DE10361564A1 - Modular dumbbell head sensor - Google Patents

Abstract

A sensor (10) serves to convert a physical parameter of a flowing medium into an electrical signal. The sensor (10) has a sensor tube (12), the outer surface (15) is flowed through by the medium. In a sensor tube (12), a temperature-sensitive element (28) is arranged. The sensor tube (12) forms with two approximately disc-shaped Anströmkappen (18, 20), which are arranged at a distance to each other on the sensor tube (12), a dumbbell-shaped sensor head. The flow caps (18, 20) are detachably connected to the sensor tube (12). They can be made of a softer material compared to the sensor tube (12) (FIG. 3).

Description

The The invention relates to a sensor for converting a physical Parameters of a flowing Medium in an electrical signal, with a sensor tube whose outer surface of flowing to the medium with one in the sensor tube arranged temperature-sensitive element and with an electronic Evaluation unit, whereby the sensor tube with two approximately discoid Anströmkappen, which are spaced from each other on the sensor tube, a dumbbell Sensor head forms.

Such a sensor is from the EP 0 339 626 known.

Of the known sensor used to capture physical parameters from pouring Media is used, taking physical parameters under the present invention, the flow rate, the temperature, the mass flow and the like of the flowing medium, e.g. Air, gases or liquids, to be understood.

This Sensor has a sensor housing on, which is connected to an electronic evaluation unit. At the sensor housing is over a mounting thread a cylindrical sensor tube attached to the outer, from sensor housing opposite end a dumbbell-shaped Head is arranged.

Of the dumbbell Head goes over from the sensor tube over conical part in a smaller diameter cylindrical part over, on which is a frustoconical Cap connects, whose truncated conical tip is the same diameter as the cylindrical one Part is. from the perpendicular to the longitudinal axis of the cylindrical Partially extending end surface the cap, which at the same time the bottom surface of the frustoconical cap represents, extends a cylindrical connecting piece of the sensor tube, the diameter and coaxial with the cylindrical part. At the cap opposite End of the connector of the sensor tube is another cone-shaped cap arranged with rounded tip. The bottom end surface of the another conical cap is the end face the frustoconical cap facing. The caps are in one piece with the sensor tube educated.

On the connector is a cylindrical one Carrier, as a cylindrical measuring sleeve is trained, deferred. The carrier is shorter than the connector formed, so that between the outer ends of the carrier and the end faces of the Caps each a part of the connector is located.

The Hauptanströmrichtung of the medium to be measured is perpendicular to the longitudinal axis of the sensor.

in the Foremost end region is the sensor as a conical cap with rounded Formed tip, which is designed as a high cap and a lumpy with a tubular one joint is trained. The tubular joint wear that sleeve-shaped carrier or a sleeve, the outside on the connector is deferred. In the end of the sleeve, the connector has a Thickening on, so that with deferred sleeve a smooth cylindrical area created in the area of the "dumbbell grip", so that edges that could cause turbulence are avoided.

Of the as one piece hollow body trained assembly of connector and cap is made of one poorly heat-conducting Plastic material produced. The sleeve consists of a good heat-conducting Material. It includes a ceramic chip as a sensor element. Of the Ceramic chip is on an outer side with a heating layer in the form of a thin-film resistor and at one Inner side with a measuring layer also in the form of a thin-film resistor coated. The sensor element itself is by means of a good heat conducting Potting compound in the interior of the sleeve embedded.

At the known sensor, it has proved to be disadvantageous that the dumbbell-shaped end the sensor with which the flowing medium is measured, very vulnerable across from Canceling the caps when placing the sensor at the site is. The known sensor is e.g. through a corresponding, intended opening in a tube inserted in the same. The opening of the tube is insignificantly larger than the diameter of the Dumbbell caps. If the sensor is not inserted optimally, i. he is e.g. cant, can or can one or both caps abort. This has the destruction of the entire sensor element result. A new sensor has to be renewed become. The purchase price is relatively high.

It It is therefore an object of the present invention to provide a sensor to create, which is easier to handle in measurements and at incorrect handling is not complete destroyed becomes.

These Task is solved by a sensor of the type mentioned, at the flow caps solvable with the sensor tube are connected.

This ensures that the flow caps can be replaced. Of the Sensor is then modular. The sensor tube and the flow caps can be made separately. If one of the flow caps is lost when positioning the sensor at the measuring location, it can be easily replaced by a new one. The production costs for a single sensor cap are far below the production costs of the entire sensor. A loss of a sensor cap, such as by breaking or stripping during insertion, for example, in a tube containing the flowing medium, thus does not necessarily lead to the uselessness of the entire sensor.

Further It is advantageous if the flow caps from a comparison soften to the sensor tube Material exist.

If the flow caps softer than the sensor tube are easier to connect to the sensor tube. Should when it comes to connecting to mechanical resistance, so is more likely the Give the cap as the tube. This ensures that the pipe, which contains (expensive) sensors, not damaged becomes.

According to one preferred embodiment the flow caps on the sensor tube attachable.

On the sensor tube attachable caps can be changed quickly and easily. To the Replacing caps does not require a tool. The caps can simply be replaced by hand.

Further it is preferred if the flow caps having an inner annular bead, the elastic in an outer annular groove of the sensor tube, preferably positive fit, is clipped.

So can be guaranteed be that the flow caps fixed on the sensor tube are arranged. They do not slip. When plugging, i. when clipping of the bead into the groove, the user gets a tactile feedback, that the caps are in the right place, i. when the caps snap into place.

Further it is preferred if the sensor tube in Area of the annular groove is formed thickened.

By a thickening of the sensor tube in the area of the annular groove, the mechanical stability of the sensor tube improved when attached Anströmkappen. The danger that the sensor tube either when positioning the sensor at the measuring location or during application the flow caps on the sensor tube damaged will be significantly reduced. Due to the thicker wall thickness of the sensor tube In the area of the annular groove, the sensor tube can have higher mechanical stresses take up. Furthermore, the annular groove in the manufacturing process of sensor tube simple, e.g. cutting, in the sensor tube be formed. The annular groove can also be injection-molded.

According to one another preferred embodiment are the flow caps on the sensor tube screwed.

These for attaching alternative connection between the flow caps and the sensor tube has the advantage that it prevents (accidental) dislocation or Moving the flow caps prevented. In this way it is ensured that the flow caps always at the predetermined location relative to the sensor tube so that anytime ideal flow conditions in the (measuring) range between the flow caps to rule.

Further It has proven to be advantageous if the sensor tube with a temperature, preferably a heater for regulated Tempering or heating the temperature-sensitive element to a predetermined temperature is provided, and the evaluation unit an electronic measuring means has recorded for detecting and evaluating the temperature. Another advantage is when measuring the temperature of the medi ums to predetermined temperature higher as the temperature of the medium is set.

By these measures Ensures that the temperature-sensitive sensor is working properly. Due to the planned adjustable heating, the temperature is around the temperature-sensitive element around to a predetermined temperature, especially a higher one Temperature as the temperature of the medium, adjusted so that the Cooling medium acts on the sensor. In case of cooling then regulates the heating the temperature after. The electronic measuring devices record these Performance of the heater and evaluate them, giving conclusions about the flow rate of the Medium can be pulled.

According to one another embodiment is the sensor tube thin-walled educated.

The wall thickness of the sensor tube influences the thermal conductivity. The greater the wall thickness in the radial direction, the lower the heat conduction between the outer space and the interior of the sensor tube. Since the temperature-sensitive element is disposed within the sensor tube, it is advantageous if the wall thickness of the sensor tube is thin-walled at least in the region where the temperature-sensitive element is arranged. In this way, the temperature or the temperature difference is best transmitted from outside to inside.

Advantageous is also when the temperature-sensitive element in the sensor tube by means of a heat-conducting Cast material is.

These measure allows an even better heat conduction between the outside space to be surveyed of the sensor tube and its interior, where the temperature-sensitive sensor element is located.

Further it is an advantage if the sensor tube itself forms a front end portion of a sensor tube, especially when the front end portion is formed closed at its free end is.

In In this case, the sensor tube in one piece with formed the sensor tube, i. the sensor tube forms the housing of the Sensor. This reduces production costs and costs. An assembly of the sensor tube with the remaining sensor is not required. The temperature sensitive Element may be opposite from the one closed end of the sensor tube, open side into the sensor tube introduced become. Since the free end, i. the end where it is measured is closed is formed, no means for sealing the pipe between the front inflow cap and the pipe itself needed. The flowing through Medium can not get inside the sensor, even then, if one of the caps or both caps are off the probe tube should solve. This increases the life of the sensor, as often measured aggressive media in particular the electronic components of the sensor could attack.

According to one another embodiment the front end portion is open at its free end and by means of a cap-shaped trained inflow cap closable.

This has the advantage that the sensors located in the sensor tube Components of the sensor, in particular the temperature-sensitive Element, slightly from the outside is accessible for assembly or repair purposes.

Especially is advantageous if the sensor tube has a rear end region, has a central region and the front end region, and these areas in one piece are formed.

By one-piece will ensure that the medium to be measured, which may also be aggressive, not at the joints between the individual areas can get into the interior of the sensor tube. By the one-piece will Furthermore, provided a certain strength, the breaking of the tube, e.g. due to leverage, prevent.

Advantageous is also when in the rear end another temperature sensitive Element is arranged.

The Another temperature sensitive element can be used as a reference for yourself in the front end area of the sensor tube serve temperature-sensitive element. The measurement results are then more precise and more reliable, since fluctuations in the ambient temperature can be taken into account.

Especially it is preferred if the rear end region is thick-walled is and with a heat window for the further temperature-sensitive element is provided.

The arranged in the rear end region further temperature-sensitive Element is thus not affected by the temperature in the or at the front end area, in particular the actual measuring area, prevails. about the heat window becomes it allows the further temperature-sensitive element to determine the temperature of the medium. A heat exchange between sensor and heat window is avoided.

Further it is advantageous if the other temperature-sensitive element via a thermally conductive Paste with the heat window thermally connected. The heat paste allows a better heat conduction from the medium to the temperature element.

According to one another preferred embodiment the middle area is poor heat-conducting educated.

By This measure will the "heat communication" between the front and the rear end region prevented or at least largely reduced.

Farther is advantageous if the middle region with a small cross section, especially opposite the front and rear end portion is formed.

Also This measure Prevents or worsens the heat communication between the front and the rear end area.

Especially is advantageous if the central region is evacuated.

This measure also supports the poorer thermal conductivity between the front and rear end area. The front and rear end regions are decoupled with respect to their heat sensitivity.

According to one another preferred embodiment exist the flow caps made of an elastic plastic, in particular of a perfluoroelastomer.

The elasticity the flow caps supports easy installation of caps on the sensor tube. The sensor tube is less damaged when using elastic caps because this in contact with the sensor tube the surface claiming less of it.

It is also advantageous if the sensor tube consists of a material which is resistant to aggressive media, in particular of a ceramic selected from the group consisting of ZrO ₂ and Al ₂ O ₃ .

These Choice of manufacturing materials ensures that the sensor one possible has long life, with the required thermal conduction effects or the thermal conductivity be taken into account or will.

The Task, further features and advantages of the present invention be from the following description in conjunction with the attached Drawings become even clearer. Show it:

1a / 1b a schematic perspective view of a sensor according to the present invention in a disassembled state;

2 one opposite the 1 enlarged schematic perspective view of the dumbbell-shaped sensor head of 1 in the assembled state; and

3 a section along the longitudinal axis of the sensor according to the 1 ,

The Sensors shown in the figures are used to detect physical Parameters of flowing Media, taking among physical parameters in the context of the present Invention the flow velocity, the temperature, the mass flow and the like of the flowing medium, e.g. Air, gases (biogas) or liquids are understood should.

An in 1a illustrated sensor 10 has a sensor housing 12 on, which is connected to an electronic evaluation unit not shown here.

The sensor housing 12 is here in one piece with a sensor tube 12 educated. At the front end area 14 of the sensor tube 12 that has an outer surface 15 can, along the longitudinal axis 16 a first inflow cap 18 and a second inflow cap 20 (see. 1b ) with the sensor tube 12 get connected. In the connected state form the sensor tube 12 , in particular the front end region 14 , with the caps 18 and 20 a dumbbell-shaped sensor head (see also 2 ).

In the 1a is only the first inflow cap 18 shown. The second inflow cap 20 is in the further for the sake of clarity 1b shown. In the assembled state, the second inflow cap would be 20 but before the first inflow cap 18 in the direction of the longitudinal axis 16 on the front end area 14 of the sensor tube 12 applied. The second inflow cap 20 has for this purpose a corresponding opening (not shown). Then the first inflow cap would be 18 along the longitudinal axis 16 on the front end area 14 of the sensor tube 12 been applied.

Around the flow caps 18 and 20 safely on the sensor tube 12 To fix, the caps can 18 and 20 one ring bead each 21 (see also 3 ) exhibit. The torus 21 can engage with a groove or annular groove 24 be brought, which at a thickening 22 in the front end area 14 of the sensor tube 12 can be provided.

The width of a measuring range 26 is (in the assembled state) by the distance between opposing faces of the flow caps 18 and 20 Are defined. To measure, the flowing medium becomes substantially perpendicular to the outer surface 15 in the front end area 14 of the sensor tube 12 ie perpendicular to the central axis 16 , on the sensor 10 directed (see also arrows 30 and 32 in 3 ).

2 shows an enlarged schematic view of a front end portion 14 ' a sensor 10 which is essentially identical to the sensor 10 of the 1 is. The sensor 10 of the 2 is shown in perspective in an assembled state of the sensor head. One clearly recognizes the dumbbell-shaped design of the sensor head. The sensor tube 12 is preferably cylindrical. Other shapes are also possible.

The flow caps, in particular the inflow cap 18 ' , is cap-shaped, and closes the front end of the sensor tube 12 ,

The front end of the sensor tube 12 can be formed both closed and open. If the front end is closed, it is between the first inflow cap 18 ' and the sensor tube 12 no seal required, the penetration of the medium to be measured into the interior of the sensor tube 12 prevented. However, should the front end be open, a seal such as an O-ring is provided.

The front end of the front end area 14 respectively. 14 ' Traineeship has the advantage of being inside the sensor tube 12 located components of the sensor 10 , in particular the elements which are located in the front end area, are easily accessible. The closed design has the advantage that the medium to be measured can not penetrate into the sensor tube. However, then the incorporation of the components, located in the front end area 14 respectively. 14 ' are a little harder.

In 3 is a schematic sectional view along the longitudinal axis 16 of the sensor according to the 1 and 2 shown.

The front (free) end of the front end area 14 is formed closed in this embodiment.

The flow caps 18 and 20 each have a torus 21 on, which engages with the annular groove 24 can be brought.

In the 3 is the first inflow cap 18 already in one with the sensor tube 12 connected state shown. The second inflow cap 20 is not yet final with the sensor tube 12 connected. By moving the second inflow cap 20 in the 3 to the left could be the second inflow cap 20 be brought into a predetermined position for a measurement.

In the 3 you can see that the flowing medium along the arrows 30 and 32 perpendicular to the longitudinal axis 16 on the outside surface 15 the front end area 14 of the sensor tube 12 is directed.

In the front end area 14 is inside the sensor tube 12 a sensor element 28 arranged. The sensor element 28 is a temperature-sensitive element that is connected to an electronic evaluation unit (not shown).

Spatially close to the outer surface 15 is a regulated heater in the sensor tube 12 intended. This controlled heating (not shown) is used to heat the sensor tube 12 to a predetermined temperature, which is preferably above the temperature of the medium to be measured.

With the heater for controlled heating, the front end area 14 of the sensor tube 12 regulated to a predetermined temperature. Due to the flowing medium, the temperature of the sensor tube lowers 12 , Around the sensor tube 12 Keeping at the predetermined temperature, the heater will adjust the temperature by heating. The evaluation unit, which has among other things (electronic) means for detecting and evaluating the power of the heater, registers this process and can determine the temperature of the medium on the basis of the recorded and registered data.

At the front end area 14 of the sensor tube 12 closes a middle section 34 at. To the middle area 34 closes a rear end area 36 at. The front end area 14 , the middle area 34 and the rear end area 36 are preferably formed in one piece.

In the rear end area 36 of the sensor tube 12 can additionally a further sensor element 38 be provided, which is temperature sensitive. The other temperature-sensitive element 38 is by means of a thermally conductive paste, ie by means of a thermal bridge 42 , thermally with a heat window 40 connected. Instead of a thermally conductive paste, other materials which have a good heat-conducting property, as a thermal bridge 42 be used. The heat window 40 is preferably formed thin-walled. It is part of the sensor tube 12 ,

About the heat window 40 and the thermal bridge 42 may be the second temperature-sensitive element 38 determine the temperature of the medium. It is thus possible to measure the temperature of the medium at two different locations, ie if necessary to be able to take into account local temperature fluctuations of the medium.

Usually, the sensor 10 used so that at least the front end area 14 of the sensor tube 12 is positioned in the flowing medium. The middle area 34 is usually also within the flowing medium. The rear end area 36 is also usually within the flowing medium. For example, the sensor according to the invention could 10 be plugged into a suitable opening in a pipe through which flows to be measured medium. The middle area 34 and the rear end area 36 can then also be within the tube with the flowing medium.

Exactly in such situations, it may happen during insertion to the sensor 10 acting leverage, namely, especially when the longitudinal axis 16 of the sensor 10 oriented horizontally with respect to a vertically extending tube.

Due to the one-piece design of the sensor tube 12 The acting forces can be better absorbed without causing damage to the sensor tube 12 comes. Should be during insertion of the sensor 10 into the opening of the tube, in which the medium flows, break off one of the Anströmkappen, it can be easily replaced due to the modular design of the sensor according to the invention.

The smaller the wall thickness in the front end area 14 is formed, the better the heat from the outer surface 15 towards the interior of the sensor tube 12 transfer. So that the heat changes in the measuring range 26 the second temperature-sensitive element 38 As little as possible will affect the middle range 34 of the sensor tube 12 preferably provided with a smaller wall thickness. The cross section of the middle region 34 is preferably chosen as small as possible, so that the volume between the front end portion 14 and the rear end area 36 also for heat transfer between the two temperature-sensitive elements 28 and 38 contributes as small as possible.

Preferably, the interior is 44 of the sensor tube 12 hollow designed and evacuated. In the rear end area 36 of the sensor tube 12 the pipe diameter may increase again, in particular if the connection to the electronic evaluation unit or the electronic evaluation unit itself is provided in the rear end region.

The sensor tube 12 is preferably injection molded from a media-resistant ceramic. The ceramic may be selected from the group ZrO ₂ and Al ₃ O ₃ . The sensor tube 12 can also be made of a plastic, such as PBT, which is glass fiber reinforced, or LCP (liquid crystal polymers), which is particularly strong and temperature resistant.

Claims (25)

Sensor for converting a physical parameter of a flowing medium into an electrical signal, with a sensor tube ( 12 ), whose outer surface ( 15 ) is flown by the medium, with a in the sensor tube ( 12 ) arranged temperature-sensitive element ( 28 ), and with an electronic evaluation unit, wherein the sensor tube ( 12 ) with two approximately disk-shaped flow caps ( 18 . 20 ), which are spaced apart on the sensor tube ( 12 ), forms a dumbbell-shaped sensor head, characterized in that the flow caps ( 18 . 20 ) detachable with the sensor tube ( 12 ) are connected. Sensor according to claim 2, characterized in that the flow caps from a compared to the sensor tube ( 12 ) softer material. Sensor according to claim 1 or 2, characterized in that the flow caps ( 18 . 20 ) on the sensor tube ( 12 ) are attachable. Sensor according to claim 3, characterized in that the flow caps ( 18 . 20 ) an inner annular bead ( 21 ) which elastically in an outer annular groove ( 24 ) of the sensor tube ( 12 ), in particular form-fitting, can be clipped. Sensor according to claim 4, characterized in that the sensor tube ( 12 ) in the region of the annular groove ( 24 ) is thickened. Sensor according to claim 1 or 2, characterized in that the flow caps ( 18 . 20 ) on the sensor tube ( 12 ) are screwed. Sensor according to one of claims 1 to 6, characterized in that the sensor tube ( 12 ) with a temperature control for controlled temperature control of a measuring range ( 26 ) of the sensor tube is provided to a predetermined temperature, and that the evaluation unit has an electronic measuring means for detecting and evaluating the power of the temperature. Sensor according to claim 7, characterized in that for measuring the temperature of the medium, the predetermined temperature higher than the temperature of the medium is set. Sensor according to one of claims 1 to 8, characterized in that the sensor tube ( 12 ) is formed thin-walled. Sensor according to one of claims 1 to 9, characterized in that the temperature-sensitive element ( 28 ) into the sensor tube ( 12 ) is poured by means of a thermally conductive material. Sensor according to one of claims 1 to 10, characterized in that the sensor tube ( 12 ) a front end region ( 14 ) of a sensor tube ( 12 ). Sensor according to claim 11, characterized in that the front end region ( 14 ) is formed closed at its free end. Sensor according to claim 11, characterized in that the front end region ( 14 ' ) formed open at its free end and by means of a cap-shaped inflow cap ( 18 ' ) is closable. Sensor according to one of claims 11 to 13, characterized in that the sensor tube ( 12 ) a rear end region ( 36 ), a middle area ( 34 ) as well as the front end region ( 14 ) and that the areas ( 14 . 34 . 36 ) are integrally formed. Sensor according to claim 14, characterized in that in the rear end region ( 36 ) another temperature-sensitive element ( 38 ) is arranged. Sensor according to claim 15, characterized in that the rear end region ( 36 ) thick-walled and with a heat window ( 42 ) for the further temperature-sensitive element ( 38 ) is provided. Sensor according to claim 16, characterized in that the further temperature-sensitive element ( 38 ) via a thermally conductive paste with the heat window ( 42 ) is thermally connected. Sensor according to one of claims 14 to 17, characterized in that the central region ( 34 ) is poorly thermally conductive. Sensor according to one of claims 14 to 18, characterized in that the middle region ( 34 ) is formed with a small cross-section. Sensor according to one of claims 14 to 19, characterized in that the central region ( 34 ) is evacuated. Sensor according to one of claims 1 to 20, characterized in that the flow caps ( 18 . 20 ) consist of an elastic plastic. Sensor according to claim 21, characterized in that the flow caps ( 18 . 20 ) consist of a perfluoroelastomer. Sensor according to one of claims 1 to 22, characterized in that the sensor tube ( 12 ) consists of a material resistant to aggressive media. Sensor according to claim 23, characterized in that the sensor tube ( 12 ) consists of a ceramic. Sensor according to claim 24, characterized in that the ceramic is selected from the group ZrO ₂ and Al ₂ O ₃ .