DE19951342A1 - Filling level display; has flange with tube having float rod with giant magnetoresistance non-contact sensor opposite magnetic part of float rod joint and magnetically controlled display unit - Google Patents

Abstract

The filling level display (10) has a flange (10) with a tube fitted in it that can be inserted into a container. The tube guides a rod, whose lower end is connected to a float rod (22) and assigned to a magnetically controllable display unit. The rod has a giant magnetoresistance sensor, which is opposite a magnetically polarised bearing part (26) of the joint (24) and does not contact it. An Independent claim is included for the use of a giant magnetoresistance sensor to measure the filling level in fluid or liquefied gas containers.

Description

The present invention relates to a level indicator according to the preamble of claim 1.

Usual containers for liquids and pressurized liquid gas such as propane, Butane or mixtures thereof have fittings with separate connections and Valves; filling, safety and dispensing valves are generally available. Moreover display means are required to detect the fill level or the current volume do. In a proven device, a flange attached to the container holds inwardly projecting tube for guiding a rod, the lower (inner) end is connected via a gearbox to a float rod and its upper one (outer) end can wear a viewing capsule in which a rotatably mounted display needle is facing a reading scale.

A joint with a propeller shaft has also been provided on the float shaft the magnets are attached to the float position on a magnetically controllable Transfer display capsule. DE 39 04 824 A1 discloses a device of this type wrote that additionally an electronic level sensor or an ultrasound Sensor and a high-level dipstick to the greatest mechanical interference to suppress and if necessary cancel a filling or not only in Gear. Long measuring probes were used for remote content display, e.g. B. according to DE 12 65 444 B1 and DE 14 73 132 A1.  

In the known devices, it is disadvantageous that the float with the holder pipe is connected via a gearbox that is not just an inevitable movement has play, but is also prone to contamination. This inevitably arises Measurement uncertainties; irregular deviations cannot be excluded.

It is an important object of the invention to overcome these and other disadvantages of the prior art Overcoming technology and creating an improved level indicator that with a simple structure, economical manufacturability and easy installation reliable level indicator. The device is said to be in containers for various purposes Flow media can be used and be free from the defects of a gearbox.

Main features of the invention are set out in the characterizing part of claim 1 ben. Refinements are the subject of claims 2 to 10. To a special Component use is directed to claim 11.

In a device of the type specified at the outset with a flange on which an in the container projecting tube is attached, which guides a rod, the lower or inner end is articulated with a float rod and one is assigned to a magnetically controllable display device, the invention provides the characterizing part of claim 1 that the rod has a GMR sensor points that touches a magnetically polarized bearing part of the float linkage faces without hesitation. With this arrangement you can achieve a problem-free assembly Clear level indicator that is largely free of mechanical interference. The conventional float gear is replaced by a simple swivel bearing; this goes hand in hand with significantly reduced friction losses. At the same time, the contactless magnetic field coupling a sufficiently accurate, at least reliable transformation of the float lever angle into a level value that is analog and / or can be displayed digitally, which in turn opens up new application possibilities opened.

According to claim 2, the GMR sensor is on the circumference of the lower (inner) rod end attached and the rod is rotatably arranged with respect to the tube so that the GMR sensor detects the magnetic field of the bearing part. The mechanical structure is therefore just as simple as fail-safe, especially if it is on the pipe according to claim 3 Anti-rotation lock has a nose, e.g. B. a notch in a recess of the Rod engages. The bearing part can be assigned to one another according to claim 4  Have permanent magnets that are diametrically opposed to each other, so that the GMR sensor fully detects the magnetic field in between, which is why Say 5 appropriately provides that the distance between the permanent magnets in the Size with a width dimension on a probe attachment of the GMR-Sen sors matches.

In accordance with claim 6, the bearing part is ver with a swivel angle limiter see the according to claim 7 specifically as a one-piece with the bearing part sheet, Seg ment, angle or the like is formed, which by the stop on the pipe the maximum Rash of the float linkage determined. This means that the lower and upper limit ripples in the simplest way excluded.

According to claim 8, a combination with an overfill protection is provided for for example by adding a through channel and a ring seal on the pipe and Rod a possibly releasable closure element is present, which is in the Moving the passage channel to the system on the ring seal.

The further development of claim 9, according to which the display device is used, is very advantageous means for remote transmission and remote reading are coupled, optionally by Cable and / or over a radio link, so that the level indicator is not as forth is conveniently local. For this purpose, evaluation electronics are provided seen in a housing connected to the flange or separately brings and can be activated as required at predefinable time intervals or manually and / or is available.

Independent protection is claimed for claim 11. He sees in general the new type for detecting the fill level in liquid or liquid gas containers Using a GMR sensor before, which is not considered in the prior art pulled had even been realized.

Further features, details and advantages of the invention result from the Wording of the claims and from the following description of execution examples using the drawings. Show it:  

Fig. 1 is a side view - partly in section - of a level indicator device,

Fig. 2 is a plan view of the device of Fig. 1 and

Fig. 3 is a partial sectional view of the lower end of the device.

As can be seen from FIGS. 1 and 2, a level indicator generally designated 10 has a flange 11 which can be screwed on the head side to a cover 12 with the interposition of a sealing ring 13 and which holds a tube 14 which, after the flange 11 has been attached to a ( not drawn) container protrudes into this. A rod 16 is guided in the tube 14 , the lower end 18 of which is connected to a float linkage 22 via a joint 24 . The latter has a length matched to the size of the container and carries a float 20 on a bearing part 26 and a counterweight 27 on the one hand.

The joint 24 has an axis 25 with a coaxially projecting bearing pin 28 on which the bearing part 26 is rotatably seated and z. B. is axially secured by a ring disc 29 on the joint 24 . The bearing part 26 is integrally or rigidly connected to at least one arc segment 55 arranged concentrically to the axis 25 or another limiter element which determines the maximum deflections of the float linkage 22 by a stop on the tube 14 .

On both sides of the bearing pin 28 26 permanent magnets 50 are present in the bearing part, namely ring or bar magnets, which are anchored in a transverse bore of the bearing part 26 , for example glued in, and have a distance a from one another at the end. This corresponds to a width dimension b of a probe attachment 42 on a sensor 40 , which is attached to a flat 48 at the lower end 18 of the rod 16 . Thus, the sensor 40 can scan the existing between the magnets 50 magnetic field optimum for securing the parallelism of the elements is 40/48/50, an anti-rotation device is provided. In the simplest case, it consists of a nose or indentation 44 on the tube 14 which is arranged transversely to the flattened portion 48 and which engages in an associated slot 46 of the rod 16 so as to be longitudinally displaceable.

As a sensor 40 is a GMR sensor, namely a "Giant Magneto Resistor" provided with the probe attachment 42 known per se, which has a stack of magnetic and non-magnetic metal layers and by means of a bridge or half-bridge circuit depending on the direction caused by the float of the field detected by the sensor 40 between the magnets 50 supplies electrical signals which are largely independent of the magnetic field strength and of the air present. Power supply and signal lines (not shown) are led through a cable version 30 . An evaluation electronics (also not shown) effects the level indication with the signals. It is not, as is conventional, only local, but can also be passed on via cable and / or radio link, so that a remote reading can be called up automatically or manually as required at predefinable time intervals. The evaluation electronics can be separately or in a housing connected to the flange 11 , e.g. B. housed in the lid 12 . It is also possible to provide a container (not shown) on the flange 11 for batteries or for an external power supply, in or on which there can also be a display (also not shown) for an analog and / or digital display.

Significant advantages of the invention based on the fact that the elements 20/22 He to the level with the sensor 40 grasp not mechanically connected, but are ma gnetisch coupled. The electronics can therefore be spatially separated from the mechanics. If the level indicator 10 has been serviced or z. B. his electronic part is changed out, consequently you do not have to empty a pressurized container, which saves considerable time and money. In the context of the invention, it also falls to complete the tube 14 under atmospheric pressure, for. B. by brazing at both ends. In combination with a known overfill protection, it is also possible to provide a through-channel and a ring seal on the tube 14 and on the rod 16 an optionally releasable closure element which can be moved into the through-channel to abut the ring seal.

The invention is not limited to one of the above-described embodiments, but can be modified in many ways. However, it can be seen that a device ( 10 ) is equipped with a GMR sensor ( 40 ) which detects a magnetic field direction without contact, which is on or in a bearing part ( 26 ) a float rod ( 22 ) whose angular position corresponds to the level. The GMR sensor ( 40 ) is located at the end of a rod ( 16 ) which is guided in a tube ( 14 ) attached to a container by means of a flange ( 11 ) in a rotationally fixed manner. There is at the lower end for the float rod ( 22 ) an axis ( 25 ) with a bearing pin ( 28 ) between z. B. two Ma gneten ( 50 ), which are located on / in the bearing part ( 26 ). Electrical signals generated by the GMR sensor ( 40 ) can be shown on a display as a near or far display.

All arising from the claims, the description and the drawing Features and advantages, including structural details, spatial arrangement conditions and process steps can be used both individually and in a wide variety of ways Combinations be essential to the invention.

Reference list

a distance
b width dimension

10th

Level indicator

11

flange

12th

cover

13

Sealing rings

14

pipe

16

Rod

18th

lower end

19th

top end

20th

swimmer

22

Float rods

24th

joint

25th

axis

26

Bearing part

27

Counterweight

28

Bearing bolt

29

Axial lock / washer

30th

Cable version

40

GMR sensor

42

Probe approach

44

Nose / notch

46

slot

48

Flattening

50

Permanent magnets

55

Segment / delimiter

Claims (11)

1. Level indicator ( 10 ), with a flange ( 11 ), on which a tube ( 14 ) which can be inserted into a container is attached and guides a rod ( 16 ), the lower end ( 18 ) of which is articulated to a float linkage ( 22 ) and to which a magnetically controllable display device is assigned, characterized in that the rod has a GMR sensor ( 40 ) which faces a magnetically polarized bearing part ( 26 ) of the float joint ( 24 ) without contact. 2. Level indicator according to claim 1, characterized in that the GMR sensor ( 40 ) attached to the circumference of the lower rod end ( 18 ) and the rod ( 16 ) with respect to the tube ( 14 ) is rotatably arranged so that the GMR sensor ( 40 ) detects the magnetic field of the bearing part ( 26 ). 3. Level indicator according to claim 1 or 2, characterized in that the tube ( 14 ) has a nose, notch ( 44 ) or the like. As a twist protection in a recess ( 46 ) of the rod ( 16 ) engages. 4. Level indicator according to one of claims 1 to 3, characterized in that the bearing part ( 26 ) has two mutually associated permanent magnets ( 50 ) which are diametrically opposed to each other. 5. Level indicator according to claim 4, characterized in that the distance (a) between the permanent magnets ( 50 ) corresponds in size to a width dimension (b) of the GMR sensor ( 40 ). 6. Level indicator according to claim 4 or 5, characterized in that the bearing part ( 26 ) is provided with a swivel angle limiter ( 55 ). 7. Level indicator according to claim 6, characterized in that the swivel angle limiter is an integral with the bearing part ( 26 ), its axis (L) concentrically assigned arc element, segment ( 55 ), an angle or the like. That by stop the tube ( 14 ) determines the maximum deflections of the float rod ( 22 ). 8. Level indicator according to one of claims 1 to 7, characterized by a combination with an overfill protection, for example by a passage and an annular seal on the tube ( 14 ) and on the rod ( 16 ) there is a closure element which is in the passage for contacting the Ring seal is movable. 9. Level indicator according to one of claims 1 to 8, characterized records that means for remote transmission and Remote reading are coupled, either wired and / or via a Radio link. 10. Level indicator according to claim 8 or 9, characterized in that an electronic evaluation unit is housed in a housing ( 12 ) connected to the flange ( 11 ) or separately and can be activated and / or called up manually at predefinable time intervals or as required. 11. Use of a GMR sensor to measure the level in liquid or LPG containers.