DE2522621A1 - Temp. monitor and warning circuit for electric motors - has photo-detector probe near rotor and externally-mounted element - Google Patents

Abstract

The electric motor temperature monitoring circuit detects the temperature in the vicinity of the commutator bushing of the rotor or of the air-gap between rotor and stator. A probe of fibre-optic rod or sealed, hollow tube with lens-end and internal reflecting coating, is positioned near the rotor-end. The other end of the tube is taken through the motor casing to a detector and termination block in a flame-proof or other housing attached to the motor frame. The output of the detector element is amplified and this signal used to switch off the supply to the motor and operate an alarm if the temperature exceeds a certain value.

Description

Electrical machine with at least one radiation receiver for Contactless monitoring of the rotor temperature The invention relates to an electrical Machine with a stand and a rotor, in which at least one with the immovable machine parts firmly connected radiation receiver for monitoring the temperature of the runner, especially in the runner that is particularly susceptible to malfunction when heated Areas, is provided.

When operating an electrical machine such as a motor or a Generator, occurs in the machine parts as a result of the flow of electricity and the resulting occurring Joule heat a warming up, which leads to disturbances and if exceeded certain temperature values can lead to the complete failure of the machine. In order to the resilience and therefore also the performance of an electrical machine their warming is limited.

Large amounts of heat are mainly used in electrical machines released that switch frequently. For example, there is a high switching frequency in such electric motors, the underground mining machines in long-front mining, such as coal plow, drive when the mining resistance is due in the coal face existing rock deposits often grows one after the other so strongly that that it cannot be overcome by the drive motors and therefore the motors expose. Practice has shown that the electric drive motors for coal planers in underground mining operations a switching frequency of up to 60 switching operations per Minute may have.

While the immovable stator of the electric machine is under can be easily cooled with comparatively little effort, is the cooling of the rotating rotor only possible with very expensive means. Hence there is a special need to measure and monitor the temperature of the runner. Often the rotor temperature should be during the entire operation of the electrical Machine are continuously monitored and the machine is impermissible if an high temperature value in the rotor, if necessary automatically, can be switched off. Here the temperature monitoring also serves as overload protection.

It is above all the temperatures that are particularly susceptible to malfunction when heated Monitor areas of the runner. The rotor winding belongs to these areas xxxxxxxxx the machine. The exposed parts of the Rotor winding, from which the Joule heat is dissipated considerably worse than from those in direct contact with the other rotor parts and thus in parts of the rotor winding with good thermal conductivity.

In the case of three-phase squirrel cage motors, those in the rotor package a large number of short-circuit rods made of copper or brass in parallel is arranged to the motor shaft in such a way that it has the rotor core with its end sections protrude in the axial direction, the end sections with one another via short-circuit rings are connected, for example, these end sections of the short-circuit rods are inclusive their connection with the short-circuit rings particularly sensitive to heat. Are the shorting rods soldered to the short-circuit rings, which is the rule, the solder can also be too high Temperatures soften, eventually causing the short-circuit rings to peel off can lead to the short-circuit rods. By detaching the short-circuit rings from the Short-circuit rods can completely destroy the machine.

Because of the difficulty in transferring readings from the rotating Runners on the immovable machine parts are increasingly outside Radiation receivers attached to the runner for monitoring the runner temperature used, so that the monitoring device has no direct contact with the Has runner. Like any other body, the rotor of the electrical machine swaps with the environment from heat in the way of thermal radiation. The thermal radiation can be visible and ultraviolet light, especially ultraviolet light. The kind the thermal radiation or its frequency or wavelength depends on the temperature of the radiant body. This can be derived from the frequency or wavelength of the Thermal radiation emitted by the runner can be deduced from the runner temperature. Radiation receivers use the thermal radiation that hits them Radiation frequency or wavelength and thus dependent on the rotor temperature electrical signal around.

In known devices for monitoring the temperature of the rotor of an electrical machine, thermocouples are used as radiation receivers large number of thermocouples connected in series or resistance thermometers, in which, for example, thin-rolled surfaces are used as radiation receiving surfaces Platinum sheets are provided, used. These facilities have the disadvantage that the measuring speed is usually low and the actual measured values to a large extent interference values are superimposed which falsify the actual measured values. This is one of the reasons why these known monitoring devices are faulty Temperature determinations, because dust particles easily get on the radiation receiver can settle. The response time at these facilities is also long, with what the exceeding of permissible maximum temperatures is often detected too late and the machine is damaged. It has been shown that with the known monitoring devices for the runner temperature a largely instantaneous, unambiguous and moreover safe temperature monitoring is not possible.

Mainly based on the well-known monitoring equipment of thermocouples are also very expensive.

This is how the areas of the rotating rotor to be monitored become when used with a non-reflective, preferably black surface provided, e.g. by a black coating, so that the the radiation emitted to the other rotor areas is only slightly reflected and This radiation is the same as the heat rays emanating from the areas to be monitored thus only superimposed to a small extent. On the other hand, the radiation receiver here usually designed as a black body to prevent one Part of the heat radiation emitted by the runner due to reflection on the radiation receiver itself is lost.

If the surfaces prepared in this way are damaged, what above all in gas-cooled machines, in which dirt particles are carried away with the gas flow can happen, there will be considerable measurement errors. Damage, especially the black surfaces, can also be used when assembling Runners and stands of the machine occur, especially when runners and stands are at slide past each other during assembly.

The determination of the rotor temperature with the help of these monitoring devices is still subject to major sources of error because the state of the black Radiation receiver here mostly to that of a white and thus as radiation-insensitive as possible Comparative body that serves as the carrier for the cold solder joint of the thermocouple or elements is formed, is related.

Finally, there are the costs of the known monitoring device for the runner temperature often in a very unfavorable ratio to the total value of the machines to be monitored. This is especially true for machines of smaller or smaller size medium performance.

The invention has the task of providing a device for contactless monitoring of the temperature of the rotor of the type mentioned above to create that determines the temperature largely without delay and at large Performance and low levels of disturbance variables ensure accurate and safe temperature monitoring and which can also be produced with little effort at low costs is.

This object is achieved according to the invention in that the radiation receiver is designed as a photoelectronic semiconductor component, which against through Heat conduction - in particular by convection - brought about heat supply on the part of the The machine is secured and, if possible, only influenced by thermal radiation.

In the monitoring device according to the invention, the photo effect exploited in semiconductors. The one sent by the rotor of the electrical machine Radiation is converted into an electrical in the photoelectronic semiconductor component Electricity implemented, which in turn is a measure of the temperature of the radiant Runner is. A photoelectronic semiconductor component is very fast or largely without delay, i.e. it is characterized by low photoelectric inertia by a high measuring speed. This will make crossing the dangerous Temperature values are recorded quickly and the machine can then be shut down immediately even with strong ones in quick succession Temperature changes, as with the machines with high switching frequency. On the other hand, it needs because of the high light sensitivity of photoelectronic semiconductor components in As a rule, no special measures are taken on the radiation emission and absorption surfaces, such as black or white paint. Since by means of the device according to the invention directly determines the value of the temperature of the area to be monitored becomes, the measurement accuracy is also high. As a result of these advantages, the machine can can be fully exploited without the risk of partial damage or even complete destruction of the machine due to excessive heating.

Both photodiodes and phototransistors, in which a direct conversion of radiant energy into electrical energy and photoresistors can also be used.

The radiation receiver preferably consists of a photodiode. When the p-n junction of the photodiode is irradiated, charge carrier pairs are formed in this junction released.

If an external voltage is applied to the photodiode and it is reversed operated, these charge carrier pairs flow according to the existing field outside. However, a current is also present without an external voltage, in that the at Charge carrier pairs formed by irradiation cannot cross the barrier layer, but compensate for each other via an external circuit through a short-circuit current have to. For the photodiode, for example, polycrystalline p-conductive material can be used Silene as the base material with a thin, translucent n-conductive layer, for example made of cadmium selenide, or n-conductive silicon as a base material with a thin p-layer can be used.

Phototransistors used as radiation receivers with a light-sensitive The p-n transition show a behavior similar to that of photodiodes. With them, however, takes place an additional gain due to the transistor effect.

In the case of a photo resistor, which is an intrinsic semiconductor, increases when irradiating the number of charge carriers, so that at the same time be more specific Resistance decreases and with constant external voltage the current increases. Photoresistors usually have a longer response time and also wider distribution curves the spectral sensitivity as photodiodes and phototransistors. So allow they usually do not have such reliable and precise temperature monitoring as photodiodes and Phototransistors. On the other hand, photo resistors are more robust and simpler to interconnect than those. Lead sulfide, indium arsenide, or cadmium selenide photoresistors are preferred which are sensitive in the infrared range are used.

According to the invention, as a photoelectronic semiconductor component trained radiation receivers against heat conduction, in particular convection, Heat supply caused by the machine is secured and, if possible, only through Affects thermal radiation. Semiconductor components are different in their electrical properties strongly dependent on temperature. The components grow with increasing temperature the dark currents falsifying the measurement and superimposing the photo currents strongly, and at high temperatures the components can eventually act as radiation meters become completely unusable. Because the semiconductor components are according to the invention secured against heat transfer from the machine caused by heat conduction and if possible only through thermal radiation are affected the radiation receiver is kept at a constant and also low temperature. This means that the disturbance variables are small, but in any case largely determinable, and the Measurement accuracy great.

According to a further feature of the invention is the radiation receiver arranged at a distance from the measuring point and a radiation conductor for guiding the Heat rays provided from the measuring point to the radiation receiver, its the radiation receiver the end facing away is in the immediate vicinity of the measuring point. Here is the Thermal radiation emitted by the rotor in the area of the measuring point through the radiation conductor passed through to the radiation receiver. In this way the by conduction caused heat supply to the radiation receiver on the part of the machine extremely low and thus the temperature of the radiation receiver on the one hand low, but also be kept constant. When using the radiation conductor can also Areas of the runner that are very difficult to access are monitored with regard to their temperature by designing and dimensioning the radiation conductor in such a way that that its end facing away from the radiation receiver to be arranged in such areas is.

It is particularly advantageous in terms of production technology to use the radiation receiver to be arranged at the end of the radiation conductor facing away from the measuring point, whereby it It is also recommended to use the radiation receiver with the one facing away from the measuring point To connect the end of the radiation conductor directly. To get as large an output signal as possible of the radiation receiver should be the active area of the radiation receiver be at least as large as the cross-sectional area of the radiation conductor.

The radiation conductor is preferably arranged outside the stand, so led around the stand. The monitoring device is very simple designed and also easy to assemble. In this case, you can also easily can be retrofitted in a machine. Is the radiation conductor on this one The radiation conductor can also be designed to be flexible when the monitoring device is designed different measuring points one after the other by simply bending the conductor be assigned. In this way, one and the same radiation guide can be used and several measuring points can be monitored at the same time with just one radiation receiver. before But it can do so especially when the electrical machine is in an unsteady state be expedient to provide the radiation conductor within the stator.

In a preferred embodiment, the radiation conductor is as tubular or tubular radiation channel formed. In this case the Heat radiation guided within the radiation channel to the radiation receiver, if necessary under multiple reflections on the inner walls of the canal.

Is the radiation conductor as a tubular or hose-shaped radiation channel formed, it is advantageous if the radiation conductor is essentially straight is. This is because the proportion of those directly hitting the radiation receiver predominates Radiation by far the share of only in the way of reflections on the channel inner walls radiation reaching the radiation receiver. When there is a reflection of radiation Attenuation of the thermal radiation cannot be completely ruled out on the inner duct walls. A lower radiation attenuation as a result of reflections can, however, be achieved as a result achieve that the radiation conductor has a circular inner cross-section.

The radiation conductor preferably consists of a tube or hose made of metal or plastic.

The radiation attenuation within the radiation channel can also be achieved thereby be reduced that the radiation conductor is mirrored on the inside. Here is the quality of the mirror coating for the efficiency of the radiation transmission from the The measuring point towards the radiation receiver is decisive. It is recommended to use the mirror coating by vapor deposition of aluminum, gold or silver on the inner walls of the radiation conductor to undertake. The vapor deposition of aluminum has the advantage that it takes place at the same time It is inexpensive and technically easy to carry out that aluminum reflectors but also have a particularly good time stability.

It is useful to have the radiation conductor facing the measuring point To close the end dust-tight, because dust particles inside the radiation conductor lead to increased radiation attenuation. Will the radiation guide at his the end facing the measuring point is in particular hermetically sealed, the supply of heat on the part of the machine towards the radiation receiver further reduced. Both the Radiation attenuation within the radiation conductor as well as the supply of heat to the radiation receiver by way of heat conduction is then particularly low, when the radiation conductor is closed in a vacuum-tight manner at its end facing the measuring point is.

The radiation conductor can not only be tubular or hose-shaped Be formed radiation channel.

According to a further feature of the invention, the radiation conductor rather also consist of an optical fiber.

If one or more lenses are assigned to the radiation conductor, which bundle the heat rays on the radiation receiver, becomes the efficiency the transfer of heat rays from the measuring point to the radiation receiver further increased. The lenses used here are preferably made of a heat-resistant one and at the same time heat-insulating material.

The radiation receiver can counteract by conduction, in particular by convection, the heat input from the machine is not only caused by the interposition of a radiation conductor between the measuring point and the radiation receiver be secured, but also by the fact that the radiation receiver within a is arranged substantially vacuum-tight housing. In this case it can Housing accommodating the radiation receiver in the immediate vicinity of the measuring point to be ordered. This embodiment of the invention is particularly manufacturing technology simple, but also very reliable and safe to operate. She can also are designed to be very space-saving, which is why they are also used in very cramped conditions suitable is.

If the radiation conductor and the possibly existing, the Housing made of an electrically conductive material for receiving the radiation receiver produced, is to avoid undesirable heating of the radiation conductor respectively.

of the housing as a result of eddy currents that cause a temperature increase of the radiation receiver can result in a material less electrical Conductivity chosen.

The monitoring of the rotor temperature is then particularly effective, if several measuring points to measure the Rotor temperature provided are, with each measuring point one and the same radiation receiver or one each separate radiation receiver can be assigned.

The monitoring of the electrical machine can be done in a simple manner take place automatically by placing the radiation receiver (s) in a monitoring circuit are incorporated. The monitoring circuit preferably has a relay for automatic shutdown of the machine if the permissible temperature values are exceeded on; the monitoring circuit can also, if necessary at the same time, give a warning signal trigger.

Are the electrical currents occurring at the radiation receiver only slightly, it may be useful to give the radiation receiver (s) an or to connect several, preferably series-connected, electrical amplifiers downstream.

It has been shown that the device according to the invention for temperature monitoring even in rooms at risk of firedamp, such as underground those at risk of firedamp Mine construction, used electrical machines can be used advantageously. For example, mine workings at risk of firedamp are only allowed with special firedamp protection equipped electrical equipment can be used. As with electrical machines with the monitoring device according to the invention, the radiation receiver and the this associated electrical components and lines at a distance from the rotor and so that they can be arranged in places where the temperature is only low, there is a risk of explosive mixtures igniting with these machines the electrical currents and voltages caused by the monitoring device greatly diminished.

The firedamp protection can also be further increased in that the radiation receiver (s) are encapsulated so that they are protected against firedamp. The or the radiation receiver can, for example, in the connection box of the electrical Machine that is designed to be firedamp proof.

The inventive monitoring device for the rotor temperature at the state-of-the-art facilities of the type mentioned measured, extremely inexpensive. Therefore, it can also be used with engines with a lower output Find application in which so far on a temperature monitoring largely therefore has been omitted because it is cheap, but largely instant, safe monitoring equipment were not available.

In the drawing, the invention is based on several exemplary embodiments illustrated in a schematic representation. A three-phase squirrel cage motor is used as the electrical machine chosen. The monitoring device each has a radiation conductor. It 1 shows a motor with a monitoring device according to the invention in Longitudinal section, with the radiation conductor outside the stand and the radiation receiver are arranged in a flameproof junction box; Fig. 2 shows a motor with a monitoring device according to the invention in a longitudinal section, wherein the radiation conductor is also arranged outside of the stator; Fig. 3 shows a motor with a monitoring device according to the invention in a longitudinal section, where the radiation conductor is located within the stand; 4 circuit diagrams of the monitoring and 5 device according to the invention without or with preamplifier.

In Figs. 1, 2 and 3, the three-phase squirrel cage motor is with 1 referred to. In the motor housing 2 is the fixed stand 3 and the rotor 5 rotating inside the stator on the motor shaft 4.

In the rotor core 6 is a large number of short-circuit rods made of copper 7 used, which protrude beyond the rotor core 6 in a known manner in the axial direction and are connected to one another with short-circuit rings 8 at their end sections 7a. The short-circuit rings 8 have bores running parallel to the motor shaft Lt, in which the short-circuit rods 7 are inserted and soldered with their end sections 7a are.

The monitoring devices for the rotor temperature each have a radiation receiver 9 arranged outside the motor housing 2, which consists of a photodiode and fixed to one end of a radiation conductor 10 connected is. The other end of the radiation conductor 10 is in the immediate vicinity Near the measuring point 11. The radiation conductor 10 consists of a flexible plastic tube with a circular inner cross-section. It's inside with a vapor-deposited Aluminum layer provided. At its end facing the measuring point 11 is the radiation conductor 10 by a radiation-permeable and at the same time heat-resistant and heat-insulating Sealing glass 13 closed vacuum-tight. The sealing glass 13 is also designed as a lens, which radiate the heat emitted by the measuring point 11 onto the receiving surface of the radiation receiver 9 bundles.

The radiation receiver 9 is with its essential parts before all its electrical components and lines, within a connection box 14 attached. The electrical lines 15 of the radiation receiver 9 are on switched on a monitoring circuit (not shown).

In the embodiments of FIGS. 1 and 2, the temperature the exposed end portions 7a of the short-circuit rods 7 monitored. Accordingly is located The end of the radiation conductor 10 facing away from the radiation receiver 9 is here in the immediate vicinity of these end sections 7a. The radiation conductor 10 is in both Cases in particular arranged outside the stator, that is, inside the motor housing 2 passed the stand. In the embodiment according to FIG. 1, this is the radiation receiver with its essential parts receiving terminal box 14 firedamp proof formed, in the embodiment of FIG. 2, the connection box 14 is on the other hand open on the sides.

In the embodiment of FIG. 3, the temperature of the rotor 5 monitored in the area of the air gap between the rotor 5 and the stator 3. For this purpose, the radiation conductor 10 is arranged within the stand 3. Here too the radiation receiver is located in a connection box 14 which is open at the side.

According to the electrical circuit diagram of Fig. Lt is the radiation receiver 9 an electrical amplifier connected downstream. It forms a structural unit with this 16, which is supplied with electrical energy via a power supply unit 17. In the The circuit according to FIG. 5 is the radiation receiver 10 also an electrical one Amplifier connected downstream and with this to a structural unit 18 summarized. The amplifier part of the structural unit 18 is only used here for pre-amplification.

There are therefore only low signal voltages at the output of the structural unit 18 which in the main amplifier supplied with electrical energy by the network unit 17 19 will be further strengthened.

The one present at the output of the structural unit 16 or the main amplifier 19 Voltage is supplied to the monitoring circuit, not shown, which is a Has relay for switching off the motor 1. According to Fig. 5, the temperature of the Rotor 5 elsewhere also with the help of a conventional radiation receiver, e.g. a thermocouple, or the temperature of the winding by means of a thermal sensor monitored, these temperature monitoring elements 20 also connected to the amplifier part the structural unit 18 are connected.

The heat radiation emitted by the measuring point 11 enters the Radiation conductor 10 via the sealing glass 13 designed as a lens and is within of the radiation conductor 10, possibly after multiple reflections on the walls of the radiation conductor 10 to the radiation receiver 9.

The radiation receiver 9 responds to the transmitted from the measuring point 11 Radiation, so that at its output an electrical, frequency or wavelength the thermal radiation and thus the temperature at the location of the measuring point l1 electrical voltage is present. This voltage is after amplification by the electrical Amplifier 16, 18, 19 fed to the monitoring circuit. If the permissible maximum temperatures switches the one assigned to the monitoring circuit Relay the electric motor automatically, with a warning signal triggered at the same time will.

Claims (29)

Patent claims: Electric machine with a stator and a rotor, in which at least one radiation receiver firmly connected to the immovable machine parts to monitor the temperature of the runner, especially when it heats up areas susceptible to failure, it is provided that h n e t that the radiation receiver (9) is a photoelectronic semiconductor component is formed, which against by conduction - in particular by convection - Heat supply caused by the machine (1) secured and if possible only through Thermal radiation is affected. 2. Electrical machine according to claim 1, d a -d u r c h g e k e n n z e i c h n e t that the radiation receiver consists of a photodiode or a phototransistor consists. 3. Electrical machine according to claim 1, d a -d u r c h g e k e n It should be noted that the radiation receiver consists of a photoresistor. 4. Electrical machine according to claim 1, 2 or 3, d a d u r c h it is noted that the radiation receiver (9) at a distance from the Measuring point (11) arranged and a radiation conductor (10) for guiding the heat rays from the measuring point (11) to the radiation receiver (9) is provided, the radiation receiver of which (9) the remote end is in the immediate vicinity of the measuring point (11). 5. Electrical machine according to claim 4, d a -d u r c h g e k e n n z e i c h n e t that the radiation receiver (9) at the one facing away from the measuring point (11) The end of the radiation conductor (10) is arranged. 6. Electrical machine according to claim 5, d a -d u r c h g e k e n n z e i c h n e t that the radiation receiver (9) with the one facing away from the measuring point (11) End of the radiation conductor (10) is connected. 7. Electrical machine according to claim 4, 5 or 6, d a d u r c h it is not indicated that the active surface of the radiation receiver (9) is at least as large as the cross-sectional area of the radiation conductor (10). 8. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) is outside of the stand (3) is arranged. 9. Electrical machine according to claim 8, d a -d u r c h g e k e n It is noted that the radiation conductor (10) without any significant change in its Cross-section is flexible. 10. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) within of the stand (3) is provided. 11. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) as a tubular or tubular Radiation channel is formed. 12. Electrical machine according to claim 11, d a -d u r c h g e k e It is noted that the radiation conductor (10) is essentially straight. 13. Electrical machine according to claim 11 or 12, d a d u r c h it is noted that the radiation conductor (10) has a circular inner cross-section having. 14. Electrical machine according to claim 11, 12 or 13, d a d u r c h e k e k e nn n n e i n e t that of a tube or hose made of metal or plastic. 15. Electrical machine according to claim 11 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) is on the inside is mirrored. 16. Electrical machine according to claim 15, d a -d u r c h g e k e n n z e i c h n e t that the inner walls of the radiation conductor (10) with a vapor-deposited Metal layer (12) made of aluminum, gold or silver are provided. 17. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) at his the end facing the measuring point (11) is sealed dust-tight and / or airtight, preferably through radiation-permeable glass (13). 18. Electrical machine according to claim Lt or one of the following, characterized that the radiation conductor (10) is closed vacuum-tight at its end facing the measuring point (11). 19. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) consists of a Optical fiber consists. 20. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) at least a lens (13) is assigned, which the heat rays on the radiation receiver (9) bundles. 21. Electrical machine according to claim 20, d a -d u r c h g e k e It is noted that the lens (13) is made of a heat-resistant and heat-insulating Material. 22. Electrical machine according to claim 1 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation receiver (9) within a substantially vacuum-tight housing is arranged. 23. Electrical machine according to claim 22, d a -d u r c h g e k e n n z e i c h n e t that the housing receiving the radiation receiver (9) is in is arranged in the immediate vicinity of the measuring point (11). 24. Electrical machine according to claim 4 or one of the following, d a d u r c h e k e n n n z e i c h n e t that the radiation conductor (10) and that possibly existing, the radiation receiver (9) receiving a housing Material of low electrical conductivity exists. 25. Electrical machine according to claim 1 or one of the following, d a d u r c h e k e n n n z e i c h n e t that several measuring points (11) for monitoring the rotor temperature are provided, each measuring point (11) one and the same Radiation receiver (9) or each associated with a separate radiation receiver (9) is. 26. Electrical machine according to claim 1 or one of the following, d u r c h e k e n n n z e i c h n e t that the radiation receiver (s) (9) are incorporated into a monitoring circuit. 27. Electrical machine according to claim 26, d a -d u r c h g e k e It should be noted that the monitoring circuit has a relay for automatic Switch off the machine (1) when the permissible temperature values are exceeded. 28. Electrical machine according to claim 1 or one of the following, d u r c h e k e n n n z e i c h n e t that the radiation receiver (s) (9) one or more electrical amplifiers, preferably connected in series (16, 18, 19) are connected downstream. 29. Electrical machine according to claim 1 or one of the following, d u r c h e k e n n n z e i c h n e t that the radiation receiver (s) (9) are encapsulated to protect them from firedamp.