CH665283A5 - FLOAT IN A MAGNETIC LEVEL INDICATOR. - Google Patents

Description

DESCRIPTION The invention relates to a float in a magnetic level indicator which is equipped with a vertical guide for the float held upright and has an elongated measurement indicator which is equipped with a series of magnetically responsive display elements which can be actuated as a function of the height of the float, which float is hollow and has the outer basic shape of an elongated circular cylinder, and with a permanent magnet which is arranged inside the float.

Such a float is known from DE-GM 8 311 354. With such a level indicator, it is desirable that a magnetic field bundled as sharply as possible passes through the row of magnetically addressable display elements, so that the respective altitude of the permanent magnet or the float can be displayed as clearly as possible.

The object of the invention is to design a float of the type mentioned in the introduction in such a way that it generates a magnetic field which is bundled as closely as possible radially to the float axis.

The invention is characterized in that the float is made of non-magnetizable stainless steel, that a circular disk-shaped iron plate is fastened within the float transversely to the float axis coinciding with the axis of the cylindrical shape, the edge of which extends around the inside of the wall of the float, and that two permanent magnets are provided, which are fastened on both sides of the iron plate and are polarized and arranged concentrically to the float axis and with poles of the same name.

A radially strongly bundled field is generated by the permanent magnets opposing each other. This is further supported by the iron plate, which advantageously also serves to keep the permanent magnets inside the float. For this purpose, the iron plate is expediently welded to the wall of the float along its edge.

In particular, if the magnetically responsive display elements are visual indicators, it is desirable that the display coincides with the level actually displayed. It is also possible to have a display with a certain offset between the display and the level, but this is not so easy to read. For this reason, the float is appropriately balanced with respect to the liquid to be measured so that the iron plate is at the level of the liquid. Then the magnetic field actuating the display elements is also at this level.

The object of a further development of the invention is to ensure that the float can move along its guide as smoothly as possible so that it can follow the level changes of the liquid without problems. This object is achieved in that the float is top-heavy in terms of its weight distribution, so that it swims inclined to the vertical axis of the vertical guide and only a first tangential, punctiform contact on its lower region and a second tangential, punctiform contact on its upper region finds.

The two point-like contacts offer minimal frictional contact, especially in cases where contamination and incrustation from the measuring liquid can be expected.

In a preferred embodiment of the invention according to claim 7 beads are provided which are advantageous for mechanical stabilization of the float and which facilitate the entrainment of the float within a bypass tube through the liquid.

The invention will now be explained in more detail with reference to the accompanying drawing.

The drawing shows:

1 shows the bypass tube of a liquid container with a float, an indicator equipped with rollers and an electrical transducer,

2 shows the partial view according to arrow II from FIG. 1,

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3 shows the partial section according to arrow III from FIG. 1,

4 in partial section IV, the U-profile rail for the indicator,

5 shows the section V from Figure IV,

6 is a top view of a bearing washer,

7 shows one half of a roller of the indicator,

8 the view according to arrow VIII from FIG. 7,

9 shows section IX from FIG. 7,

10 shows the circuit strip of the sensor from FIG. 3, viewed in the direction of arrow X,

11 shows the circuit strip from FIG. 3, seen against the direction of the arrow XI, and

12 shows a second exemplary embodiment of a magnetic level indicator, in which the float is guided in an immersion tube arranged inside the liquid container.

According to FIG. 1, 1 denotes a bypass tube which is flanged to a liquid container (not shown) with two flange connections 2, 3. There is a liquid inside the liquid container, the level of which is to be measured or displayed between the two flange connections. The bypass tube 1 and possibly also the flange connection 2, 3 are made of non-magnetizable material, preferably stainless steel. The bypass tube extends with its axis 23 vertically and parallel to the measuring section 15.

A float 5, which has the basic shape of an elongated circular cylinder and whose outside diameter according to double arrow 6 is slightly smaller than the inside diameter according to double arrow 4, swims within the bypass tube, which has a circular inner cross section with a diameter according to double arrow 4. The float 5 is hollow , spherically rounded at both ends and has a total of four indented beads 7, 8, 9, 10 each extending over the entire circumference. The float 5 is made of non-magnetizable material, preferably stainless steel.

An iron plate 11 is arranged within the float 5 perpendicular to the float axis 12. The float axis 12 coincides with the cylindrical symmetry axis of the float shape. This iron plate 11 abuts with its entire edge on the inside of the wall of the float and is welded to it over the entire circumference. Permanent magnets 13, 14 are attached to the iron plate on both sides, which are arranged, formed and magnetically polarized coaxially to the float axis 12. The polarizations of the two permanent magnets are opposite to each other, as indicated by the polarities N, S shown in FIG. 1. Both permanent magnets have their south pole on their end face facing the iron plate 11 and their north pole on the end face facing away from the iron plate (or vice versa). The result is a tightly bundled radial magnetic field 22 in a radial extension of the edge of the iron plate 11, which, even tightly bundled, passes through the indicator 20 and sensor 21 mounted on the outside of the bypass tube 1 and then continues with weaker bundling, as is the case, for example, with individual ones Lines of force, which are shown in Figure 1, is indicated.

The float is top-heavy, that is, it is heavier at the top than at the bottom, so that the float axis 12 is at a very small acute angle 16 to the vertical axis 23 of the bypass tube 1. The float only finds a first tangential, point-shaped contact 24 with its lower edge and a second tangential, point-shaped contact 25 with its upper edge with the inner wall of the float. In the drawing

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The float assumes a position which corresponds to the lowest liquid level 26 to be displayed.

The weight of the float is balanced with respect to the specific weight of the liquid to be measured, so that the iron plate 11 is exactly at the level 24 of the liquid.

The indicator 20 consists of a U-shaped rail 31 accommodated in an elongated protective box 30, between the two legs of which a row of rollers 33, 34, 35, 36, 37 are rotatably mounted with horizontal roller axes. The rollers are all the same among themselves.

Each of the rollers consists of two plastic roller halves. Such a roller half 40 is shown in FIGS. 7, 8 and 9. This roller half 40 belongs to the roller 33, see also FIG. 4, the other roller half of which is designated 41. The two roller halves 40 and 41 are identically shaped and fit together along a parting plane 45 passing through the roller axis 44. Each roller half has a projection 46 and a correspondingly shaped recess 47. The projection of the roller half 41 corresponding to the projection 46 fits into the recess 47 and vice versa.

Each roller has axially parallel stub axles 50, 51 at both ends, each half belonging to the two roller halves. Both roller halves have open recesses 52 in the center of the parting plane 45, into which a circular-cylindrical, rod-shaped permanent magnet 54 with its longitudinal direction transverse to the roller axis 44 is inserted in a form-fitting manner. The stub axles 50, 51 are each in a central, circular bearing hole 56 ... an associated, circular bearing disk 57 .... Two bearing disks are provided for each roller and the bearing disks are designed identically and cylindrically symmetrically, preferably as an automatic turned part made of Teflon .

The two roller halves of a roller are held together by the stub axles 50, 51 inserted in the bearing hole 56 and, if appropriate, additionally by the fact that the plug connections in which the projection 46 and the recess 47 are involved are designed as a clamp connection or by gluing. The respective one half of the roller, for example the roller half 40, of the roller 33 is provided on its circumference with a first marking, for example a red coloring, while the other associated roller half 41 of the same roller 33 is provided with a different marking, for example one White coloring, is equipped. This different marking is indicated in FIGS. 1, 2, 3 and 12 by blackening or leaving white.

The two legs 60, 61 of the U-shaped rail 62 have inwardly open, T-shaped, that is undercut, bearing grooves 63, 64, into which the bearing disks 69, 70, 71 ... form-fitting with play, as shown in FIGS 5 can be seen to fit. The bearing disks are lined up in the bearing grooves with contact and thereby support one another, with the result that the bearing holes have exactly the same spacing in accordance with the exactly identical configuration of the bearing disks. The bottom bearing washers, that is, the bearing washer 70 from FIG. 5, is supported with the opposing bearing washer on a lock fastened to the U-shaped rail 62, so that all the bearing washers are coaxially opposed in pairs.

The diameter according to double arrow 72 of a bearing washer is somewhat larger than the outer diameter 73 of a roller. The difference in diameter corresponds to the desired tolerance distance between the rollers, which is required so that the rollers can rotate freely from one another.

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The permanent magnet 54 is magnetized permanently magnetically in the longitudinal direction, so that the viewer of FIG. 7 has one pole turned and the other pole turned away.

The rollers and the bearing disks are designed identically to one another, as described in the text relating to FIGS. 4 to 8. When the float with the permanent magnets 13 and 14 moves up and down in the bypass tube 1, the rollers above the iron plate 11, i.e. above the level 26, assume a position with vertically oriented permanent magnets 54, with the darkly marked roller half facing the float shows, and below the level 26 a position rotated by 180 degrees, with the brightly marked half of the roller facing the float. Only three rollers are in an intermediate position. The one that is exactly at the level of level 26 stands with a horizontally oriented permanent magnet, ie with one roller half up and the other down, and the two adjacent rollers have inclined intermediate layers.

The rollers are covered on the outside by a transparent disk 80 which is inserted in corresponding grooves 81, 82 of the legs of the profile rail. Through this disk 80, the rollers and their marking are visible with the viewing direction according to arrow 84.

The measuring transducer 21 extends parallel to the indicator and thus also along the measuring section. The measuring transducer has a square tube 100 made of non-magnetizable material, for example stainless steel or plastic, within which there is a circuit strip 101 which extends over the entire measuring section. The circuit strip 101 has a series of resistors 102, 103, 104, 105, which are electrically connected in series in series and are mounted on the rear side of the circuit strip 101. Electrically actuated contact switches 106 to 108 are mounted on the front of the circuit strip,

whose contacts 109, 110 are axially parallel at both ends and inserted into an evacuated glass tube 111. The contact switches can be actuated magnetically by magnetizing the one or both contacts 109, 110. The contact switches are connected as short-circuit taps between two resistors, so that, depending on which of the contact switches is closed, a more or less long piece of the resistor chain formed by the resistors 102, 103, 104, 105 is interrupted. This interruption and the resulting change in the resistance value s of the entire series of resistors is clearly related to the height level of the respectively closed contact switch and causes an electrical display or control signal dependent thereon.

The circuit strip 101 is arranged on the circumference of the bypass tube io 1 in the region of the narrow bundling of the magnetic field 22, so that the contact switch is actuated which is at the respective height of the iron plate 11 and thus at the liquid level 26.

In order for the roller or the contact switch corresponding to the liquid level to be actuated as precisely as possible, the indicator 20 and the sensor 21 are mounted close to the circumference of the bypass tube 1, that is to say as close as possible to the permanent magnet 13 or 14. For this reason, the indicator 20 and the measuring value transmitter 21 are arranged in different circumferential areas 120, 121, which adjoin one another in this exemplary embodiment.

The exemplary embodiment shown in FIG. 12 differs essentially only in that instead of the bypass tube 1, a dip tube 130 is provided as a guide for the float, which is arranged in the liquid container 131, has an opening 132 at the bottom and a vent opening 134 at the top. The float 133 corresponding to the float 5 is arranged inside the immersion tube 130 and as close as possible to it, but outside the liquid container the indicator 136 corresponding to the indicator 20 is arranged, but preferably not necessarily together with a sensor that is not visible in FIG.

In a modification of the illustrated exemplary embodiments, magnetically actuated limit switches can be provided instead of the measured value transmitter or in addition to the measured value transmitter, as are indicated for example in FIG. 12 under items 140 and 141. The limit switches can have contact switches which are accommodated in evacuated glass tubes, as described in the text relating to FIGS. 10 and 11.

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Claims (7)

665 283 PATENT CLAIMS 1. Float in a magnetic level indicator, which is equipped with a vertical guide for the upright float and has an elongated measurement indicator, which is equipped with a number of magnetically responsive display elements that can be operated depending on the height of the float, which float is hollow is and has the outer basic shape of an elongated circular cylinder, and with a permanent magnet which is arranged inside the float, characterized in that the float (5) consists of non-magnetizable stainless steel, that a circular disc-shaped iron plate (11) transverse to the inside of the float with the axis of the cylindrical shape coinciding float axis (12) is attached, which extends with its edge all around to the inside of the wall of the float, and that two permanent magnets (13, 14) are provided, which are fixed on both sides of the iron plate and concentrate polarized and arranged to the float axis and facing each other with poles of the same name. 2. Float according to claim 1, characterized in that the iron plate (11) is welded along its edge to the wall of the float (5). 3. Float according to one of the preceding claims, characterized in that the float (5) is balanced in weight with respect to the liquid to be measured so that the iron plate (11) is at the level (26) of the liquid. 4. Float according to one of the preceding claims, characterized in that the float (5) is top-heavy in terms of its weight distribution, so that it swims inclined to the vertical axis (23) of the vertical guide (1) and only a first tangential, punctiform contact (24) on its lower area and a second tangential, punctiform contact (25) on its upper area. 5. Float according to claim 4, characterized in that the vertical guide is a bypass tube (1), that the outer cross section of the float (5) is slightly smaller than the circular inner cross section of the bypass tube (1), and that the first contact (24) of the float with the bypass tube at the bottom of the float and the second contact (25) at the top of the float. 6. Float according to one of the preceding claims, characterized in that the upper and lower ends of the float (5) are rounded in a spherical shape. 7. Float according to one of the preceding claims, characterized in that beads are distributed in the length, annularly extending around the entire circumference of the float (5) beads (7) in the float.