DE4306364A1 - Differential pressure transmitter - Google Patents

Abstract

The differential pressure transmitter has a pressure-proof and pressure-tight pressure housing (1) having a high pressure connection and a low pressure connection (2, 3). Arranged in this pressure housing (1) there are a capsule spring (4) and a ferrite core (5) which can be deflected together with the capsule spring (4), the said ferrite core (5) being able to be displaced axially inside a two-part induction coil (7) which is fixed in a distance pick-up (6) and forms part of an electrical measuring bridge, for transmitting the measuring movement. The ferrite core (5) can be axially displaced without friction and with a small clearance inside a guiding tube (8) screwed to the pressure housing (1) and pressure-tight to the outside. The induction coil (7) having the distance pick-up (6) can be manually steplessly displaced on the guiding tube (8) with respect to the ferrite core (5) for balancing the measuring bridge and can be locked on the pressure housing (1) by means of a clamping screw (9). <IMAGE>

Description

The invention relates to a differential pressure transmitter for measuring differential, positive and negative pressure and subsequent conversion of the pressure signal via a Induction coil with electrical measuring bridge in an electrical Signal.

Such differential pressure gauges have the problem that due to tolerances in the mechanical and electrical Components even when the actual differential pressure is zero, a low pressure signal is displayed. Therefore, accurate differential pressure gauges must be used for compensation this inaccuracy can be adjusted.

The object of the invention is a differential pressure transmitter with the differential pressure in a precise and reliable manner can be measured and compared in a simple manner is to create.

This object is achieved by the characterizing Features of claim 1 solved. The ones at it subsequent sub-claims contain design features, what advantageous and beneficial further training the Represent invention.

The differential pressure transmitter has a pressure-resistant and -tight pressure housing with a high pressure and a Low pressure connection. There is one in the pressure housing  Capsule spring arranged between two one between Capsule membranes forming pressure volume. At a Pressure difference between capsule spring interior (pressure volume) and capsule spring exterior (pressure housing) becomes the capsule spring stretched or compressed. This measuring movement is based on a Ferrite core transmitted within one in one Position transducer fixed induction coil is displaceable. The induction coil is part of an electrical measuring bridge. The Detuning this electrical measuring bridge by moving of the ferrite core in the induction coil provides the Pressure difference corresponding electrical signal.

The ferrite core is within one with the pressure housing behind guide tube screwed tightly on the outside with little play, can be moved axially without friction. The ferrite core is included the capsule spring via an elastic connecting element coupled in terms of movement. The induction signal is thus from Ferrite core over the hermetically sealed to the outside Guide tube in a flawless manner on the induction coil transfer. The induction coil is now with the displacement sensor on the guide tube opposite the ferrite core for Stepless calibration of measuring bridges in a simple way movable and by a clamping screw on the pressure housing lockable.

An exemplary embodiment is shown in the drawings, which is explained in more detail below. It shows:

Fig. 1 shows a section through the pressure housing with capsule, ferrite core, guide tube and the transducer,

Fig. 2 shows a section through the capsule spring,

Fig. 3 shows a section through the pressure housing installed in the housing box.

The differential pressure transmitter has a pressure-tight and tight pressure housing ( 1 ) with a high-pressure and a low-pressure connection ( 2 , 3 ). A capsule spring ( 4 ) is arranged in the pressure housing ( 1 ) and consists of two capsule membranes ( 4 a, 4 b) forming a pressure volume between them. The capsule membranes ( 4 a, 4 b) are formed from identically corrugated metal sheets and can be joined together in a form-fitting manner. The high-pressure medium reaches the capsule spring ( 4 ) via the high-pressure connection ( 2 ), while the low-pressure medium ( 3 ) is connected to the interior of the pressure housing. If there is a pressure difference between the capsule spring interior (pressure volume) and the capsule spring exterior (pressure housing interior), the capsule spring ( 4 ) is stretched or compressed.

This measuring movement is transferred to a ferrite core ( 5 ) which can be displaced within a two-part induction coil ( 7 ) fixed in a displacement transducer ( 6 ). This induction coil ( 7 ) is part of an electrical measuring bridge. The detuning of this electrical measuring bridge by moving the ferrite core ( 5 ) in the induction coil ( 7 ) provides the electrical signal (current, voltage) corresponding to the pressure difference, which can then be processed and displayed accordingly.

The ferrite core ( 5 ) can be moved axially within a guide tube ( 8 ) tightly screwed to the outside of the pressure housing ( 1 ) with little play. For this purpose, the ferrite core ( 5 ) is coupled in terms of movement to the capsule spring ( 4 ) via an elastic connecting element ( 10 ), preferably a metal spring. The measuring movement of the ferrite core ( 5 ) is thus transmitted to the induction coil ( 7 ) in a simple manner by induction through the guide tube ( 8 ), which is hermetically sealed to the outside.

The induction coil ( 7 ) can be moved continuously and manually with the displacement transducer ( 6 ) on the guide tube ( 8 ) for measuring bridge adjustment and can be locked by a clamping screw ( 9 ) on the pressure housing ( 1 ).

The guide tube ( 8 ) is open at the end piece facing the capsule spring ( 4 ) and screwed pressure-tight and tight on the pressure housing ( 1 ) by means of a sealing ring ( 11 ), while the other end piece protrudes from the pressure housing ( 1 ) as a closed end. The length of the guide tube ( 8 ) protruding from the pressure housing ( 1 ) is dimensioned such that it completely penetrates the displacement transducer ( 8 ) and the induction coil ( 7 ) in any adjusted position.

The ferrite core (5) is mounted on a rod (12) and maintained thereby secured against shifting between a lying in the guide tube (8) end head of the rod (12) and attached to the other end of the rod (12) connecting member (10).

The capsule spring ( 4 ) is assigned a pressure relief valve ( 13 ) on the side facing the high pressure connection ( 2 ). This pressure relief valve ( 13 ) has a socket-shaped valve seat ( 13 a) screwed into the pressure housing ( 1 ) and holding the capsule membrane ( 4 a). In this valve seat ( 13 a), a valve piston ( 13 b), which holds the second capsule membrane ( 4 b) on a holding plate ( 15 ), forms an annular space ( 14 ) for the pressure medium. This valve piston ( 13 b) has an adjusting screw ( 13 c) with a sealing ring ( 11 ) for setting and shutting off an entry gap ( 16 ) to the annular space ( 14 ). The holding plate ( 15 ) carries a coaxial bearing journal ( 17 ) for fastening the connecting member ( 10 ).

If the pressure set on the pressure relief valve ( 13 ) is exceeded, the pressure relief valve ( 13 ) closes the inlet gap ( 16 ) to protect the capsule spring ( 4 ). If the high-pressure and low-pressure connections ( 2 , 3 ) are mistakenly interchanged, the capsule membranes ( 4 a, 4 b) of the capsule spring ( 4 ) are pressed against one another in a non-destructive manner.

The pressure housing ( 1 ) is screwed into a housing box ( 18 ) with a high-pressure and low-pressure adapter ( 19 , 20 ) and a cable connection ( 21 ). An electronics board ( 22 ) with the measuring bridge is contained in this housing box ( 18 ).

The pressure housing ( 1 ) is divided into two parts and is screwed together with a sealing ring ( 11 ) so that it is pressure-tight and tight. Coaxial to the adjusting screw ( 13 c) of the valve piston ( 13 b), a sealing screw ( 23 ) forming an access to the adjusting screw ( 13 c) for its actuation is arranged in the pressure housing ( 1 ).

Claims (12)

1. Differential pressure transmitter with a pressure-tight and -tight pressure housing having a high-pressure and low-pressure connection and a capsule spring arranged therein and a ferrite core which can be deflected together with the capsule spring and which is transmitted within a two-part induction coil which is fixed in a displacement transducer and which is part of an electrical measuring bridge the measuring movement is axially displaceable, characterized in that the ferrite core ( 5 ) can be moved axially with little play within a guide tube ( 8 ) tightly screwed to the pressure housing ( 1 ) and the induction coil ( 7 ) with the displacement sensor ( 6 ) on the guide tube ( 8 ) relative to the ferrite core ( 5 ) for manual adjustment of the measuring bridge, it can be moved continuously and locked by means of a clamping screw ( 9 ) on the pressure housing ( 1 ). 2. Differential pressure transmitter according to claim 1, characterized in that the ferrite core ( 5 ) with the capsule spring ( 4 ) via an elastic connecting member ( 10 ), preferably a spring, is coupled in terms of movement and play in the guide tube ( 8 ). 3. Differential pressure transmitter according to claim 1 and claim 2, characterized in that the guide tube ( 8 ) on the capsule spring ( 4 ) facing end piece is open and by means of a sealing ring ( 11 ) pressure-tight and tight on the pressure housing ( 1 ) and the other End piece protrudes from the pressure housing ( 1 ) as a closed end. 4. Differential pressure transmitter according to claim 1 to claim 3, characterized in that the length of the pressure housing ( 1 ) projecting guide tube ( 8 ) is dimensioned so that this the displacement transducer ( 6 ) and the induction coil ( 7 ) completely in any adjusted position penetrates. 5. Differential pressure transmitter according to claim 1 to claim 4, characterized in that the ferrite core ( 5 ) is mounted on a rod ( 12 ) and between an end head in the guide tube ( 8 ) of the rod ( 12 ) and at the other end of the rod ( 12 ) fastened connecting member ( 10 ) is held against displacement. 6. Differential pressure transmitter according to claim 1 to claim 5, characterized in that the capsule spring ( 4 ) is formed by two between them forming a pressure volume identically corrugated capsule membranes ( 4 a, 4 b) and the two capsule membranes ( 4 a, 4 b) positively are put together. 7. Differential pressure transmitter according to claim 1 to claim 6, characterized in that the capsule spring ( 4 ) is assigned a pressure relief valve ( 13 ), which is screwed into the pressure housing ( 1 ), socket-shaped and a capsule membrane ( 4 a) holding valve seat ( 13 a) and (a 13) enclosing in this valve seat to form an annular space (14) for the pressure medium, to a holding plate (15), the second capsule membrane (4 b) holding the valve piston (13 b) having a screw (13 c) with Has sealing ring ( 11 ) for setting and blocking an entry gap ( 16 ) to the annular space ( 14 ) and carries a coaxial bearing journal ( 17 ) for fastening the connecting member ( 10 ). 8. Differential pressure transmitter according to claim 1 to claim 7, characterized in that the pressure housing ( 1 ) in a housing box ( 18 ) with a high pressure and a low pressure adapter ( 19 , 20 ) and a cable connection ( 21 ) is installed. 9. Differential pressure transmitter according to claim 1 to 8, characterized in that the housing box ( 18 ) contains an electronic board ( 22 ) with the measuring bridge. 10. Differential pressure transmitter according to claim 1 to claim 9, characterized in that the pressure housing ( 18 ) is divided in two and with the interposition of a sealing ring ( 11 ) is screwed pressure-tight and tight. 11. Differential pressure transmitter according to claim 1 to claim 10, characterized in that the capsule membranes ( 4 a, 4 b) are formed from sheet metal. 12. Differential pressure transmitter according to claim 1 to claim 9, characterized in that coaxial to the adjusting screw ( 13 c) of the valve piston ( 13 b) in the pressure housing ( 1 ) a sealing, an access to the adjusting screw ( 13 c) for actuating the locking screw ( 23 ) is arranged.