DE4417009C1 - Non contact monitor for a heated roller - Google Patents

Abstract

The appts. for a non-contact measurement acquisition for a roller on a hollow shaft, especially a heated floating roller at a fixed machine section, has at least one temp. sensor (1) in the mantle (1) of the roller (2) and a converter circuit (13) rotating with the roller to generate a signal for the temp. A cable connection (18) is through the hollow shaft (6) to the rotating section (10) of a non-contact transfer unit (7) for the measured values. A fixed section (9) of the transfer unit (7) is connected to a display and/or control for the roller temp. The rotor (10,13) of the transfer unit (7) is at the free end (12) of a protective tube (11) through the hollow shaft (6) and the temp. sensor (3) is at the other end (19) of the protective tube (11). The cable connection (18) between the temp. sensor(s) (3) and the rotor runs through the protective tube (11). The protective tube (11), together with the rotor (10,13) is inserted into the hollow shaft (6) at the end side (17) away from the roller (2) sufficiently for the rotor (10,13) to enter into the stator (9) of the measured value transfer unit (7).

Description

The invention relates to a device for contactless transmission of measured values from one to one Hollow shaft attached role, e.g. B. a heating godet, on a fixed machine part. At a DE-B 16 15 453 known device of this type carries with a temperature sensor equipped godet a resonant circuit connected to the temperature sensor, which generates a signal with temperature-dependent frequency. This is through the hollow shaft of the Galette-extending lines are fed to the rotor of a coaxial capacitor, the rotor of which non-contact enclosing stator to a control device for the stationary Induction heater of the godet is connected. The sits on the end of the hollow shaft Rotor of a rotary transformer, its stator for the energy supply of the resonant circuit is fed with alternating current. In the hollow shaft is adjacent to the rotor of the rotary transformer a rectifier is used which converts the transmitted AC voltage into a DC voltage Derives power supply of the resonant circuit. The power supply line runs also through the hollow shaft. Different embodiments of rotating transducers are known from DE-B 16 15 431.

DE-C 29 37 656 shows a device of the type mentioned, in which the central Pin of the hub carrying the godet casing and connecting it to the motor shaft protrudes the entire godet. A cavity extends from the front of the hub to to the attachment part of the hub sitting on the motor shaft. In this cylindrical cavity surrounds a coaxial protective tube that otherwise runs through the hollow motor shaft Connection cables for the temperature sensors.

In a godet known from DE-A 19 48 618 there is between the guided through the hollow shaft Connection lines on the one hand and the connecting lines carried by the hub to the in Temperature sensors located on the godet, on the other hand, have a detachable plug connection provided to remove the godet from the godet for repair or maintenance purposes To enable the drive shaft. This connector is in a to the front of the The opening of the godet, closed by a lid of the central holding pin of the Hub.

DE-C 38 30 384 describes a device for contactless measured value transmission, in which a only a stationary and a rotating winding having transducer both for Energy transfer to the rotating part, to transfer the measurement signal to the stator as also for the transmission of synchronizing signals for the scanning of several on the godet located temperature sensor is used.

The invention characterized in claim 1 discloses a measured value transmission device which is characterized by a particularly simple, clear and compact structure, easy to assemble and disassemble in case of repair and good mechanical protection their electronic components. The rotor of the Transmitter, the electronic converter circuit and also the sensor to one Unit can be summarized. The protective tube is from the free end of the godet inserted into the hollow shaft and connected to the hollow shaft. For any repairs to this Components or for their replacement do not need the end of the hollow shaft facing away from the godet to be accessible.

Advantageous refinements and developments of the invention are in the subclaims described. It is shown below with reference to the drawings Exemplary embodiments explained. Only the parts essential to understanding the invention Galette are shown. It shows

Fig. 1 shows schematically a longitudinal section through godet, hollow shaft and the measured value transmitter,

Fig. 2 in a similar representation, an embodiment in which the sensors can be electrically and mechanically separated from the connecting lines, and

Fig. 3 on an enlarged scale, the end remote from the godet of a divided protective tube with the rotating part of the transducer.

In the jacket 1 of the heated godet 2 , a plurality of temperature sensors 3 are inserted, which measure the temperature at various points on the godet. In the interior 4 of the godet is a stationary induction heating device, not shown. The godet sits with its hub 5 on the end of a hollow shaft 6 , which is preferably overhung in the machine frame (not shown) and is driven by an electric motor (also not shown).

A measured value transmitter 7 , consisting of a stator 9 carried by the machine frame 8 and a rotor 10 rotating with the hollow shaft 6, is used to transmit the measurement signals generated by the temperature sensors 3 to a stationary control device for the induction heater. A protective tube 11 made of steel is inserted into the hollow shaft 6 , the end part 12 remote from the godet accommodates an electronic component, for example in the form of an electronic circuit board 13 , which converts the measurement signals into signals suitable for inductive transmission via the measurement value transmitter 7 . A circuit board 14 in the stator 9 of the measured value transmitter 7 carries an electronic evaluation circuit for the transmitted signals and controls the stationary induction heater which is also carried by the machine frame. An example of such a converter circuit is described in the above-mentioned DE-C 38 30 384. The circuit board 14 of the evaluation circuit is connected via a cable 15 to a controller for the induction heater.

The temperature sensors 3 are mechanically connected to the protective tube 11 and electrically to the module 13 so that an assembly is formed which comprises all the rotating parts of the measured value transmitter serving for the transmission of measured values, i.e. the sensors 3 , the converter circuit 13 and the rotor coil 10 , and as such Assembly can be inserted into the hollow shaft 6 from the end face 17 of the godet 2 . The protective tube 11 together with a support 16 for the temperature sensors 3 is inserted into the hollow shaft 6 until the rotor coil 10 projects properly into the stator 9 . The connecting lines 18 between the temperature sensors 3 and the electronic module 13 run in the protective tube 11 and are protected by this. The electronic module 13 or its printed circuit board also serves as a holder for the rotor coil 10 . The mechanical connection of the temperature sensors 3 to the protective tube 11 is supported by the carrier 16 , which is fastened to the end 19 of the protective tube 11 remote from the frame or is formed integrally therewith.

For any repairs to the resistance temperature sensors 3 , the printed circuit board 13 or the rotor 10 , the entire assembly 3 , 10 , 11 , 13 , 16 is pulled out of the hollow shaft 6 as a unit and replaced if necessary. For this purpose, the end of the hollow shaft 6, which is far from the godet 2 and carries the rotor 10 and is usually difficult to access within the yarn treatment machine, need not be exposed. The end face 17 of the godet 2, on the other hand, is located outside the machine and can be reached quickly and easily.

The embodiment shown in Fig. 2 has between the connecting lines 18 and the connecting lines of the temperature sensor 3 on the support 16 provided connecting devices 23 , z. B. screw terminals, which allow an exchange of the sensor 3 , without this the entire assembly 3 , 13 , 10 must be pulled out as a unit from the hollow shaft 6 . The temperature sensors 3 and the connecting lines 18 are therefore connected to one another in an electrically and mechanically detachable manner via the connecting terminals 23 fastened to the carrier 16 .

A further simplification of the disassembly and repair of the measured value transmission device is shown in the partial drawing in FIG. 3. Here, the protective tube 11 at the end remote from the godet is divided into two parts 11 A and 11 B which can be screwed together by a thread 20 . Part 11 B is only partially shown. It continues to the right in the same way as the undivided protective tube 11 in FIG. 1. The left part 11 A of the protective tube receives the electronic component 13 A, from which a printed circuit board 13 B protrudes on the right side. This serves as a connection area for the connecting wires 18 , which are soldered there, for example, to conductor tracks provided on the printed circuit board 13 B. The part 13 C of the circuit board to the left of the electronic component 13 A or an attachment of the electronic component 13 A forms a holder for a coil carrier 10 A of the rotor coil 10 B. When protective tube parts 11 A and 11 B are screwed apart, the connection point of the connecting wires 18 on the circuit board 13 B accessible so that you can unsolder and either the rotor 10 , 13 or the temperature sensor 3 together with the connecting wires 18 can be replaced independently. This further simplifies and simplifies the maintenance and repair of the measured value transmitter, and only those parts need be replaced which are actually defective.

The measured value transmitter can not only serve for the transmission of temperature signals but also as part of a speed measuring device. For this purpose, a magnet 22 is inserted into the end wall 21 of the coil carrier 10 A, which is connected to a stationary sensor, not shown, for. B. an induction coil, works together and generates a frequency-dependent pulse train in frequency.

The invention is not only for heated but also for cooled or other treatment, for example, drawing or texturing rolls of yarn or thread Advantage applicable.

Claims (9)

1. Device for the contactless transmission of measured values from a roller attached to a hollow shaft, in particular a heating godet, to a stationary machine part

• a) at least one temperature sensor ( 3 ) in the jacket ( 1 ) of the roller ( 2 );
• b) a converter circuit ( 13 ) rotating with the roller and producing a temperature-dependent measurement signal;
• c) a line connection ( 18 ) extending through the hollow shaft ( 6 ) to the rotating part ( 10 ) of a contactless measured value transmitter ( 7 ); such as
• d) a fixed part ( 9 ) of the measured value transmitter ( 7 ) which can be connected to a device for displaying and / or regulating the roll temperature; in which
• e) the rotor ( 10 , 13 ) of the measured value transmitter ( 7 ) is attached to the free end ( 12 ) of a protective tube ( 11 ) passing through the hollow shaft ( 6 );
• f) the one or more temperature sensors ( 3 ) are provided at the other end ( 19 ) of the protective tube ( 11 );
• g) the line connection ( 18 ) between the temperature sensors ( 3 ) and the rotor runs through the protective tube ( 11 ) and
• h) the protective tube ( 11 ) together with the rotor ( 10 , 13 ) can be pushed into the hollow shaft ( 6 ) from the end face ( 17 ) of the roller ( 2 ) until the rotor ( 10 , 13 ) into the stator ( 9 ) of the measured value transmitter ( 7 ).

2. Device according to claim 1, characterized in that the temperature sensor ( 3 ), protective tube ( 11 ) and rotor ( 10 , 13 ) form a single structural unit. 3. Apparatus according to claim 2, characterized in that a plurality of temperature sensors ( 3 ) are attached to a support ( 16 ) held by the protective tube ( 11 ). 4. The device according to claim 3, characterized in that the temperature sensors ( 3 ) are electrically and mechanically detachably attached to the carrier ( 16 ). 5. Device according to one of claims 1 to 4, characterized in that an electronic component ( 13 ) containing the converter circuit is held in a part ( 12 ) of the protective tube ( 11 ) adjacent to the rotor ( 10 ). 6. The device according to claim 5, characterized in that a circuit board ( 13 A, B, C) of the electronic module ( 13 ) on one side ( 13 C) in a coil carrier ( 10 A) of the rotor ( 10 , 13 ) protrudes and on the other side ( 13 B) is designed as a connection area for the connecting lines ( 18 ) to the temperature sensors ( 3 ). 7. Device according to one of claims 1 to 6, characterized in that the protective tube ( 11 ) is divided and the two protective tube parts ( 11 A, 11 B) are provided with a thread ( 20 ) and screwed together. 8. The device according to claim 7, characterized in that when the protective tube parts are screwed apart ( 11 A, 11 B), the connection region of the connecting lines ( 18 ) on the electronic module ( 13 ) or on the printed circuit board ( 13 B) is accessible. 9. Device according to one of claims 1 to 8, characterized in that a magnet ( 22 ) serving as a speed sensor is arranged on the rotor ( 10 , 13 ), preferably on its end face ( 21 ).