DE2556783A1 - Test points switch for multipoint measurements - is used on rotating parts and has magnetically controlled contacts holding after field is removed - Google Patents

Abstract

Contacts (2) rotate together with the tested object. The contacts are holding contacts, i.e. they are opened or closed, depending on the magnetic field polarity, and stay in this state when the field disappears. The contacts pass in front of a stationary electromagnet (3) owing to their rotation, and are opened or closed in accordance with the electromagnet excitation. The contacts (2) consist of reed switches and they are mounted between weakly magnetised pole shoes.

Description

Measuring point switch with magnetically controllable adhesive

Contacts for multi-point measurements Rotating parts The invention relates to measuring point switches that can be used for multi-point measurements on rotating parts, in particular for experimental stress analysis with strain gauges and for measuring temperature distributions with thermocouples on engines, turbines, wheel axles, cement lathes, etc.

The purpose of the measuring point switch is to switch several measuring points one after the other to connect with a common continuing channel.

If you attach the Neßstellenumschalter to the rotating part, so the transmission of the measured values from the object to be measured to the stationary measuring or a single-channel recorder. For revolving changeover switches of this type In many applications, the constraints become more difficult: The building blocks of the Changeover switches must be small, light and robust, they should not cause an imbalance, and they should be reliable even at high temperatures and strong accelerations work. The transfer of the information needed to operate the changeover switch is also problematic possibly necessary supply energy as well as the transmission of control signals, there Galvanic connections to the rotating part are often difficult or not at all can be produced.

According to the current state of the art, one uses for multi-point measurements Mainly the following aids on rotating parts: - Slip ring - Rotary joint [1] - Mercury - rotary transmitter 1, 23 - wireless transmission $ ya to up to 9 Slip ring rotary joint can be compact and with relatively few channels even with a large number of channels Make effort if the shaft end is freely available for assembly, otherwise the production or attachment of the rings is very expensive; other disadvantages are the fluctuations in contact resistance, due to which in connection with strain gauges complex Thomsierungsschaltungen are necessary, furthermore the risk of lifting the brushes at higher speeds, the high wear and consequently the limited Lifespan and the deterioration of the insulation due to the deposition of abrasion.

In contrast, rotary mercury transmitters have a much smaller size Wear and better contact properties; however, they are more complex and voluminous as a slip ring rotary joint. The number of channels is usually limited to a few channels.

Wireless transmission systems are free from rotational wear; however, they practically always require co-rotating electronics; because that of The measurement signals generated by the transducers must be amplified and converted into a NUr die Transfer suitable form. The transformer rotary joint is a special case El), for which no rotating electronics is necessary if it is used for AC-powered passive transducers, e.g. strain gauges, are used; because of the necessary close coupling between rotating and stationary coils and the associated The transformer rotary joint can practically only be used for one or more of the expenditure realize a few channels.

I.a. if such transmission methods are used for wireless transmission systems, in which the "degree of coupling" between the sending and receiving side is practically nonexistent Has an influence on the measurement.

The signals are preferably frequency modulated. The for general Recently preferred pulse code modulation has been due to telemetry applications the relatively high effort and the poor utilization of the HF bandwidth for Measurements on rotating parts not used. The coupling between the transmitter and Receiver can be inductive t33 or capacitive t71 or by means of electromagnetic Waves E4, 83.

I.a. the following components must be used for multi-channel wireless systems rotate with: supply sources for passive transducers, bridge supplements, preamplifiers, Modulators, oscillators, multiplexers and transmission amplifiers. The electronic components must also come from a circulating battery or via an additional energy ¢ transmission path L31 are supplied.

The rotating electronics are often exposed to extreme environmental conditions. Above all, strong temperature fluctuations and excesses are problematic the maximum permissible temperature, the ° ° for electronic components between 70 ° C and 125 ° C.

Most of the circulating electronics are used for multiplication of the measuring channels according to the frequency or time division multiplex method. The frequency division multiplex method requires complete signal processing per channel and one subcarrier oscillator each. Even with the time division multiplex method, each channel usually has its own signal processing be assigned as the electronic multiplexer because of their large through resistances for switching some types of transducers, especially quarter-bridge diaphragm gauges, are unsuitable.

Neßstelle switchers with mechanical contacts have compared to electronic ones Changeover significantly lower contact resistance; they are also suitable for Switchover of non-processed test signals. Therefore one uses with nstationärenn Multi-point measuring devices, preferably mechanical contacts instead of semiconductor switches, unless extremely high sampling rates are required. For measurements on rotating Parts, mechanical contacts could only be used in special cases so far, since the problem of control has not yet been solved satisfactorily.

The actuation of rotating shielding gas contacts by a stationary one Permanent magnets 9 has the disadvantage that the contacts are only in a small one Angular range are closed, so that the observation can be changed quickly and / or Angle-dependent sizes are only possible to a limited extent. For long-term tests at high speed the end of the service life of the contacts is reached quickly.

The invention is based on the problem of the number of measuring channels Easily increase measurements on rotating parts.

This object is achieved in that on the rotating Part of a measuring point switch with magnetically controllable adhesive contacts attached will. During the rotation of the test object, the contacts run on a stationary one Electromagnet over. This is briefly excited when the one just passing by Contact should experience a change of state.

For automatic control of the switching process, after a further embodiment of the invention, the contacts passing by the electromagnet counted automatically. For this purpose there are counting marks on the rotating part and on the stationary part Part corresponding sensors attached; the latter are connected to a counter, which triggers the excitation pulse when a preselected number is reached.

According to a further embodiment of the invention, the circumferential Part of the toggle switch is divided into small, similar building blocks that run along the Circumference of cylindrical bodies can be attached evenly distributed.

Another solution to the same problem is, according to the invention, that to actuate the adhesive contacts instead of a fixed electromagnet a moving system of permanent magnets is used. This pathogen system is relative by means of a gear depending on the angular position of the object to be measured to the contacts moved so that each after rotation through a certain angle the previously closed contact is opened and the next one is closed. The switching process is triggered when the relevant contact approaches a permanent magnet.

The contact is made according to the polarization direction of the magnet placed in the closed or open state.

As a further refinement of this 2nd idea, the movements of the rotating test object on the one hand and the excitation system on the other hand via 2 gears coupled to each other; furthermore, the one to be attached to the shaft of the object to be measured Cogwheel with the attached contacts can be divided into 2 axes.

The advantages achieved by the invention are that the number the measuring channels of rotary transmitters can be multiplied in a simple manner. Of the The measuring point switch can be advantageously used with a mercury rotary transmitter or combine with a transformer rotary transmitter without any co-rotating Electronic components are necessary. In addition, one can use the invention also use simple, single-channel telemetry systems for multi-point measurements. To operate the switch itself, you don't need a circulating battery a special energy transmission path, since the adhesive contacts are outside the short Switching times require energy supply.

A special advantage of the first approach is that that further contacts can be closed without those already closed to open. So it is possible to have a contact to switch a circulating on and off Use battery supply, e.g. if the switch is connected to a single-channel Telemetry system is combined and both the passive transducer and the Transmission electronics must be supplied from the battery; the life of the battery can be extended considerably if it is switched off during measurement phases.

Another advantage of the first-mentioned approach is the possibility the simple attachment to shafts of any diameter without specially made Adapters.

The 2nd solution has the advantage that for the operation of the changeover switch neither on the rotor nor on the stator side any electrical control circuits or power supply facilities are required.

Two embodiments are shown in the drawings and should be described in more detail below. 1 shows the control of the circulating Adhesive contacts by a fixed electromagnet, Fig. 2 the control of the revolving Adhesive contacts through a system of permanent magnets, which by means of gear wheels relative is moved to the contacts.

Magnetically controllable protective gas contacts, so-called reed contacts, are also available as adhesive contacts in stores. The tongue material of these adhesive contacts is a hard magnetic material. A magnetic field impulse in the longitudinal direction of the tongues with a certain minimum duration and minimum amplitude magnetizes the tongues and brings the contact to close. When the external magnetic field disappears, that is enough the field caused the remanence> to keep the contact closed. However, if the field caused by remanence is compensated by an external counter-directed field Field, the contact opens and remains open if the outer field is subsequently disappears; because through the air gap between the tongues is the magnetic flux interrupted and the forces acting on the tongues are small. The one to open However, the pulse used must not exceed a maximum amplitude, otherwise magnetization takes place in the opposite direction and contact is immediately restored would close. The miniaturized version of commercially available adhesive reed contacts with a glass body length of only 15 mm enables a design of the changeover switch, which hardly takes up more space than that of a corresponding electronic switch.

According to FIG. 1, the adhesive contacts are on the shaft 1 of the rotating part 2 evenly distributed along the perimeter.

The contacts move during the rotation of the test object One after the other past an electromagnet 3. To better initiate the magnet field are the ends of the contact tubes including the outer tongue connections embedded in soft magnetic pole shoes 4. To avoid a magnetic short circuit of the To prevent both pole pieces from being in the vicinity of shaft 1 is between the shaft on the one hand and the pole pieces on the other hand a magnetically poorly conductive Intermediate layer 5 attached, which also serves as a mounting base. On the wave 1, counting marks 6 are attached in 2 tracks at the level of the contacts. In the There is only a single mark on a trace, indicating the location of that contact at which counting should start.

In the other lane, a label is assigned to each additional contact. The marks are scanned by 2 sensors 7. When passing the individual brands a counter 8 is preset to a value that corresponds to the number of the one to be actuated Contact. After that, in the other track, one corresponding to the preset Number of marks has passed, the counter issues a transmission message. If there is a command to close or open the preselected contact, it will the carry forward passed through a gate circuit to an amplifier, the one corresponding current pulse in one of the two oppositely arranged windings of the electromagnet 3 generated.

In Fig. 2, the adhesive contacts 2 are in the bores of a gear 9 arranged evenly distributed along the circumference.

The gear wheel sits on the shaft 1 of the rotating part, it can be dismantled in 2 halves to enable attachment even if the shaft end is inaccessible is. In the example shown in Fig. 2, it is a gear with 20 teeth and lo adhesive contacts. With the gear 9 there is another gear lo in engagement; the latter has 22 teeth. Two of these 22 teeth are axially parallel Bores in which rod-shaped permanent magnets 11 with mutually opposite directions Polarity and different strength. The distance between the magnets corresponds to the grid in which the contacts are arranged. In the case of the one entered in FIG The direction of rotation is initially the previously closed contact by approaching the weaker one of the two magnets open. After about a tenth of a turn of the test object the next contact is closed by approaching the stronger magnet and remains closed for about a full turn.

In this case, the indexing takes place after 11 / lo Revolutions. Instead of the arrangement of 2 gears shown in FIG a combination of gears and toothed belts can also be used.

Considered literature 1 Rohrbach, Chr .: Handbook for electrical measuring mechanical quantities, Chapter E 5, VDI-Verlag Düsseldorf 1967 2 Rohrbach> Chr .: Possibilities for measuring moving parts, VDI reports No. 144, 1970, 5. 5-11 3 Messgeräte-Katalog 75, Fa. Philips, p. 324-334 4 Donato, V. and S.P.Davis: Radio Telemetry for Strain Measurements in Turbins, Sound and Vibration, Vol. 7 (1973)> 5. 28-34 5 Valentich, J .: Radio Telemetry in Experimental Stress Analysis, Experimental Mechanics, Dec. 1971, pp. 569-576 6 Pratt, A.J.S .: Telemetry of Engine Rotor Test Data, 2nd International Symposium on air breathing engines, Sheffield 1971 7 prospectus from Aerotherm, Mountain View, Calif .: Wireless Data Couplers, 1972 8 N.N .: Telemetry - the bridge from the measuring point to the measuring point, Elektronik-Zeitung, September 5, 1975 pp. 8-22 9 Gerresheim, M .: Measurement method for determining temperatures in rolling tires, ATM (1973)> No. 1, p.7-lo

Claims (9)

Claims 1. Measuring point switch for multi-point measurements on rotating parts (1) with magnetically controllable contacts (2), which with the Rotate measurement object, characterized in that the contacts 41s are made with adhesive contacts are, i.e. åe according to the polarity of the magnetic field in the closed or open State and remain in it when the field disappears, furthermore characterized by a fixed electromagnet (3) on which the contacts as a result of the rotation moved past in sequence and according to the excitation of the Electromagnets are closed or opened. 2. measuring point switch according to claim 1, characterized in that on the rotating part (1) counting marks (6) and on the stationary part on them Counting mark responsive sensors (7) are attached, further characterized in that that the sensors are connected to a counting circuit (8), the excitation of the Electromagnet controls. 3. Measure point switch according to claim 1, characterized in that the part of the switch to be attached to the test object or its shaft is divided is divided into several similar building blocks running along the circumference of cylindrical Bodies can be attached evenly distributed. 4. measuring point switch according to claim 1, characterized by a two-pole or multi-pole structure, two or more contacts being arranged adjacent to each other and are operated at the same time 5. Measuring point switch for multi-point measurements on rotating parts (1) with magnetically controllable contacts (2), which with the Rotate measurement object, characterized in that the contacts are designed as adhesive contacts are, further characterized by permanent magnets (11), which by means of gears in Addiction of the angular position of the measurement object relative to the Contacts are moved and thereby cause the contacts to close and open. 6. measuring point switch according to claim 5, characterized by 2 into each other engaging gears, namely one attached to the test object or its shaft (1) Gear (9) with holes made along the circumference to accommodate the Contacts (2) and another gear (lo) with holes to accommodate rod-shaped Permanent magnets (11). 7. measuring point switch according to claim 5, but in contrast to claim 6 characterized in that the permanent magnets (11) are not attached to a gear wheel (lo), but are attached to a toothed belt, which is attached to a measuring object (1) Gear (9), on which the contacts (2) are attached, engages. 8. measuring point switch according to claim 6 and 7, characterized in that that the gear (9) to be attached to the test object or its shaft (1) in 2 halves can be dismantled. 9. measuring point switch according to claim 5, characterized by a two-pole or multi-pole structure, with two or more contacts arranged adjacent to each other and are operated at the same time.