queried in S176. If it is set, the speed nist was still greater than nAOn on the last run and has now fallen below this limit, because according to S174 Tist> TAOn, S176 is exited via the YES branch and this flag goes to zero in S178 set because the speed has dropped.

The AVZ 56 is set to zero and started in S180. Then the routine goes to S182.

Since Flag_DIR now has the value zero, steps S178 and S180 are no longer carried out as long as the rotational speed nist does not rise above nAOff, but in this case S176 is exited via the NO branch and goes directly to S182.

Two alarm settings are queried there.

A flag called PowerUpAlarm is set to 0 during a reset or initialization (FIG. 15) and then leads to S182 being exited via the YES branch and the program going to S184. The AVZ 56 is monitored there to determine whether it has reached the time tdOn (FIG. 1C). The AVZ is incremented cyclically when the engine is running, so that it eventually becomes larger than tdOn in S184. Then ALARM = 1 is set in S186. If tdOn has not yet been reached, the routine goes to the end S188 (return) of module 1 E.

The flag PowerUpAlarm, which is queried in S182, serves to wait for the alarm delay once when the engine 49 starts. It is set to 1 in FIG. 13 at S190 when the speed of the motor 49 rises above the speed nAOff at the start.

In S184, a flag called Flag DnDelayOnce is queried. This is a parameter that is set to 1 or 0 at the customer's request, for example, at the factory. If the generation of an alarm signal should be suppressed when the engine is started, but the signal ALARM in normal operation of the Motors should be generated immediately, this flag is set to 1. This function is particularly important for fans because a fan is braked by its impeller when starting, so that the ALARM = 1 signal would be generated briefly when there was no error.

In some applications, this Flag_OnDelayOnce is set to 0 because many customers want an alarm to be displayed after a certain delay so that short errors that repair themselves, so to speak, are not displayed.

If this flag = 0, the program always goes to step S184 through the YES branch in S182, where the alarm delay is monitored.

If this flag = 1, the alarm delay in S184, 186 is only activated until the flag PowerUpAlarm is set to 1 in S190. From this point on, S182 is exited via the NO branch and goes to monitor the .AVZ 56 in S192. A minimum value of approximately 0.3 seconds is specified for the time tdOn in S192. This makes the alarm detection more robust against other errors, e.g. Errors in measuring Tist or calculating Tsoii. If the 300 ms are exceeded, the signal ALARM = 1 is set in S194.

In the flowchart in FIG. 13, the program parts are run through on the right-hand side when the ALARM signal has to be deactivated, or when nist speed is even greater than the speed ΠAOΠ, ie Tact <TAOn. In this case, the program goes from S174 to S200, and there it is checked whether the actual speed nist is still <nAOff, ie whether Tist> TAOff. If YES, the actual speed in the hysteresis zone is between the speeds nAOn and nAOff. In this case, AVZ = 0 is set in S202 and the AVZ 56 begins to count.

The reason for this is as follows: If the speed has dropped below nAOn in FIG. 1, the program is shortly after t2. The delay tdOn in FIG. 1C therefore begins here. If the speed 20 rises above nAOn again during tdOn, no alarm may be activated. That is why the AVZ 56 can always be reset to 0. An alarm is only activated if the actual speed remains longer than tdOn below the speed nAOn. This is explained below in FIG. 14.

If in FIG. 1 the speed 20 has risen above nAOff at time t4, the alarm must be deactivated, unless the customer requests that the alarm be stored permanently. The deactivation is preferably carried out with a delay tdotf, which can also be set to 0 if necessary.

In this case, since nist> nAOff (ie Tist <TAOff), the program goes from S200 to S204, where the already explained Flag_DIR is queried. Since nist has risen above the limit nAOff, Flag_DIR must have the value 1, which corresponds to a "healthy" speed. If this is not the case, the program goes to S206, where Flag_DIR receives the value 1, which indicates that the speed tends to increase. The AVZ 56 is then reset to 0 in S208 and a new deceleration measurement begins.

Subsequently, the already explained Flag_PowerUpAlarm is set to 1 in S190, since when the limit nAOff is exceeded, the starting phase of the motor 49 can be regarded as complete. The Flag_PowerUpAlarm is set to zero during initialization (Fig. 15).

After S190, the program goes to S210. A parameter Flag_Alarm_Store is queried there, which is specified by the customer when ordering. If this parameter has the value 0, a once activated alarm signal may no longer be deleted. Therefore, in this case, query S210 is left through the NO branch, and the program goes to S188.

But if this parameter has the value 1, the program goes from S210 to S212, where it is checked whether the delay time tdOff has expired, and if this is the case, ALARM = 0 is set at S214, i.e. the alarm signal is deactivated.

Flag_DIR (cf. S176, 178, 204, 206) enables this program part to be executed quickly and easily. FIG. 14 explains the processes in the flowchart of FIG. 13 using an example.

The course of the actual speed nact is shown at 220. For didactic reasons, this process is shown so that many functions can be explained on it. The (constant) alarm switch-on speed ΠAOΠ is designated by 222, the (constant) alarm switch-off speed nAOff by 224, and the hysteresis zone in between by 226.

To the left of time t5 has a value in the normal range, the direction flag Flag_DIR therefore has the value 1 and the signal ALARM has the value O.

Between the times t5 and t6, the speed lies in the hysteresis zone 226, which is why steps S174, S200, S202 are continuously carried out in FIG. 13, whereby the alarm delay counter AVZ 56 is constantly reset to 0 according to FIG. 14D, that is to say AVZ = 0, eg every 100μs. This prevents an alarm from being triggered if nist has a value in hysteresis zone 226, i.e. the change in signal ALARM is deactivated in hysteresis zone 226.

At time t6, the speed 220 drops below nAOn, which is why the direction flag Flag_DIR is switched to 0 by S178, which sets the AVZ 56 to 0 in S180, so that it starts its time measurement, e.g. a time tdOn of one minute.

At time t7, e.g. after 30 seconds and before an alarm could be triggered, the speed 220 returns to the hysteresis zone 226, whereby the AVZ 56 is periodically reset to 0, e.g. every 100 s. This continues until time t8, where the speed drops again below ΠAOΠ, which, according to FIG. 13, switches on the AVZ in steps S184 and S186 and, after time tdOn has elapsed, activates the alarm at time t9 (ALARM = 1) causes.

At time t10, the speed 220 returns to the hysteresis zone 226, as a result of which the program again periodically takes steps S174, S200, S202 runs through, and at time t11 the alarm shutdown speed nAOff is exceeded, which causes a switchover to Flag_DIR = 1 in S206 of FIG. 13 and sets the alarm delay counter AVZ 56 to 0 and starts in S208.

Shortly thereafter, at time t12, the speed 220 returns to the hysteresis zone 226, which causes the AVZ to be periodically reset to 0 via S202, so that the alarm is not cleared.

From time t13, the speed 220 returns to the normal range (above the speed 224), and at time t14 the alarm is cleared again after the time tdOff (ALARM = 0).

It can be seen that the signal ALARM = 1 is only generated when the speed 220 has dropped sustainably into the "red zone" (below 222), and that it is only deleted when the speed 220 returns to the "green zone" again "(above 224) has returned, and that in the hysteresis zone 226 the change of a pre-existing alarm signal is deactivated by the signals shown in FIG. 14D, ie if ALARM = 1, ALARM = 1 remains, and ALARM = 0 as well. The possibility of changing ALARM is thus blocked or deactivated in hysteresis zone 226, which prevents the ALARM signal from frequently switching.

15 shows the sequence S234 during the initialization. Initialization takes place after the motor 49 is switched on and during a reset process. In step S236, the alarm signal is set to 0 since it is assumed that the motor 49 is OK when it is switched on. It should also be possible to delete an alarm by switching off the motor and switching it on again if the Flag_Alarm_Store in S210 prevents the automatic deletion of an alarm signal.

In S238, the Flag_PowerUpAlarm is set to 0, which was explained in S182 and which takes effect in S182 when the engine 49 is started.

In S240 the alarm delay counter AVZ 56 is set to 0 and started, and in S242 Flag_DIR receives the value 0, analogous to S178 in FIG. 13.

In S244, the Flag_SpeedLow is set to 1 because this flag is intended to indicate that the speed is below 500 rpm and because the speed is below 500 rpm when starting.

In S246, Tist = 120,000 (μs) is set. This causes the computer to work at a fictitious speed of 500 rpm when starting. This is necessary because otherwise a very long time Tist would be measured at start-up because of the low speed, which could be too long for the registers and could lead to an error.

Following S246, routine S234 ends with S248 return.

Naturally, numerous modifications and modifications are possible within the scope of the present invention. For example, The invention can also be used with an uncontrolled motor, provided that its speed lies in a definable normal zone which is not undercut or exceeded when the engine is running correctly.

Claims

claims

1. A method for generating an alarm signal in a motor (49) which has a rotor (50), the speed of which is to be regulated to a speed setpoint (nsoii), with the following steps:

Starting from an instantaneous speed setpoint (nsoii; Tsoii), an alarm switch-on speed (nAOn AOn) is calculated in time intervals, which is in a predetermined relation to the instantaneous

Speed setpoint (nsoii, Tsoii); it is checked at intervals whether the actual speed (actual,

Tist) of the motor (49) is in an area outside of one

Speed setpoint (nsoii, Tsoii) and switch-on speed defined

Range and on one away from the speed setpoint (nsoii, Tsoii)

Side of this area; if this is the case, an alarm activation criterion (Fig. 1: 26;

Flag_DIR = 0) generated.

2. The method according to claim 1, in which after the generation of an alarm switch-on criterion, the period of time which has passed since the generation of this criterion is monitored.

3. The method of claim 2, wherein when the monitored time period exceeds a predetermined value (tdOn), an alarm signal is generated.

4. The method according to any one of the preceding claims, with the following additional steps:

In addition to the alarm switch-on speed, an alarm switch-off speed is calculated at intervals, which lies between the current speed setpoint (nsoii, Tsoii) and the current alarm switch-on speed and, together with the latter, a hysteresis zone (23; 45; 68; 73; 76 ; 226) defined; it is checked at intervals whether a change in the actual speed of the motor from the hysteresis zone (23; 45; 68; 73; 76; 226) to a range between the alarm cut-off speed and the speed Target value (nsoii, Tsoii) has occurred; if this is the case, an alarm shutdown criterion (Flag_DIR = 1) is generated.

5. The method according to claim 4, in which after the generation of the alarm switch-off criterion, the period of time which has passed since the generation of this criterion is monitored.

6. The method of claim 5, wherein when the monitored time period exceeds a predetermined value (tdOff), the generation of the alarm signal is terminated (ALARM = 0).

7. The method according to any one of the preceding claims, in which a time is used as the speed value, which the rotor needs at the speed in question for passing through a predetermined angle of rotation.

8. The method as claimed in claim 7, in which a target time (Tsoii) is used to characterize the rotational speed setpoint (nsoii), and in which an alarm time (TAO wird) is calculated for characterizing a value used for generating an alarm criterion, which is in a predetermined relation to the target time (Tsoii).

9. The method according to claim 8, wherein the alarm time (TAOΠ) is calculated in such a way that a correction value is added or subtracted to the target time (Tsoii), which is formed by the target time (Tsoii) by a fixed value (x ) is divided.

10. The method according to claim 9, wherein the fixed value (x) is a number from the series ... 1/16, 1/8, 1/4, 1/2, 1, 2, 4, 8, 16, 32. .. is used.

11. The method according to claim 10, in which a shift to a binary base value is used to generate the fixed value (x).

12. A method for generating an alarm signal (ALARM) in a motor (49) having a rotor (50) whose actual speed (nist; Tist) im Operation is in a normal zone (nsoii, Tsoii), can deviate from this normal zone in the event of an error, and should be monitored for an error condition, with the following steps:

At least one alarm switch-on speed (ΠAOΠ, TAOn) and at least one alarm switch-off speed (nAOff, TAOff) are defined, the latter of which is closer to the normal zone than the former, with an assigned pair of alarm switch-on speeds (ΠAOΠ, TAOn) and alarm shutdown speed (nAOff, TAOff) defines a hysteresis zone (23; 45; 68; 73; 76; 226) between them; If the speed to be monitored, coming from the hysteresis zone, reaches the alarm switch-on speed (nAOn, TAOn), an alarm switch-on criterion (Flag_DIR = 0) is generated (FIG. 13: S178); from its generation (Fig. 1: t2) the duration of this alarm switch-on criterion is monitored (Fig. 13: S184; S192); when this duration reaches a predetermined value (tdOn), an alarm signal (ALARM) is activated (Fig. 13: S186, S194).

13. The method according to claim 12, in which it is monitored (FIG. 13: S174, S200) whether the speed to be monitored (nist, Tist) during the monitoring of the duration of the alarm activation criterion (Flag_DIR = 0) is a value in the hysteresis zone (23; 45; 68; 73; 76; 226), and in this case the monitoring of this duration (tdOn) is deactivated (Fig. 13: S202).

14. The method according to claim 12 or 13, wherein when the speed to be monitored (nist, Tist) after generation of an alarm signal from the hysteresis zone (23; 45; 68; 73; 76; 226) coming to the alarm shutdown speed ( nAOff, TAOff), an alarm switch-off criterion (Flag_DIR = 1) is generated, in which the duration is monitored from its generation (Fig. 1: t4), and when this duration reaches a predetermined value (tdOff), the Alarm signal is deactivated (Fig. 13: S214).

15. The method according to claim 14, wherein it is monitored (Fig. 13: S174, S200) whether the speed to be monitored during the monitoring of the Duration of the alarm switch-off criterion (Flag_DIR = 1) assumes a value in the hysteresis zone (23; 45; 68; 73; 76; 226), and in this case the monitoring of this time period (tdOn) is deactivated (Fig. 13: S202) ,

16. The method according to claim 14 or 15, in which before the deactivation of the alarm (Fig. 13: S214) it is checked whether a command (Fig. 13; S210) is present for the permanent storage of an activated alarm, and in this case the Deactivation of the alarm signal is suppressed.

17. The method according to any one of claims 12 to 16, in which when starting the motor a criterion (Fig. 13: S182; Flag_PowerUpAlarm) is generated, which extends the predetermined value for the time required to activate the alarm signal (tdOn) during startup.

18. The method according to claim 17, in which this command is deleted (FIG. 13: S190) when the alarm activation criterion (Flag_DIR = 0) is reset (FIG. 13: S206).

19. The method as claimed in one of claims 12 to 18, in which the alarm switch-on criterion (Flag_DIR = 0) is the inverse value of an alarm switch-off criterion (Flag_DIR = 1), which is generated before an activated alarm signal can be switched off.

20. The method according to any one of claims 12 to 19, in which a speed (nsoii, Tsoii) is used as the normal value of the speed to be monitored (nist, Tist), which is predetermined for the motor by a speed setpoint.

21. The method according to claim 20, wherein the alarm switch-on speed (nAOn, TAOn) is in a predetermined ratio to the speed setpoint (nsoii, Tsoii).

22. The method of claim 20 or 21, wherein the alarm shutdown speed (nAOff, TAOff) in a predetermined ratio to Speed setpoint is available.

23. The method according to any one of claims 12 to 22, in which a target time (Tsoii) is used to characterize the speed setpoint, and in which an alarm time is used to characterize a value used to generate an alarm criterion (nAOn, nAOff) (TAOn, TAOff) is calculated, which is in a predetermined relation to the target time (Tsoii).

24. The method according to claim 23, wherein the alarm time (TAOn, TAOff) is calculated in such a way that a correction value (Tsoiι / x) is added or subtracted from the target time (Tsoi), which is formed by the Target time is divided by a fixed value (x).

25. The method according to claim 24, wherein the fixed value (x) is a number from the series ... 1/16, 1/8, 1/4, 1/2, 1, 2, 4, 8, 16, 32. ..is used.

26. Motor (49) with an arrangement (43) for monitoring a deviation of the actual speed (nist, Tist) of the motor (49) from a normal zone, which motor has:

A speed sensor (60) for detecting a value (THALL) characterizing the actual speed (nist) of the motor; an alarm device (54) which is designed to compare the actual speed with a predetermined alarm switch-on speed (ΠAOΠ, TAOn) and a different alarm switch-off speed (nAOff, TAOff), which speeds have a hysteresis zone (23; 45 ; 68; 73; 76; 226) and to activate an alarm switch-on criterion (Flag-DIR = 0) when the alarm switch-on speed (nAOn, TAOn) is reached; and with a timer (AVZ 56) for monitoring the alarm switch-on criterion (Flag_DIR = 0), which timer is designed to activate an alarm signal (ALARM = 1) after the alarm switch-on criterion (Flag_DIR = 0) for a predetermined period of time (tdOn) was activated.

27. Motor according to claim 26, which is designed as an electric motor (49).

28. Motor according to claim 26 or 27, in which a device (Fig. 13: S200, S202) is provided which monitors the actual speed to determine whether it has reached the alarm switch-on speed (nAOn) and generated the alarm switch-on criterion ( Flag_DIR = 0) assumes a value in the hysteresis zone (23; 45; 68; 73; 76; 226), and which in this case deactivates the process of activating the alarm signal (Fig. 13: S202).

29. Motor according to one of claims 26 to 28, wherein the alarm device (54) is designed to activate an alarm switch-off criterion (Flag_DIR = 1) after activation of the alarm switch-on criterion (Flag-DIR = 0), if the actual Speed coming from the hysteresis zone (23; 45; 68; 73; 76; 226) has reached the alarm shutdown speed (nAOff).

30. Motor according to claim 29, in which a timer (AVZ 56) for monitoring the alarm switch-off criterion (FIG. 13: Flag_DIR = 1) is provided, which timer is designed to deactivate the alarm signal (ALARM = 0) after the alarm switch-off criterion (Flag_DIR = 1) was activated for a predetermined period (tdOff).

31. Motor according to claim 30, in which an arrangement (FIG. 13: S200, S202) is provided which monitors the actual speed (nist, Tist) to determine whether it has reached the alarm cut-off speed (nAOff) and generated the alarm Switch-off criterion (Flag_DIR = 1) assumes a value in the area of the hysteresis zone (23; 45; 68; 73; 76; 226), and which in this case deactivates the process of deactivating the alarm signal (FIG. 13: S202).

32. Motor according to one of claims 26 to 31, which has a speed controller (48) in order to regulate the actual speed (nact) to a desired speed setpoint (nsoii), and which has an arrangement (FIG. 6: 82b) which automatically adjusts the switch-on speed (nAOn) and the switch-off speed (nAOff) depending on the size of the speed setpoint (nsoii).

33. Motor according to claim 32, in which the arrangement (FIG. 6: 82b) is designed to assign a value to the alarm switch-on speed (nAOn), which is essentially a first percentage of the speed setpoint value (nsoii).

34. Motor according to claim 32 or 33, in which the arrangement (FIG. 6: 82b) is designed to assign a value to the alarm cut-off speed (nAOff) which is essentially a second percentage of the speed setpoint (nsoii).

35. The motor of claim 34, wherein the first and second percentages differ from one another in order to form a hysteresis zone (23; 45; 68; 73; 76; 226) when the alarm signal is activated and deactivated.