DE10051534A1 - Sensor system, has homogeneous, dumbbell-shaped sensor body with end connections with key parts and surfaces on intermediate part for sensor elements that do not penetrate inner bore wall - Google Patents

Abstract

The system has a sensor body for insertion into a pipeline with an inner bore and outer sensor elements for detecting the flow state of a medium. The homogeneous, dumbbell-shaped sensor body has process connections on its end with key parts and at least two surfaces on an intermediate part on which the sensor elements are mounted so as not to penetrate the wall of the inner bore. Independent claims are also included for the following: a method of manufacturing a sensor system.

Description

The sensor system is based on a tubular system insertable sensor body, which together with on the outside of the sensor body applied sensor elements, a flow state detected, the inner tube flows through.

Sensor systems of the type mentioned are used in numerous applications used to monitor liquid flows. DE 40 17 877 A1 described such a sensor. On a thin-walled tube are outside walls Temperature measuring elements applied in a heat-conducting manner, one measuring element is additionally heated. The inner wall of the pipe, which is also heated transfers the heat to the medium flowing through this pipe. This leads the measuring elements as a function of the flow velocity Temperature difference used for determining the flow rate becomes. This thin-walled measuring tube is over seals with process connections connected to which external pipe systems can be connected. To one Both are to prevent the application of force on the thin-walled inner tube Process connections connected to an outer body, the inner measuring tube encloses. A major disadvantage of this system is that it is made up of there are at least four individual parts that are manufactured individually and accordingly cause high costs. Another disadvantage is that different Media also require different seals, which is a complex Warehousing results. The compressive strength of such systems is also due to the required thin-walled tube limited.

Currently known systems have one or more of the above Design features and the associated disadvantages.

The object of the invention is a sensor system and a method for its Specify production that avoids the disadvantages indicated above, in which the Sensor body in one piece and preferably automatically manufactured in one operation being, on the outer wall of the sensor body that of the to be detected Medium flows through the inner wall, the measuring elements detecting the flow are applied, which do not break through the wall of the sensor body and where a housing comprises the sensor body, which simultaneously rotates the Sensor body prevents against the housing.

The features indicated in claims 1 and 11 lead to the solution of the posed Task. The subordinate claims further develop the invention.

The one-piece, dumbbell-shaped design of the Sensor body, which consists of a homogeneous material that has no breakthroughs for sensor elements and which does not interfere with homogeneity Has welded connections or sealed parts. Through this Training ensures optimal corrosion resistance. Hence it too possible to manufacture the sensor body from materials that are difficult to weld are made of plastic or made of mineral materials, in particular, ceramics are also made. A high mechanical strength is achieved in that, if necessary, the wall thickness of the inner part of the Sensor body, the intermediate part, preferably tubular and is only on the places where the sensor elements are attached is reduced. This Locations are preferably designed as surfaces on which thermal, optical, acoustic or electromagnetic sensors are applied. Become Microwave sensors used, the sensor body is preferably made of Plastic or ceramic. Optical sensors require an optically transparent Sensor body while using thermal and acoustic methods very well metallic sensor bodies work.  

For each physical principle used, there is a similar procedure applied, taking into account only the peculiarity of the individual sensors become.

A special feature of the design is that the process connections unite Have key part, the partial of a preferably two-part housing is included, which protects the inner region of the sensor body against environmental influences and can also accommodate evaluating electronics. Through this embrace of the key part, it is no longer possible that the interior of the Sensor body can rotate relative to the housing. This type of anti-rotation is not limited to a geometry of a key part. You can also by Gluing, asymmetrical cross section of this part or pinning are generated. The process sequence for producing the sensor body can also be done in this way be designed that a sensor body for different sensory Applications. The for the special sensory elements required mechanical modifications of the intermediate part of the sensor body, are then carried out as the last mechanical process step, if known is what type of sensor to use. This procedure enables one extremely inexpensive manufacture of the sensor body. By in the Sensor body integrated key parts, preferably as a hexagon or hexagon are formed is an aligned, repeated clamping, z. B. in one Milling machine possible, so that very precise and accurate surfaces on the tubular inner part of the sensor body can be applied. A The special feature of this construction when using acoustic transducers is evident in that an acoustic transducer in the vicinity of the two opposite Key parts is attached. The key parts have a unit of length related mass, which is larger than that of the intermediate part. The distance too a key part is chosen so that it multiples a quarter of the corresponds to the acoustic wavelength of the transducer, which is in the longitudinal direction of the inner tube wall.  

At the same time, the distance between the key parts from each other so determined that when the acoustic signal is reflected on a key part gives a minimal signal at the location of the acoustic transducer. With that acoustic disturbances, which result from the sensor body itself Minimum reduced so that sound effects within the flowing medium Interference signals predominate. Similar considerations apply when Microwave sensors with electrically non-conductive sensor bodies are used.

The invention is explained in more detail with the aid of application examples.

Fig. 1 shows a sensor body 1 , the process connections 3 , which are each connected to a key approach 4 . The inner region of the sensor body, which is generally referred to as intermediate part 5 , has a bore 2 . Its outer area can have a round hexagonal cross section or a cross section that is different. In this intermediate part sensor surfaces 6 are applied which have a smallest wall thickness towards the inner bore of 0.2 to 0.8 mm. In the example shown, the sensor surfaces are applied to the intermediate part in such a way that their surface normals form an angle of 0 ° with one another. It is also possible to apply several surfaces to the intermediate part whose normals deviate from zero, e.g. B. surfaces whose normals form an angle of 60 ° with each other.

Fig. 2 shows a two-part housing 7 , which includes the sensor body so far that the key part 4 and the process connection 3 are freely accessible. In the front view, the housing in the area of the key part has the same geometric shape as the key part, so that it is not possible to twist the two interlocking parts against one another. The housing is held together by one or more, preferably screw connections 8 .

FIG. 3 shows a sensor system in which the sensor elements 9 , 10 are each shifted towards the key parts 4 . The spacing of the sensor elements 9 , 10 from one another is selected such that the acoustic transmission within the walls of the intermediate part 5 is minimized at the location of the sensor elements by interference which results from reflections on the near and far key part. The larger mass of the key part acts as a reflector for sound signals that come from the area of the outer pipes connected to the process connections.

In the case of very strong interference signals from this area, the housing 7 can also be made of metal, so that due to the good acoustic connection between the key surfaces and the housing, an acoustic short circuit occurs with respect to the internal sensor system.

Claims (15)

1. Sensor system, based on a sensor body that can be inserted into a line system with inner bore, which together with on the outside of the sensor body applied sensor elements the flow state of the inner bore flowing medium detected, with a sensor body that is dumbbell-shaped is formed and consists of a homogeneous material, where on the end Sensor body process connections are provided, each with one end attached key part, with a reduced outer diameter of the In between between these two key parts, and with at least two on surfaces attached to the intermediate part, on which sensor elements are applied, and where these sensor elements do not break through the wall of the inner bore. 2. Sensor system according to claim 1, characterized in that sensor elements are used, their function on an optical, thermal, acoustic or electromagnetic principle. 3. Sensor system according to claim 1 and 2, characterized in that the Sensor body is comprised of a housing, which is formed in several parts, one part a key part, which is preferably designed as a hexagon or hexagon, includes.   4. Sensor system according to claim 1 to 3, characterized in that on the outside the intermediate part of the sensor body, which is preferably tubular, two opposing sensor surfaces are incorporated in the manner that the smallest wall thickness of the intermediate part towards the inner bore 0.2 to Is 0.8 mm. 5. Sensor body according to claim 4, characterized in that on the surfaces Temperature measuring elements are applied, at least one Temperature measuring element is heated with an additional current. 6. Sensor system according to one of claims 1 to 5, characterized in that each a sensor surface in the direction of a key part of the sensor body are. 7. Sensor system according to one or more of claims 1-6, characterized characterized in that microwave sensors are used as sensor elements. 8. Sensor system according to one or more of claims 1-7, characterized gekennzeichent that the sensor system made of metal, plastic or a mineral material, preferably a ceramic, is made. 9. Sensor system according to one or more of claims 1-8, characterized characterized in that the sensor surface normal deviates from 90 ° Forms an angle with the flow normal.   10. Sensor system according to one or more of claims 1-9, characterized characterized in that the key parts of the sensor body from one or more Surfaces are formed. 11. Method for producing a sensor system based on one in one Line system insertable sensor body, which together with on the sensor body sensor elements applied to the outer wall, one the flow state of a the medium flowing through the medium is detected with a sensor body which preferably in one piece from a rod-shaped material, is machined, with an inner bore in a first step is introduced into the material with a second step, which is the free one Material end creates a process connection, with a third step that one free material end opposite part of the material a second Process connection created, with a fourth step, one at each material end Key part provides for a fifth step, which is the material thickness of the intermediate the key parts of the inner area, the intermediate part, reduced with a sixth step, the at least two surfaces on the intermediate part for the Attachment of sensor elements provides without the wall for Inner hole is broken. 12. The method according to claim 11, characterized in that two or more Process steps for producing the sensor system in one step are summarized or their order has been changed.   13. The method according to claim 11 and 12, characterized in that sensor elements applied to the intermediate part, which is preferably designed as a tube be, their function on an optical, thermal, acoustic or electromagnetic principle. 14. The method according to claim 11 to 13, characterized in that the sensor body is comprised of a housing which is formed in several parts, part of a Key part includes. 15. The method according to claim 11 to 14, characterized in that the In a last step, the sensor housing with an evaluating the sensor signal Electronics is provided.