DE102007010589A1 - Pressure measurement transducer for use as field device of process instruments, has channels, where length and diameter of channels are guided by boring such that it forms ignition breakdown protection section between two parts - Google Patents

Abstract

The pressure measurement transducer has a process connection that is provided for supplying a pressure for measuring. The process connection has a measuring chamber, which is charged with a pressure transmission unit and is separated from the process medium by a separated membrane. The length and the diameter of the channels (21) are guided by boring in such a manner that it forms an ignition breakdown protection section between both parts (5) of the measuring chamber without other measurements.

Description

The The invention relates to a pressure transmitter for use as field instrument of process instrumentation, the one process connection for supplying a pressure to be measured according to the generic term of claim 1.

Such a process connection is already known from pressure transmitters of the SITRANS P DSIII series from Siemens AG. To clarify the state of the art is in 2 a sensor with the known process connection shown. The process connection is designed in two parts for manufacturing reasons and consists of a sensor holder 1 and a flange receptacle 2 containing a measuring chamber filled with a pressure transmitting means, for example silicone oil. A first part 3 the measuring chamber is located under a separating membrane 4 which, in the installed state of the process connection, separates the pressure transmission medium from the process medium whose pressure is to be measured. A second part 5 the measuring chamber, in which a pressure-sensitive sensor 6 is located in the sensor receptacle 1 , A reference pressure is the back of the sensor 6 through a pipeline 7 fed. Other parts of the pressure transducer, such as an evaluation, which is often referred to as a transmitter, or a transmitter housing, are not shown for clarity. The sensor holder 1 and the flange receptacle 2 are through a welded joint 8th hermetically sealed together. As a transport protection is the separation membrane 4 through a dust cap 9 covered, which is removed prior to attachment of a mounting flange, which is also not shown in the drawing. After removing the cap 9 lies an external thread 10 free of the process connection to which the external thread 10 and a stop 11 adapted flanges of different diameters can be screwed on, leaving the separation membrane 4 for example, flush with the front of the flange flush. The first part 3 the measuring chamber is with the second part 5 via a channel filled with pressure transfer means 12 connected.

When using the pressure transmitter in potentially explosive areas, cable bushings, such as the duct 12 , so-called ignition or flame arrestors, which prevent the transmission of the flame through the conduit out of the device in the event of ignition of a gas within the device. In conventional ignition locks the realization is exploited that flames lose energy when passing through narrow channels and are no longer reactive, thus be extinguished. The extinction of the flames is achieved by intimate contact of the flame with the cooling walls of the channels and pressure drop.

To realize a flameproof route is the channel 12 with a hole 13 with 4 mm diameter at its the second part 5 provided the measuring chamber facing side, which has a length of about 10 mm. In this hole 13 is a stopper 14 made of stealite, the length of 6.1 mm and a central recess 15 with 0.3 mm diameter. The recess 15 is by shaping during sintering of the plug 14 created. The stopper 14 acts due to its narrow recess 15 as a flashback safe route. A disadvantage of this design is the high, filled with pressure transfer medium volume in the remaining free hole 13 in front of and behind the stopper 14 , In the case of temperature changes, deviations of the expansion coefficients of the pressure-transmitting means and of the material steel, from which the process connection is made, lead to a volume shift and thus to a change in the position of the separating membrane 4 , Due to the elastic properties of the separation membrane 4 this causes a change in the pressure in the measuring chamber and thus a measurement error of the pressure transmitter. Another disadvantage is the high production cost, the production of the bore 13 , the pressing of the plug 14 as well as the stopper 14 even as an additional required component cause.

Of the Invention is based on the object, a pressure transducer for Use as field device to create process instrumentation that compares with a low production costs and at the same time characterized by improved measurement accuracy.

to solution this task, the new pressure transducer of the aforementioned Type specified in the characterizing part of claim 1 features on. In the dependent claims Advantageous developments of the invention are described.

The invention has the advantage that an ignition-puncture-proof path with the aid of the channel between the two parts of the measuring chamber is already achieved, without a larger diameter bore having to be introduced into the channel and pressed with a plug to realize the ignition-puncture-proof path. This eliminates the disturbing, filled with pressure transfer medium volumes before and after the plug, which previously increased the measuring chamber volume disadvantageously. With the reduced volume of the measuring chamber, a higher measuring accuracy of the pressure transducer can be achieved in an advantageous manner, since temperature fluctuations are clotting gere displacement of Trennmembranlage and thus cause a lower measurement error.

The Invention is based on the recognition that it is with the modern method the spark erosive pipe possible is, retrospectively in a body made of steel to introduce a channel during the production of the process connection, its length and its diameter is carried out in this way are that he is a flameproof Distance forms. This condition is already met with a channel that is at least 6.3 mm long and its maximum diameter is 0.35 mm is. Such a bore was with a conventional chip removing drilling method not producible.

With The method of spark erosion pipe are in an advantageous manner Holes of very high dimensional accuracy and very small diameter possible. The as ignition-proof Route serving small bore advantageously has a diameter of 0.3 mm and is made by spark erosive drilling of the channel at his the second part of the measuring chamber facing side over a length of 7 mm made. This is the ignition-proof route directly at the housing interior the pressure transmitter facing channel side. This page is also for the production of the fine bore with a spark erosion machine, for example, the type K1BL Sodik, easily accessible. Spark erosion is a thermal, abrasive manufacturing process for conductive materials, that on electrical discharges (Spark) between an electrode (tool) and the conductive workpiece (process connection) based. The processing takes place in oil as a non-conductive medium (Dielectric) instead. A large The advantage of spark erosive machining is the very high dimensional accuracy and their suitability for hard materials, such as steel.

Based on the in 1 illustrated embodiment of the invention, the invention and refinements and advantages are explained in more detail below.

1 shows a new sensor recording, 2 a process connection with a sensor receptacle according to the prior art.

In The figures are the same parts with the same reference numerals.

The execution of a known from the prior art process connection of a pressure transmitter for use as a field device of process instrumentation according to 2 was already described at the beginning. The new process connection, of which in 1 only a sensor recording 20 is shown, differs significantly from the known design by the design of a channel 21 that is between the first part 3 ( 1 ) and the second part 5 the measuring chamber is arranged.

Instead of the known hole 13 ( 2 ) with pressed stopper 14 ( 2 ) as Zünddurchschlagsichere route now forms a hole 22 a section of the canal 21 whose diameter is 0.3 mm and whose length is 7 mm. Length and diameter of the bore created with an EDM drilling method 22 are therefore measured in such a way that they form an ignition-proof path without any further measures. Another section 23 of the canal 21 was in its diameter opposite the known channel 12 ( 2 ) reduced to 0.6 mm. In the section 23 the bore is produced by a chip-removing process. When comparing the channel 21 in the sensor holder 20 with the channel 12 ( 2 ) of the known sensor receptacle 1 ( 2 ) becomes particularly clear that now the amount of pressure transmitting means due to the reduced volume of the bore 22 and the channel section 23 is considerably reduced. This results in better measuring characteristics and a higher measuring accuracy of the pressure transmitter. In addition, there is the new pressure transmitter, in which the new sensor holder 20 in the same way as the known sensor holder 1 ( 2 ) can be mounted, by logistics advantages, cost savings at the supplier and lower manufacturing costs by omission of the plug 14 ( 2 ) and improved manufacturing quality, since the formation of chips can be excluded due to the omitted pressing-in process. By using a so-called high-speed spark-erosive drilling method, the manufacturing cost of the fine hole 22 of the canal 21 be further reduced.

Claims (3)

Pressure transmitter for use as field instrument of process instrumentation, with a process connection ( 1 . 2 . 20 ) for supplying a pressure to be measured, wherein the process connection is a measuring chamber ( 3 . 5 . 12 . 21 ), which is filled with a pressure transfer medium and from the process medium through a separating membrane ( 4 ), the measuring chamber having a channel ( 12 . 21 ) for connecting a first part ( 3 ) of the measuring chamber, which is located below the separating membrane, with a second part ( 5 ) of the measuring chamber in which a pressure-sensitive sensor ( 6 ), characterized in that the length and the diameter of the channel ( 21 ) are carried out by drilling in such a way that, without further measures, they provide an ignition-puncture-proof route between the two parts ( 3 . 5 ) forms the measuring chamber. Pressure transmitter according to claim 1, characterized in that the channel ( 21 ) has a diameter of at most 0.35 mm over a length of at least 6.3 mm. Pressure transmitter according to claim 1 or 2, characterized in that the process connection ( 1 . 2 . 20 ) consists of steel and the channel ( 21 ) at its second part ( 5 ) of the measuring chamber facing side over a length of 7 mm with a diameter of 0.3 mm is produced by spark erosion drilling.