DE19616258A1 - Temperature monitoring method for rotating metal body - Google Patents

Abstract

The temperature monitoring method uses a number of temperature dependant magnetic permeabilities (5,10a,10b,10c) within the rotating magnetic body (2), inductively coupled with a stationary detector (3,11), providing a voltage signal which is evaluated to determine the temperature of the metal body. The magnetic permeabilities are provided by at least 2 ferromagnetic regions for amplification of the magnetic flux upon each rotation of the metal body, one of the corresponding voltage signals used as a reference signal used to provide a quotient with the other voltage signal, converted into a corresponding temperature output.

Description

The invention relates to a method for indirect monitoring the thermal state of a cyclically moving body, especially for monitoring the temperature of a metal body pers, depending on the area different temperature has magnetic permeabilities, with which a Sig legally linked to magnetic permeabilities wirelessly using a magnetic induction flux transferred to a recording device and from this into a convertible voltage signal is converted, as well an apparatus for performing this method.

In various technical devices, it happens that moving parts of the device under a thermal load lie. To ensure safe operation of the device afford or even failure of a heat-stressed body to avoid, it is necessary to monitor this in the company chen.

It is known to monitor a moving body or several ferromagnetic areas, for example in the form of additional bodies to be provided in or on the body.  

In order in the known method a lawful with the tempe rature of the additional body linked output signal ten, which is largely independent of the distance of the recording is a device to the body or to the additional body, the Curie temperature of the additional body is detected. This he follows in the absence or at least a sharp drop the magnetic induction flux when approaching the Curie temperature or when the Curie temperature is exceeded becomes. This sharp drop in the magnetic induction flux is in the case of ferromagnetic materials due to the strong Change in permeability shortly before reaching it Curie temperature recorded.

The Curie temperature of additional bodies made of iron-nickel-le alloys can be in a certain temperature range by a Change in the alloy composition can be varied. There only the effect of the pronounced Curie temperature is used, can be in the temperature to be monitored an output signal is only recorded in temperature levels the. The output signal that can be generated in this way is therefore dependent essentially depend on what temperature levels work fabrics with suitable Curie temperatures are available. If a temperature range of, for example, 200 Kelvin with Zu sentence bodies to be monitored, the Curie temperatures in a distance of 5 Kelvin, 41 additional bodies must be be used. Another problem is that the Her do not use standard materials with any Can offer Curie temperature, and factory production fabrics according to customer requirements is complex and expensive. In addition it is often difficult with smaller bodies, the required Number of additional bodies to be monitored at all Body.

Furthermore, it is known to use a material whose magnetic permeability in the temperature to be monitored temperature range is a clear function of the temperature.  

However, this measure does not bring a reliable end either signal, because it is never certain whether due to the magne tical permeability a certain output signal is reached or just because the distance between the shots measuring device and the body to be monitored, for example changed wisely due to vibrations in the company.

The invention has for its object a device and to create a process by which the heat state of moving bodies continuously and almost independent of the distance between the Receiving device for the body as well as of varying own inherently similar reception facilities, duration transferred and repetitive and in a further workable output signal can be converted, which is correlatively linked to the actual temperature.

According to the invention this object is achieved in that Body at least two ferromagnetic areas with under different magnetic permeabilities that the magnetic induction flux with every revolution of the body is reinforced by the two successive areas, that the gains of the magnetic induction flux depending transmit a signal to the recording device, which in on successive voltage signals are converted that per Revolution at least one voltage signal as a reference value between cached and from the reference value and the second Voltage signal a quotient is formed, and that per um rotation of the quotient by means of a specifiable or predefined correlate clearly with the temperature is assigned to the output signal.

The proposed method can be used for various purposes application purposes, for example for monitoring the heat status of brake bodies such as brake discs, Brake drums, etc. Of course, the process is also on other bodies, for example parts of turbines like Wel  oils or blades, pump impellers or parts of piston units machines such as pistons, connecting rods, crankshafts, etc. bar.

The magnetic permeability of one ferromagnetic Range, its voltage signal per revolution for reference value is cached and that of the other voltage signals are in the temperature range to be monitored a unique function of temperature. The quotient from the The two voltage signals are themselves unique Function of the temperature, therefore it can clearly be a with the temperature correlating output signal assigned the. This Ver can be used particularly advantageously drive when the temperature range to be monitored is small. There are many materials for small temperature ranges available, the magnetic permeabilities for this Ver drive suitable functions of the tempe, at least in some areas are.

One and diesel are used for the two ferromagnetic areas be recording device used. The distance between the two fer Romagnetic areas from the receiving device is always the same even if the position of the recording is different direction adjusted in operation. The quotient of the two span voltage signals is independent of the distance between the ferro magnetic areas. An increase in distance has an effect to those reinforced by the two ferromagnetic areas magnetic induction fluxes, each to the same extent. The quotient of the two voltage signals changes at one Distance change not. Even replacing an old one defective receiving device against a new one, with another Recording behavior is completely problem-free because the other Recording behavior on the reinforcements of the magnetic In flow affects equally, so no influence on the quotient. There is therefore an automatic Standardization of the transmitted signals to the signal in the form of Quotient.  

The body can have three ferromagnetic areas. Out the reference value and a second voltage signal, as well as from the reference value and a third voltage signal are there formed with two quotients assigned to each other. The two assigned quotient is then determined using a predetermined Register the output signal assigned. This measure can can advantageously be applied when a temperature area to be monitored in which the magnetic permea bilabilities of two ferromagnetic areas no quotient result which is a unique function of temperature is. If the quotient in the temperature to be monitored range, for example, the same value for two temperatures results in a second quotient that corresponds to the changes in the relevant temperature range, thus the two quotients assigned to each other in this Combination of exactly one output signal uniquely assigned can be.

Of course, more than three ferromagnetic can Areas are provided. For example, if there are five four quotients assigned to each other are formed. The quo In this combination, patients must be in a register stand around the output signal corresponding to this combination to be able to assign.

The body can have at least four ferromagnetic areas point. Only a quotient is formed and this one Output signal assigned. The quotient can be in a first delimited temperature range from the reference value and a second voltage signal are formed. In a second limited temperature range, which is the first closes, the quotient of the reference value and one third voltage signal are formed. A fourth ferro magnetic region has a Curie temperature that the highest temperature of the first temperature range the lowest temperature of the second temperature range  ches corresponds. Below the fourth Curie temperature ferromagnetic range, the quotient of the reference value and the voltage signal of the second ferromagnetic Range and from the Curie temperature from the reference value and the voltage signal of the third ferromagnetic region educated.

This way it is possible to use a reference value education serving ferromagnetic area and with three other ferromagnetic areas over a larger tem temperature range an output correlating with the temperature receive signal. Capture of the pronounced curie temperature of the fourth ferromagnetic region is used exclusively for switching between the magnetic per meability of the second and third ferromagnetic Be rich in the transition from the first to the second temperature Area.

The body can have at least five ferromagnetic areas point. The quotient will adjoin one another in three the temperature ranges with the help of the magnetic Permeabilities of three different ferromagnetic areas che generated. In the first two temperature ranges this as described above. The third delimited temperature area closes at the second delimited temperature area. The quotient is made in this temperature range the reference value and the fifth ferromagnetic range educated. The second ferromagnetic region has one Curie temperature on that of the highest temperature of the second Temperature range or the lowest temperature corresponds to the third temperature range. Below the Curie temperature of the second ferromagnetic region is the quotient of the reference value and the voltage signal of the third range and from the Curie temperature from the reference value and the voltage signal of the fifth area.  

This procedure is in the case of the second ferro magnetic range not only its temperature-dependent Magnetic permeability for stepless measurement of the temperature used in the first temperature range, but also its pronounced Curie temperature, namely for switching between the magnetic permeability of the third and the fifth ferromagnetic area at the transition from the second in the third temperature range. An additional sixth ferromagnetic range, the only one with switching Helping its Curie temperature serve is not necessary.

Of course, the entire tempera to be monitored divided into more than three temperature ranges will. Switching from one temperature to the next If possible, the area can be equipped with such ferromagneti areas that occur in a temperature range un below its Curie temperature also for continuous detection serve the temperature.

With this method, a stepless, distance-independent Temperature detection in a wide temperature range possible light. Only a few ferromagnetic areas are required Lich. Even in or on small bodies there is an or Introduction of the required ferromagnetic areas, for example in the form of additional bodies. Furthermore inexpensive standard alloys can be used.

The body can be a brake body, the ferromagnetic regions of which are formed from additional bodies. At the time of a start of braking and the following braking end, the rotation frequencies f _b and f _{e of} the brake body can be detected, and the braking time Δt between the beginning and end of braking can be determined. The deceleration can be derived from the rotation frequencies f _b and f _e and the braking duration Δt. In addition, the temperature increase Δϑ that occurred during the braking period can be determined. The squares of the rotation frequencies f _e at the end of braking and f _b at the beginning of braking as well as the difference between these two rotation frequency squares can be formed. A factor K can be formed from the temperature increase (Δ = ϑ-ϑ₂-ϑ₁) and the difference between the rotation frequency squares as follows:

With the factor K and the square of the instantaneous rotation frequency f _m , a product (K * f _m ²) can be continuously formed. The temperature sum ϑ _s can be continuously formed from the product and the actual instantaneous temperature ϑ _m according to the following relationship:

The temperature sum ϑ _s can be compared with a limit temperature ϑ _g . The limit temperature ϑ _g can be formed from a critical temperature minus a temperature reserve that serves as security. As a preventive measure, a warning signal can be activated and / or the movement energy supply can be throttled or switched off if the temperature sum ϑ _{s is} equal to or greater than the limit temperature ϑ _g .

The amount of heat generated during braking with the maximum possible braking work is roughly proportional to the square of the speed of the mass to be braked, and thus also to the square of the instantaneous rotational frequency f _{m of} the brake body. Knowledge of the specific mass to be braked and its speed, and whether this Mass, for example, is braked to the same extent within a braking time of 20 seconds or 15 seconds, is almost insignificant for the resulting temperature increase. The stronger cooling of a brake body cooled by the ambient air due to a longer braking time, compared to a lower cooling of the brake body with a shorter braking time, is negligible.

It is therefore advantageous in the present exemplary embodiment knowledge of the mass to be braked and their actual speed as well as knowledge of that Brake body absorbable amount of heat, and other marginal conditions not required.

For example, in the case of a vehicle to be braked, it is assumed that the temperature increase Δϑ reached during braking, for example from 180 km / h to 100 km / h during a braking period of 4 seconds, which of course depends, among other things, on the specific heat capacity of the brake body material. With this specific temperature increase Δϑ, as already described above, the factor K is formed. With the help of this factor K and the square of the instantaneous rotation frequency f _m , it is constantly calculated which temperature increase (K * f _m ²) would occur with immediate braking to a standstill. If, for example, the cooling conditions of a brake body deteriorate during operation, this is reflected in an increase in the temperature increase .DELTA..phi. This is included in the calculation of the factor K and will in future be automatically taken into account in the pre-calculation of the temperature increase (K * f _m ²) to be expected with immediate full braking to a standstill.

This method only expediently needs to be used if the determined delay is <3  m / s² and the braking time is <2 seconds, since less Deceleration and shorter braking times no critical tempera doors can be achieved.

The body can be a rotating brake body, the fer Romagnetic areas are formed from additional bodies. The Rotation frequency of the brake body can be detected continuously. With the help of the rotation frequency and the mass to be braked can be latent in the braked mass at any moment existing kinetic energy can be derived. The one Braking with the maximum possible braking work as expected The amount of braking heat supplied to the brake body can be used with these Data are calculated in advance. The one at the current tempera The amount of heat that can still be absorbed by the brake body can be reduced be communicated. For the amount of heat that can be absorbed, at least a limit heat quantity serving for security is formed. The limit heat quantity can be from the currently still absorbable Amount of heat less a reserve amount of heat are formed. A warning signal and / or a throttle can be activated preventively ment or switching off the kinetic energy supply caused become when the predicted amount of braking heat is greater or is equal to the limit amount of heat.

Preferably, several stages of limit heat quantities can ge be formed, for example to activate warning signs len. The warning signals can indicate increasing levels of danger Clues. In addition or alternatively, it can be continued Exceeding these staggered threshold heat amounts an increasing reducing the kinetic energy supply will.

If the mass to be braked rests on a hoist load moving below is its movement only from the earth drawing results, if the limit heat is exceeded ge, for example, a redundant arrangement, in the form of a Zu set brake triggered to failure of the brake body to avoid.  

With a rotating or moving body per the ferromagnetic areas are always in the same Moving direction past the recording device. The However, cyclical movement can, for example, also be a pen del or other swinging movement, in which the loading direction of movement, constantly reverses. In the case of a rotating one Movement is sufficient, only the first of the others the following voltage signals as a reference value and with the following voltage signal (s) in each case To form quotients. In the case of a pendulum movement it is also possible to temporarily store all voltage signals and to form the quotients below. Any one The following voltage signal is the reference value.

The reserve heat quantity can be taken as a product of the heat quantity and a safety factor. The safety factor can at least be taken from the recordable Amount of heat, the momentary kinetic energy and the decelerate send mass to be formed. The Si safety factor and the limit heat quantity only then be true when the temperature is already high from which monitoring appears appropriate.

The device for performing the method has one Body with at least two ferromagnetic areas. The receiving device is cyclically moved The body is arranged stationary. With the receiving device are magnetic induction flows in voltage signals delbar.

With the recording device, a magnetic field, at be generated with the help of a coil, for example. Thereby can keep the magnetic field constant at a constant given strength. Of course, the On the other hand, the receiving device has a permanent magnet point.  

The ferromagnetic areas can be permanent magnetic and generate a magnetic field yourself. Advantageously can thus be used to feed auxiliary energy for transmission of the temperature-dependent signal using the magnetic Field are waived.

Preferably, at least two areas of the body can be ferro have additional magnetic body.

Of course, several additional bodies can also be behind one another are otherwise provided in the body. So it is with conceivable, for example, the temperature of a body from a Aluminum alloy that operates at a maximum working temperature temperature of approx. 440 ° C in a critical temperature temperature range, for example from 310 ° C to 450 ° C to monitor four additional bodies. For this purpose the Body, for example a rotating brake body, with four Provided additional bodies, the four additional bodies are now behind lying opposite each other on the same diameter of the brake body a distance of, for example, 20 angular degrees and if the rotation of the brake body lasts 100 msec, so happen the additional body the receiving device in a temporal Distance of 5.5 msec, while the distance between the last one the four additional bodies to the first of the four additional bodies (100 msec - 3 × 5.5 msec = 83.5 msec). With this data also be the rotational frequency of the brake body, for example and the driving speed of a vehicle be directed.

The additional body can essentially be designed as a pin and be at least partially embedded in the body. Be especially for monitoring a body that ferromagne itself has properties, it is advantageous if the Additional body partially protrudes from the body, so through a shorter transmission distance clearer signals from To be able to transmit additional body to the receiving device.  

The additional body can be with an external thread and the body be provided with an internal thread. He can go to the inside winch screwed in. This way is an easy one Attachment option and easy replacement of Zu sentence bodies possible.

The additional body can be parallel to the axis of rotation in one Recess of the body can be arranged. The introduction of the Additional body can be easily in the axial direction of the Body. By rotating the body in operation and the resulting centrifugal forces become the additional body only perpendicular to its longitudinal axis and with respect to the rotate the body is loaded radially outwards. Through this type of He cannot be absorbed by the attacking forces from the Recess of the body are moved out, but is always kept safe.

The additional body can essentially consist of an iron-nickel Copper-molybdenum alloy exist. Depending on the composition and aftertreatment can additive bodies with diverse tempe rature-dependent permeabilities and in particular diverse Curie temperatures are made for use in the proposed procedure.

The body can be non-magnetic or non-magnetic outside the additional body be paramagnetic. With this measure, that's the addition body-generated signal can be transmitted particularly clearly.

The body can be made of aluminum silicon carbide or aluminum nium oxide alloy exist. Especially as a material for Brake bodies come in addition to the positive para for the procedure magnetic properties of aluminum still the low mas se and the large heat capacity. Ver carbon, carbon-silicon carbide or other materials gem used for the body.

The receiving device can advantageously have a coil have a core with which a magnetic induction  flow can be generated as well as by a ferro that can be moved past magnetic body caused amplification of the magnetic Induction flow is convertible into a voltage signal.

Alternatively, the recording device can have at least one Hall have effect plate in which when passing a electric current and a magnetic induction flow a voltage signal can be generated.

The receiving device can be used as a further alternative, at least have a magnetic field-dependent resistance plate, with which is a change in the magnetic induction flux corresponding voltage signal can be generated.

The body can be a brake body that has an overshoot is provided.

The invention is based on several embodiments games explained. The drawing figures show:

Fig. 1 is a moving body, which partially produces a magneti ULTRASONIC field, a receiving device having a Hall effect plate and a principle sketch of a clamping voltage signal,

Fig. 2 pern a moving body with ferromagnetic Zusatzkör, a receiving device with a coil which generates a magnetic field as well as a schematic diagram of a voltage signal,

Fig. 3 is a schematic representation of a method in accordance with claim 5,

Fig. 4 is a schematic representation of a method in accordance with claim 5,

Fig. 5 is a schematic diagram of a register,

Three Fig. 6 is a schematic diagram of the temperature-dependent Per meabilitäten suitable additional body,

Fig. 7 is a schematic diagram of three temperature-dependent permeabilities that are not suitable for the proposed method in the specified temperature interval.

Figure 8 properties. A moving body with ferromagnetic Eigen, a receiving device with a magnetic field-dependent resistance plate and a principle sketch of a voltage signal,

Fig. 9 shows a section of a braking body with partially screwed in the brake body additional body,

Fig. 10 shows a portion of a braking body partially inset in the brake body additional body,

Fig. 11 is a perspective view of a braking body with three additional ferromagnetic bodies as half-section,

Fig. 12 is a schematic representation of five different temperature-dependent permeability with which a normalized output signal may be generated in three temperature ranges.

According to the drawing, the device 1 for carrying out the proposed method consists of a moving body 2 and a receiving device 3 .

In the embodiment shown in FIG. 1, the moving body 2 consists of a rotating brake body 4 , which has ferromagnetic properties in some areas. The ferromagnetic regions 5 are formed from permanent ferromagnetic additional bodies 6 and 6 a. The additional body 6 is surrounded by a permanent magnetic field 7 . The Aufnah meeinrichtung 3 consists in this embodiment of a thin Hall effect plate 8 , which is flowed through in its longitudinal direction by a current 1 . If the brake body 4 now rotates, the additional body 6 is cyclically moved past the Hall effect plate 8 . In this short time, the additional body 6 reinforces the magnetic induction base of the magnetic field 7 . This passes through the Hall effect plate 8 , and thus transmits a signal. A polarization or change in voltage U arises on the sides of the Hall effect plate parallel to the direction of flow of current 1. This change in voltage U is a further processable voltage signal 9 .

With each rotation of the auxiliary bodies 6 and a is a 6 transmitted in pulse-like signal to the receiving device 3 and from this is converted into a pulse-like voltage signal. 9 This voltage signal 9 is shown in the schematic diagram of FIG. 1 and in the schematic diagrams of FIGS. 2 and 8 each on the ordinate axis. The signal mapped in principle on the ordinate axis could also be the signal transmitted from the brake body 4 to the recording device 3 by means of the amplifications of the magnetic induction flux.

The additional bodies 6 and 6 a have different temperature-dependent permeabilities.

In FIG. 2, a further embodiment of the device is illustrated. The brake body 4 is provided with three ferromagnetic tables additional bodies 10 a, 10 b and 10 c. However, these have no permanent magnetic properties. On the recording device 3 has a coil 11 with a core (not shown). The coil 11 generates a magnetic field 12 . The magnetic induction flow of the magnetic field 12 is amplified due to the temperature-dependent permeabilities of the additive bodies 10 a, 10 b and 10 c, and each induces a voltage signal 9 in the coil 11 .

In the schematic diagram of FIG. 2, the voltage signal generated at a constant tempera ture in the receiving device 3 9 is shown. The schematic diagram also shows that a cycle of movement lasts from the beginning impulse of the set body 10 a to the next beginning pulse of the set body 10 a.

In Fig. 3, a method is shown schematically, with the three transmitted signals of the three additional bodies 10 a, 10 b and 10 c, a further processable output signal AS can be generated, which is a measure of the thermal state of the brake body. In the present exemplary embodiment, the voltage signals S1 to S3 are processed further. For this purpose the voltage signal S1 is latched an additional body 10 a, and treated as a reference value R. The order in which the voltage signals S1 to S3 arrive is in principle indifferent. Instead of three voltage signals, more can also be used (as shown in FIG. 4). Immediately upon arrival of the voltage signal S2, the quotient Q1 between the voltage signals S1 and S2 is formed, and immediately upon arrival of the voltage signal S3 the quotient Q2 between the voltage signals S1 and S3 is formed. The two quotients Q1 and Q2 are subsequently compared with a register 14 which contains all possible combinations of the two quotients Q1 and Q2. The corresponding combination of the two quotients Q1 and Q2 is clearly assigned an output signal AS in the register 14 , which is a measure of the actual heat condition of the brake body 4 . The output signal AS is used to actuate a safety device (not shown) and / or to trigger a warning signal by means of a control device.

In Fig. 4, another embodiment of the method is shown in which a plurality of signals transmitted from the brake body 4 to the recording device 3 have been converted into voltage signals S1 to Sn. All voltage signals S1 to Sn are then buffered. The quotient Q1 and the voltage signals S1 and S3 form the quotient Q2 with the voltage signals S1 and S2 and finally the quotient Qn with the voltage signals S1 and Sn. There are (n-1) quotients. A certain combination of related quotients (Qi-Q2... Qn) is assigned to each temperature. The associated quotients are again compared with a register 14 . The register 14 consists in this case of a table from which an output signal AS is read, which is a measure of the actual thermal state of the brake body 4 . The output signal AS actuates a safety device (both not shown) by means of a control device and / or triggers a warning signal.

The quotient combinations (Q1-Q2... Qn), as shown in FIG. 5, are recorded in the register 14 with a certain tolerance, for example a scatter bandwidth B, so that with different quotient combinations, for example K1, K2, K3, within a tolerable range, always an unambiguous output signal AS can be generated via the thermal state. Within the tolerable range are, for example, those voltage signals which, due to slightly different magnetic properties, additive bodies 10 a, 10 b or 10 c of the same type or different behavior of recording devices 3 originate. This ensures that a defective additional body or a defective receiving device 3 can be replaced without influencing the accuracy of the output signal AS. The quotient combinations shown in FIG. 5, for example K1, K2 and K3, could also be contained in a matrix in which, for example, between 350 ° C. and 370 ° C. not only a single value (360 ° C.) is contained, a field of several temperatures is contained, which brings a more precise resolution of the actual temperature.

In the example shown, there would be an output signal AS generates which corresponds to a temperature of 360 ° C. Ratio combinations, such as K4 or K5, the are outside the spread bandwidth B, lead to output signals AS, which cause a warning signal and / or Operate the safety device (not shown). Kick such an output signal AS only briefly on and ver disappears quickly, so a temporary exterior Influence, such as ferromagnetic dirt particles, to be responsible. If it constantly occurs, for example a defect in the device may be responsible. It can be reacted accordingly.

This ensures that there are quotient combinations with a certain tolerance for each temperature, which occur in this quotient combination (Q1-Q2... Qn) only for this temperature, additional bodies must be used whose temperature-dependent permeabilities P1, P2 and P3, as shown in FIG. 6, do not repeatedly lead to the same quotient combinations (Q1-Q2-... Qn) in the temperature interval to be monitored and thereby erroneously allow multiple conclusions to be drawn about the same temperature. In Fig. 6 is shown an example of how a continuous Ver permeabilities of P1, P2 and P3 of the three additional body 10 a, 10 b and 10 c may appear in principle.

The temperature range 15 shown in FIG. 7 cannot be monitored with the permeabilities P4, PS and P6, because it always leads to the same quotient combination (Q1-Q2-Q3), which incorrectly deduce the same temperature to let.

Fig. 8 shows a further simple embodiment of the device 1 before. In this case, the receiving device 3 consists of a magnetic field-dependent resistance plate 16 . The magnetic field 12 is generated outside the brake body 4 . The brake body 4 is itself ferromagnetic.

The receiving devices 3 of the described embodiment form the device 1 , namely the Hall effect plate 8 , the coil 11 or the magnetic field-dependent resistance plate 16 are interchangeable. They can be used both for whole and for areas of ferromagnetic bodies 2 . They can be used for those which are surrounded by their own magnetic field 7 and for those to whom a magnetic field 12 generated outside the body 2 must be provided.

Fig. 9 shows a portion of a brake body 4 , in which an additional body 6 is partially embedded. For this purpose, the additional body 6 is designed as a pin and is provided with an external thread 17 . With the external thread 17, it is screwed into an internal thread 18 which is arranged in a recess 19 of the brake body 4 .

Of course, it is also possible to glue or rivet an additional body 6 provided with or without an external thread 17 in the recess 19 or to use other known fastening types.

Fig. 10 is also a section of a braking body 4. The recess 19 is designed with a dovetail profile 20 . The additional body 6 has a matching dovetail profile. In the recess 19 there is an undercut 21 which predominantly holds the additional body 6 , which is radially outwardly loaded by centrifugal forces, in a form-fitting manner. Of course, other shapes can also be used for the recess 19 and the additional body, which give hold with the help of at least one undercut 21 .

Fig. 11 shows a cut-through for purposes of illustration in the half braking body 4. In the present embodiment, a so-called brake ring made of an aluminum-silicon carbide alloy is shown. He is hen in the manner of a radially acting pump impeller with blade channels 22 verses. The annular friction surfaces 23 and 24 interact with friction linings (not shown) during operation. In the edge area of the brake body 4 , three additional bodies 10 a, 10 b and 10 c are arranged one behind the other on the same diameter. Protruding ribs 25 and 26 are arranged in the blade channels 22 , on the inner sides of the friction surfaces 23 and 24 . These serve on the one hand to increase the surface area for the purpose of good heat dissipation and to accumulate material in order to give the brake body the highest possible heat capacity. Before geous enough, a material accumulation is unproblematic due to the material of the lightweight brake body 4 . On Ma material recesses and / or recesses, as they are usually seen in cast iron brake bodies for weight reasons before, ver is waived in the proposed brake body 4 . The brake body 4 has in the area of its friction surface 24 a radially inwardly projecting projection 27 which is provided with fastening holes 28 . In addition to the function as a fastening element, the projection 27 also represents a material accumulation to increase the heat capacity of the brake body 4 .

Another advantage of the brake body made of an aluminum alloy is that the abrasion of the friction surfaces 23 and 24 cannot be magnetized and thus has no disruptive influences on the proposed monitoring method.

In principle, FIG. 12 shows a diagram with five different magnetic permeabilities M1, M2, M3, M4, M5 as functions of the temperature, which can be generated as voltage signals in the recording device 3 . With these functions, the method according to claim 4 can be carried out. A quotient is formed in the three adjacent temperature ranges T1, T2 and T3 from the voltage signals of the ranges M2, M3 and M5 as well as the ferro-magnetic range M1 serving as a reference. In the first temperature region T1, the quotient is formed from the reference value R of the ferromagnetic region M1 and the voltage signal of the region M2. In a second delimited temperature area T2, which adjoins the first temperature area T1, the quotient is formed from the reference value R and the voltage signal M3. A ferromagnetic region M4 has a Curie temperature C1, which corresponds to the highest temperature of the first temperature range T1 or the lowest temperature of the second temperature range T2. Below the Curie temperature C1 of the ferromagnetic region M4, the quotient of the reference value R and the voltage signal of the ferromagnetic region M2 and from the Curie temperature C1 of the reference value R and the voltage signal of the ferromagnetic region M3 is formed. The third delimited temperature range T3 adjoins the second delimited temperature range T2. The quotient is formed in this temperature range T2 from the reference value R and the voltage signal of the ferromagnetic range M5. The ferromagnetic region M2 has a Curie temperature C2, which corresponds to the highest temperature of the temperature range T2 or the lowest temperature of the temperature range T3. Below the Curie temperature C2 of the area T2, the quotient of the reference value R and the voltage signal of the ferromagnetic area M5 and from the Curie temperature C2 of the reference value R and the voltage signal of the ferromagnetic area M5 is formed.

This procedure is in the case of ferromagneti area M2 not only its temperature-dependent magne table permeability for continuous temperature measurement used in the temperature range T1 but also its out spoken Curie temperature C2 for switching between the magnetic permeabilities of the ferromagnetic regions M3 and M5, at the transition from temperature range T2 to tempera door area T3. An additional sixth ferromagnetic Be rich, the only one with a pronounced Curie temperature switching between the two of the stepless tempera The door detection serving ferromagnetic areas M3 and M5 is not due to the use of the Curie temperature C2 necessary.

Reference list

1 device
2 bodies
3 receiving device
4 brake bodies
5 ferromagnetic area
6 , 6 a permanent ferromagnetic additional body
7 magnetic field
8 Hall effect plate
9 voltage signal
10 a ferromagnetic additional body
10 b ferromagnetic additional body
10 c ferromagnetic additional body
11 coil
12 magnetic field
13 cycle
14 registers
15 temperature interval
16 magnetic field dependent resistance plate
17 external thread
18 internal thread
19 recess
20 dovetail profile
21 undercut
22 bucket channel
23 friction surface
24 friction surface
25 rib
26 rib
27 head start
28 mounting hole
I current
U voltage change
AS output signal
S1, S2, S3, Sn voltage signal
Q1, Q2, Qn quotient
R reference value
P1, P2, P3, P4, PS, P6 temperature-dependent permeability
B Spread bandwidth
K1, K2, K3, K4 quotient combination
M1, M2, M3, M4, M5 magnet. Permeability as a function of temperature
T1, T2, T3 limited temperature range
C1, C2 Curie temperature.

Claims (22)

1. A method for indirect monitoring of the thermal state of a cyclically moving body ( 2 ), in particular for monitoring the temperature of a rotating Metallkör pers, which has different temperature-dependent magnetic permeabilities in certain areas, with which chem a legally linked signal with the magnetic permeabilities with the help of a magnetic Induction flow wirelessly transmitted to a recording device and converted by this into a processable voltage signal ( 9 ), characterized in that the body ( 2 ) has at least two ferromagnetic areas ( 5 ) with different magnetic permeabilities that the magnetic In duction flow ( 7 , 12 ) at each revolution of the body ( 2 ) through the two successive areas ( 5 ) is strengthened that the amplifications of the magnetic induction flux each transmit a signal to the recording device ( 3 ), which in successive voltage signals ( 9 ) are converted, that at least one voltage signal ( 9 ) is buffered as a reference value (R) per revolution and a quotient (Q1) is formed from the reference value (R) and the second voltage signal ( 9 ), and that per Revolution, the quotient (Q1) is unambiguously assigned an output signal (AS) correlating with the temperature by means of a specifiable or predetermined register ( 14 ). 2. The method according to claim 1, characterized in that the body ( 2 ) has three ferromagnetic regions ( 5 ) with magnetic permeabilities, that from the reference value (R) and a second voltage signal ( 9 ) and from the reference value (R) and a third voltage signal ( 9 ) mutually assigned quotients (Q1, Q2) are formed such that the assigned quotients (Q1, Q2) are assigned an output signal (AS) by means of a predeterminable or predefined register ( 14 ). 3. The method according to claim 1 or 2, characterized in that the body ( 2 ) has at least four ferromagnetic regions ( 5 ), that the quotient (Q1) in a first delimited temperature range (T1) from the reference value (R) of a range ( 5 ) and the voltage signal ( 9 ) of a second region ( 5 ) is formed that the quotient (Q1) in a at the first to the second defined temperature range (T2) from the reference value (R) and the voltage signal ( 9 ) a third area ( 5 ) is formed that a fourth loading area ( 5 ) has a Curie temperature (C1) which corresponds to the highest temperature of the first temperature area (T1) or the lowest temperature of the second temperature area (T2) that below the Curie temperature (C1) of the fourth range of the quotient (Q1) from the reference value (R) and the voltage signal ( 9 ) of the second range ( 5 ) and from the Curie temperature (C1) of the quotient (Q1) of the Re reference value (R) and the voltage signal ( 9 ) of the third region ( 5 ) is formed. 4. The method according to claim 3, characterized in that the body ( 2 ) has at least five ferromagnetic regions ( 5 ), that the quotient (Q1) in a subsequent to the second third limited temperature range (T3) from the reference value ( R) and the voltage signal ( 9 ) of a fifth area ( 5 ) is formed such that the second area ( 5 ) has a Curie temperature (C2) which is the highest temperature of the second temperature range (T2) and the lowest temperature of the third Temperature range (T3) corresponds to that below the Curie temperature (C2) second range of the quotient (Q1) from the reference value (R) and the voltage signal ( 9 ) of the third range ( 5 ) and from the Curie temperature (C2) the quotient (Q1 ) from the reference value (R) and the voltage signal ( 9 ) of the fifth loading area ( 5 ) is formed. 5. The method according to any one of claims 1 to 4, wherein the body ( 2 ) is a brake body ( 4 ), the ferromagnetic areas ( 5 ) are formed from additional bodies, characterized in that at the time of a start of braking and the following braking end Ro tationsfrequenzen (f _b , f _e ) of the brake body ( 4 ) are detected that the braking time (Δt) between the beginning and end of braking is determined that the deceleration from the rotation frequencies (f _b , f _e ) and the braking time (Δt) Tet is that the temperature increase during the braking duration (Δϑ = ϑ₂-ϑ₁) is determined that the squares of the rotation frequencies (f _b , f _e ) are formed at the end of braking and at the beginning of braking that the difference between the two rotation frequency Squares is formed that a factor (K) from the temperature increase (Δϑ) and the difference of the Ro tationsfrequenz-squares is formed, that a product of the square of the instantaneous rotation frequency enz (f _m ) and the factor (K) that the temperature sum (ϑ _s ) is continuously formed from the product and the current temperature (ϑ _m ), that a limit temperature (ϑ _g ) from a critical temperature minus one of the Safety reserve temperature reserve is formed, and that a warning signal is activated preventively and / or a throttling or cut-off of the kinetic energy supply is initiated if the temperature sum (ϑ _s ) is equal to or greater than the limit temperature (ϑ _g ). 6. The method according to any one of claims 1 to 4, wherein the body ( 2 ) is a brake body ( 4 ), the ferromagnetic areas ( 5 ) are formed from additional bodies, characterized in that the rotational frequency of the brake body ( 4 ) continuously it is detected that with the help of the rotation frequency and the mass to be braked, the kinetic energy of the mass to be braked is derived, that the amount of braking heat supplied to the braking body ( 4 ) as expected during braking with the maximum possible braking work is calculated in advance, so that at the current temperature the absorbable amount of heat of the brake body ( 4 ) is determined that for the amount of heat that can be absorbed, at least one limit heat quantity serving for safety is formed, that the limit amount of heat is formed from the amount of heat that can still be absorbed less a reserve heat amount, and that a warning signal is activated and / or a throttling or shutdown of the Kinetic energy supply is caused when the amount of brake heat calculated before is greater than or equal to the limit heat amount. 7. The method according to claim 6, characterized records that the reserve amount of heat as a product from the absorbable amount of heat and a safety margin worth is formed. 8. The method according to claim 7, characterized distinguishes that the safety factor is at least the amount of heat that can be absorbed, the momentary movement gie and the mass to be braked is formed.   9. Device for indirect monitoring of the thermal state of a cyclically moving body ( 2 ), in particular for monitoring the temperature of a metal body, for example a brake body ( 4 ), the magnetic permeability legally linked to the temperature using a magnetic induction flow wirelessly to a receiving device ( 3 ) is transferable and convertible into a voltage signal that can be processed further, characterized in that the body ( 2 ) has at least two ferromagnetic areas, that the receiving device ( 3 ) is arranged stationary with respect to the cyclically moving body ( 2 ), and that Magnetic induction fluxes ( 7 , 12 ) can be converted into voltage signals ( 9 ) with the recording device ( 3 ). 10. The device according to claim 9, characterized in that a magnetic field ( 12 ) can be generated with the receiving device ( 3 ). 11. The device according to claim 10, characterized in that the ferromagnetic areas che ( 5 ) are permanently magnetic and a magnetic field ( 7 ) surrounds the ferromagnetic areas ( 5 ). 12. The device according to one of claims 9 to 11, characterized in that at least two areas ( 5 ) of the body ( 2 ) have ferromagnetic to set body ( 6 , 6 a). 13. The apparatus according to claim 12, characterized in that the additional body ( 6 , 10 a, 10 b, 10 c) is essentially designed as a pin, and that the additional body ( 6 , 10 a, 10 b, 10 c) at least is partially embedded in the body ( 2 ). 14. The apparatus according to claim 12 or 11, characterized in that the additional body ( 6 , 10 a, 10 b, 10 c) is provided with an external thread ( 17 ) and the body ( 2 ) with an internal thread ( 18 ), and the additional body ( 6 , 10 a, 10 b, 10 c) is screwed into the internal thread ( 18 ). 15. The apparatus of claim 13 or 14, characterized in that the additional body ( 6 , 10 a, 10 b, 10 c) is arranged parallel to the axis of rotation of the body ( 2 ). 16. Device according to one of claims 12 to 15, characterized in that the additional body ( 6 , 10 a, 10 b, 10 c) consists essentially of an iron-nickel-copper-molybdenum alloy. 17. The device according to one of claims 12 to 16, characterized in that the body ( 2 ) outside the additional body ( 6 , 10 a, 10 b, 10 c) is un magnetic or paramagnetic. 18. The apparatus according to claim 17, characterized in that the body ( 2 ) consists of an aluminum silicon carbide, an aluminum oxide alloy or carbon or carbon-silicon carbide composite material. 19. Device according to one of claims 9, 10 or 12 to 18, characterized in that the receiving device ( 3 ) has at least one coil ( 11 ) with a core that the magnetic field ( 12 ) can be generated with the coil ( 11 ) is, and that an amplification of the magnetic induction flux ( 12 ) by a ferromagnetic body ( 2 ) which can be moved past can be converted into a voltage signal ( 9 ). 20. Device according to one of claims 9 to 18, characterized in that the receiving device ( 3 ) has at least one Hall effect plate ( 8 ), in which when passing an electrical current (I) and a magnetic induction flux ( 7 , 12 ) a voltage signal ( 9 ) can be generated. 21. Device according to one of claims 9 to 18, characterized in that the receiving device ( 3 ) has at least one magnetic field-dependent resistance plate ( 16 ) with which a change in the magnetic induction flux ( 7 , 12 ) corresponding voltage signal ( 9 ) can be generated. 22. Brake body ( 4 ) with a monitoring device according to one of claims 8 to 20.