DE10040601A1 - Electrical plug connector has contact(s) associated with monitoring temperature sensor directly contact by contact or mounted in metal block in surface contact with contact element - Google Patents

Abstract

The connector has a housing with several holders extending in the longitudinal direction with contacts (64,66,68,70,72) designed to accept contact pins, e.g. aircraft contact pins, at their free outer ends. At least one contact is associated with a monitoring sensor (82,84) in the form of a temperature sensor directly contact by the contact or mounted in a metal block in surface contact with a contact element.

Description

The invention relates to a connector, in particular intended for on-board power Aircraft supply, comprising a housing with several in the longitudinal direction extending receptacles with cylindrical contact elements arranged in them, the bushing or sleeve-shaped in their free outer ends for making contact pins are formed, with at least one of the contact elements monitoring sensor is assigned.

A corresponding connector can be found in EP 0 966 068 A1. With a corresponding connector, an on-board power supply for aircraft is possible, whereby the connector can be inserted into an on-board connector receptacle that Contains contact pins. Via the connector or the cables connected to it 200 V or 115 V / 400 Hz supply voltage and DC voltage are preferred (28 V) for feedback. In the known connector, a Pilot contact can be provided, which includes a microswitch to check whether in the socket or sleeve-shaped ends of the contact elements of the connector in sufficient plug connector of an aircraft is introduced, whether that corresponding contact pins emanating from the connector receptacle from the contact elements ten of the connector are included.  

Corresponding pilot contacts enable extensive monitoring of whether the Connector is properly inserted, but cannot completely rule out that inadmissible heating and possibly scorching of the connector then occurs if there is no intimate contact between the connector receptacle and the connector is present. In other words, even if the pilot contact indicates that a There is a proper connection due to an error that cannot be recognized from the outside the plug connector or the plug receptacle may not heat up properly. The latter is to be avoided in particular, since otherwise an exchange is necessary, with the result that that the corresponding aircraft is not ready for use for a long time.

The present invention is based on the problem of a connector at the beginning to continue training in such a way that it is ensured that it does not heat up inadmissibly is and if necessary, the connector is switched off when one is closed a risk-causing heating occurs.

According to the invention, the problem is essentially solved in that the monitoring A temperature sensor is at least partially flat on the outside he along the contact element in the region of its socket or sleeve-shaped end stretches. The temperature sensor is in particular a PTC thermistor like PTC or NTC resistance or resistance thermometer.

A corresponding temperature sensor shows an increase in resistance when heated. If a temperature sensor with a linear characteristic, i.e. H. steady increase in resistance acts with increasing temperature, the change in resistance to control and regulation be used for purposes. It is particularly provided that switch contacts one of the Circuit containing temperature sensor are floating. About corresponding potential Free contacts can then a ge depending on the choice of the circuit temperature controller the desired value can be programmed, which, for example, triggers an alarm or the Power supply through the connector interrupts.

An alarm trigger can be recognized by the fact that e.g. B. a beacon on  Suspension of a passenger boarding bridge is put into operation.

A corresponding temperature sensor is, in particular, a sensor Platinum base like PT-100, PT-500 or PT-1000 sensor. This can be used as a thin disc sensor, Glass sensor or ceramic sensor can be formed, platinum applied to a carrier like sputtered or z. B. can be wrapped around it in the form of a wire.

There is also the possibility of a PTC resistor or PTC resistor, that is, a semiconductor sensor consisting of a semiconducting and ferroelectric material such as. B. to use barium nitrate. A corresponding PTC thermistor exhibits an exponential increase in resistance in a narrow temperature range. The sudden change in resistance can be used for switching purposes or for generating signals. For example, a sensor can be selected such that a signal is generated at a temperature T ₁ with 130 ° C 1 T ₁ ≦ 170 ° C, in particular T ₁ in approximately 150 ° C of the contact element in surface contact with the temperature sensor, by a Trigger alarm such as visual and acoustic alarm. With another suitable sensor, a signal can be generated at a temperature T ₂ with 170 ° C ≦ T ₂ ≦ 210 ° C, in particular 12 in about 190 ° C of the contact element with the temperature sensor in flat contact to z. B. to disconnect the connector.

In a development of the invention it is provided that the sensor is in contact with the contact element in flat contact with a metal block made of good heat-conducting Material such as brass or aluminum is arranged. The metal block in the Section in particular a trapezoidal shape with one lying flat on the contact element concave surface.

In the metal block, the sensor is electrically isolated, but it is a good conductor of heat, e.g. B. means an adhesive fixed, the connections of the sensor are connected with cables that are connected to the metal block with strain relief. The sensor itself should be a test chip voltage resistance up to 4 kV.  

Preferably, the contact elements themselves assume the use of a bowl trained housing releasably, the use of each other in particular webs connected hollow cylindrical sections for receiving the cylindrical contact elements includes. The sensor or the metal block then extends in a section of a one of the hollow cylindrical section surrounding the contact elements and in particular goes from its front edge. The sensor or the metal block can jam be taken up by the hollow cylindrical portion of the insert and in the direction of the contact element for flat contact with this force. this will supported by the trapezoidal shape.

Detached from this, the sensor or metal body should be exchangeable or reusable can be arranged in the application.

Further details, advantages and features of the invention result not only from the Claims, the features to be extracted from these - individually and / or in combination -, but also from the following description of one of the drawings preferred embodiment.

Show it:

Fig. 1 shows a section through an embodiment of a connector,

Fig. 2 shows a cross section through a housing front part with a preferred embodiment form of a connector,

Fig. 3 shows a section along the line AA in Fig. 2 and

Fig. 4 shows a cross section through a temperature sensor.

In Fig. 1, a connector 10 is shown purely in principle and in section, as this z. B. is described in EP 0 966 068 A1. In this respect, express reference is made to the disclosure in this regard.

The connector 10 is particularly intended for aircraft power supply devices which are intended for 28 V = / 200 V or 112 V / 400 Hz on-board power supply for aircraft. The connector 10 or also called plug has a housing which is composed of a housing front part 14 and a housing rear part 16 , which can be detached via z. B. screws are connected. The front housing part 14 is bowl-shaped and has an outer shell 15 of hollow cuboid geometry and an insert 18 , the 24 and 26 , 28 , 30 , 32 consists of hollow cylindrical first and second connections connected via webs 20 , 22 .

The internal hollow cylindrical receptacles 30 , 32 are penetrated by screws, not shown, through which the front housing part 14 is connected to the rear housing part 16 . Within the outer and, in the exemplary embodiment, six further hollow cylindrical receptacles 24 , 26 , 28 , cylindrical contact elements 34 , 36 , 38 can be used, the book-like or sleeve-like receptacles 42, 44 46 accessible in their free end from the end face 40 of the front housing part 14 have in order to be able to insert plug pins of a connector receptacle emanating from an aircraft. End, that the contact pins 34, 36, 38 in turn connected to outgoing from the rear housing part 16 second contact elements are connectable to the housing rear side extend which are connected to molded in the Gehäuser ückteil 16 cable. In this respect, however, reference is made to the disclosure content of EP 0 966 068 A1 or EP 0 235 923 A2.

In the exemplary embodiment in FIG. 1, the contact pin 38 has a pilot contact 48 , via which it can be checked whether a contact pin of a plug receptacle protrudes sufficiently into the front receptacle 46 of the contact element 38 , that is to say whether there is an electrically conductive connection, so that current flow or signals can be transmitted. In order to additionally ensure that the contact pins 34 , 36 , 38 are not heated to an inadmissible extent, a temperature sensor 50 is provided which, in the exemplary embodiment in FIG. 1, extends in the front end region of the contact pin 36 and lies flat against its outer surface.

The temperature sensor 50 comprises a temperature sensor 52 , which can be a semiconductor sensor (PTC or NTC sensor) or one whose resistance characteristic is that of a resistance thermometer such as PT sensors such as PT-100, PT-500 or Corresponds to PT-1000.

The semiconductor sensor is preferably a PTC thermistor which consists of a semiconducting and ferroelectric material such. B. there is barium titanate. In the cold Condition, the resistance is relatively low and shows the negative temperature coefficient the heating conductor. Above a temperature dependent on the composition of matter, the Curie temperature, the previously uniform orientation of the individual crystallites dissolves. In a narrow temperature range, this leads to an exponential increase in Resistance, to a high positive temperature coefficient. This sudden contradiction Change in position can be used to trigger switching signals.

A resistance thermometer sensor, on the other hand, has a linear characteristic between tempera structure and change in resistance. This characteristic can be used to switch generate gnale that z. B. forwarded to a monitoring station. In Ab Depending on reaching certain temperature values, signals like acoustic or optical signals are triggered or when an impermissibly high temperature is reached to switch the connector stormless.

The resistance thermometer sensor is in particular one of these Platinum-based. Thin-film sensors, glass sensors or ceramic sensors can be used Sensors arrive. Platinum is then applied to the appropriate supports sputtered on or the carrier is wrapped with a plantin wire. The connections are connected with cables that lead to a switching or control device.  

The sensor 52 itself extends in a metal block made of a good heat-conducting material. Brass or aluminum should preferably be mentioned.

The sensor 50 consisting of the sensor 52 and the metal block 54 has a cuboid shape with a concave boundary surface 56 , over which the sensor 50 lies flat against the outer surface of the contact element 36 in order to ensure a desired heat transfer. Connections proceeding from the sensor 52 then lead (not shown) to a controller in order to enable either a step-by-step or continuous temperature monitoring depending on the type of sensor (PTC, NTC, PT sensor).

With a resistance thermometer sensor such as PT-100, PT-500, PT-1000 sensors, in particular, continuous temperature monitoring or on potential-free contacts of the control or on a temperature control can be programmed to carry out desired values in order to carry out monitoring. When certain temperatures are reached, for. B. an acoustic signal such as horn or an optical signal such as rotating beacon can be activated. At a temperature at which there is a risk that the contact elements and thus the extending therein and from the connector receiving pins are damaged, the connector 10 can be switched off.

It is also easily possible to specify a temperature value through the choice of material for a PTC sensor in order to use z. B. at a tempera ture that can be between 130 and 170 ° C, especially at 150 ° C to trigger an alarm. With a sensor of different material composition z. B. at a further temperature, which is between 170 and 210 ° C, in particular at 190 ° C, the connector 10 are switched off. The electrical circuit comprising the sensor 52 or the temperature sensor 50 can also be connected to a control center in order to carry out central monitoring.

As can be seen from the sectional view according to FIG. 2, the temperature sensor 50 or the metal body 54 passes through the hollow cylindrical receptacle 24 for the contact element 34 , that is to say the web-like wall 58 thereof, and is received by it in a clamping manner. The metal body 54 is subjected to a force in the direction of the contact element 36 in order to ensure the desired two-dimensional contact and thus heat transfer. For this purpose, the metal body has a trapezoidal shape in section, as can be seen from FIG. 4.

The temperature sensor 50 is exchangeably arranged in the connector 10 , that is to say in the insert 18 , in order to be reused. It is also clear from the illustration in FIG. 1 that the temperature sensor 50 stretches in the region of the contact element 36 in which a contact pin (not shown) can be inserted, that is to say in the region of the socket-shaped or sleeve-shaped free end 44 of the cylindrical contact element 36 .

The sensor 52 itself is arranged in the thermally conductive contact in the metal body 54 . For this purpose, a good heat-conducting paste is used, which is provided between the sensor 52 and the inner wall of the bore in the metal body 54 . The connections of the sensor 52 are then connected with cables which lead to a switching device or to a controller. The cables themselves are fastened in the metal body 54 with strain relief.

Furthermore, the sensor 52 should have a test voltage strength of up to 4 kV against ground.

The sensor 52 itself can be integrated in circuits or controls, as can be seen from the prior art. So z. B. the resistance values of a sensor 52 designed as a resistance thermometer are passed 1: 1 to a control center for further processing and processed directly in a computer. There is also the option of supplying resistance values to a transmitter so that the output currents (e.g. 4 to 20 mA) can be easily transmitted over longer distances. An evaluation can then take place in a control center. The temperature controller can also have an interface such as an RS 485 interface, via which the connection to a control center is made. Corresponding control solutions, however, can be found sufficiently in the prior art.

Claims (24)

1. Connector ( 10 ), in particular for on-board power supply for aircraft, to comprehensively include a housing with a plurality of in the longitudinal direction extending on ( 24 , 26 , 28 ) with contact elements arranged in this ( 34 , 36 , 38 ) in their free outer ends ( 42 , 44 , 46 ) are bush or sleeve-shaped for receiving contact pins, with at least one of the contact elements being assigned a monitoring sensor ( 48 , 50 ), characterized in that the monitoring sensor is a temperature sensor ( 52 ) that is extends at least in sections along the outside along the contact element ( 36 ). 2. Connector according to claim 1, characterized in that the temperature sensor ( 50 ) has a sensor ( 52 ) with a linear temperature resistance characteristic or with an exponentially increasing characteristic. 3. Connector according to claim 1 or 2, characterized in that the sensor ( 52 ) is a PTC or NTC resistance sensor. 4. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) is a resistance thermometer, in particular based on platinum. 5. Connector according to at least one of the preceding claims, characterized in that the temperature-sensing switching contacts of a circuit containing the sensor ( 52 ) are potential-free. 6. Connector according to at least one of the preceding claims, characterized, that signals can be generated via the circuit depending on the temperature. 7. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) is a semiconductor sensor with an exponentially changing resistance and a signal at a temperature in the range from 130 ° C to 170 ° C, in particular at about 150 ° C of the contact element ( 36 ), which is in flat contact with the temperature sensor ( 50 ), triggers an acoustic or visual alarm in particular. 8. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) is a semiconductor sensor with an exponentially changing resistance and a signal at a temperature in the range from 170 ° C to 210 ° C, in particular at about 190 ° C of the contact element ( 36 ) of the connector ( 10 ), which is in flat contact with the temperature sensor ( 50 ), switches off. 9. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) is a resistance thermometer sensor, by means of which the pre-continuous temperature monitoring takes place. 10. Connector according to at least one of the preceding claims, characterized in that the temperature sensor ( 52 ) is arranged in a metal block ( 54 ) located in flat contact with the contact element ( 36 ). 11. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) consists of a good heat-conducting material such as brass or aluminum. 12. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) is a thin-film sensor. 13. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) has a carrier made of glass or ceramic material, applied to the platinum as sputtered or wound around the platinum wire. 14. Connector according to at least one of the preceding claims, characterized, that connections of the sensor or cables connected to them are strain-relieved in the Metal block are fixed. 15. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) is arranged in a bore in the metal block ( 54 ) and is embedded in a thermal paste. 16. Connector according to at least one of the preceding claims, characterized in that the sensor ( 52 ) has a test voltage strength up to 4 kV. 17. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) has a cuboid shape with a concave surface ( 56 ) lying flat against the contact element ( 36 ). 18. Connector according to at least one of the preceding claims, characterized in that the contact elements ( 34 , 36 , 38 ) of an insert ( 18 ) of the shell-shaped housing ( 15 ) of the connector ( 10 ) are accommodated, the insert via in particular webs ( 22 ) interconnected hollow cylindrical sections ( 24 , 26 , 28 ) for receiving the contact elements. 19. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) passes through a section of a hollow cylindrical portion of the insert ( 18 ) surrounding the contact pin ( 36 ). 20. Connector according to at least one of the preceding claims, characterized in that the cutout penetrated by the metal block ( 54 ) extends from the end edge of the insert ( 18 ) or extends in the region thereof. 21. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) is subjected to force in the direction of the contact element ( 36 ) for flat contact with the latter. 22. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) is received in a clamping manner by the insert ( 18 ) of the shell-shaped housing ( 14 ). 23. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) or the sensor ( 52 ) is arranged interchangeably or reusably in the connector ( 10 ). 24. Connector according to at least one of the preceding claims, characterized in that the metal block ( 54 ) has a trapezoidal shape in section, the larger base surface of which is the concave surface ( 56 ).