DE19703346A1 - Parabolic antenna for measuring the level in containers - Google Patents

Description

The invention relates to a parabolic antenna for focusing of transmission pulses when measuring the level in closed containers with a combined transmission and Receiving device with which transmit pulses over the Parabolic antenna on the surface of the product Level should be measured, directed and their Echo impulses after reflection on the surface of the Filled goods again from the combined transmit and Receive receiving device via the parabolic antenna the antenna to carry out the measuring device an opening of the container is foldable and from the running time the pulses from the transmitter to the surface of the Filling goods and the distance back to the receiving device between the transmitting and receiving device and the The surface of the product is determined and from this the level in the Container calculated and the level signal analog and / or is output digitally for further processing. The Further processing can be done in a process Component, such as recorder, indicator or a process-related Component of a process control system or programmable logic controller.

As send and receive devices have Ultrasonic sensors and to an increasing extent Proven microwave sensors. Without using the To rule out invention for ultrasonic sensors be assumed that the Level meter around a microwave level meter acts. But not only for measuring the level in Such devices are used in containers or tanks, but also in process engineering equipment, such as e.g. B. reactors, centrifuges, mixers, funnels, sifters,  or heat treatment furnaces and similar devices, which in the food, pharmaceutical, bio, gene and Find petrochemical applications. Except for the one described Devices also come with pulse methods (transit time measurement methods) according to the FMCW (Frequency Modulated Continous Wave) - Procedure for use. Such microwave Level meters are available with a rod or a Horn antenna equipped.

It very often occurs in process measurement technology or Process control engineering that the fill level of a medium below difficult and / or confined spaces shall be. Namely, when the surface of the Medium swallows a large part of the transmission energy, d. H. the product surface is wavy, the product is small Dielectric constant around 1.2 to 2.0 or the measuring point near the container wall or from Agitators, entries or other disturbing internals located. In addition, the more precise the measurement is made should, and the more difficult the conditions at the measuring site are, in order to so more value must be placed on a suitable antenna system be placed.

Based on the known equation

there are:
P _R - received power; P _T - outgoing power; D - diameter of the parabolic antenna; H - container height, measuring distance; δ - reflection coefficient as a function of product, type of product surface, etc .; λ - wavelength, in such a case it is known and customary for the person skilled in the art to focus the transmit pulse via a parabolic antenna and to direct an amplified, concentrated pulse onto the product surface. The use of such a parabolic antenna means a high level of measurement accuracy, which is also sufficient for official use, but the disadvantage of the parabolic antennas used so far is that the diameter of rod or horn antennas is usually 80-200 mm, the diameter of previously known parabolic antennas 200- 800 mm, even 1200 mm. This means that when such measuring devices are installed in existing closed containers or other process engineering apparatuses, installation openings with equally large diameters have to be introduced and releasably closed again with lids or flanges. Very often, however, the ideal measuring location, approx. 0.15 × 0.3 × radius of the container wall, is at a point where such large openings cannot be made in the container wall or the lid of a container. Thus, a suitable measuring device focusing on the transmission pulse is available, but because of the size of the opening required for this purpose, it can only be introduced with considerable effort.

To overcome this disadvantage, the German patent suggests 195 00 324 an antenna reflector in front of which consists of several pivotable reflector segments and each Segment to one, through an opening in the container insertable mounting cylinder over a uniaxial Swivel is supported and the segments over one Actuator in an angled with respect to the cylinder axis Location can be pivoted.

The disadvantage of this antenna reflector is that a Actuator triggered, only a pivoting of  Reflector segments in one opposite the cylinder axis angled position so opening takes place while a forced swiveling of the segments into one position the axis of the fastening cylinder, i.e. a closing, which alone is a re-execution of the antenna from the Container allows in the device according to this Patent is not provided.

The harsh environmental conditions at the measuring location within the However, containers very quickly cause such a strong one Pollution of the antenna reflector that in the case of a necessary disassembly and re-deployment of the antenna the container is impossible to close or strong is hindered, so that when attempted inevitable Closure of the reflector even with damage can be expected.

From US-PS 4,683,475 is also a foldable Antenna reflector has become known, which instead of stable individual elements from a foldable flexible metal-coated film. An axially displaceable The main slide is connected to the shield rails. The axial displacement causes opening and folding of the antenna reflector. Although the one shown here Antenna reflector also for reception and reflection of microwaves is the task and therefore the design of the antenna in the transmission of high-frequency signals. It is for the present case completely unsuitable for use in process technology.

In contrast, the invention is based on the object propose foldable dish antenna, which folded into an opening of smaller diameter of a container inserted inside the container forcibly opened and in case of need  can also be forcibly folded and executed again can.

This problem is solved by the in the claims marked features. Embodiments of the invention are marked in the subclaims.

The invention will be described in more detail with reference to the drawings will.

Show it

Figure 1 is a representation of a microwave level meter, in which the parabolic antenna is applied.

FIG. 2 shows a section of the microwave fill level measuring device shown in FIG. 1 with a first exemplary embodiment of the foldable antenna;

Fig. 3 shows a second embodiment of the foldable antenna;

Fig. 4 shows another embodiment of the foldable antenna.

In Fig. 1, 1 is a level measuring device, which is to be an example of a microwave level measuring device. The fill level measuring device is used to determine the fill level of a measuring medium which is located inside a container and to output the measured value in analog and / or digital form for further processing. For this purpose, the fill level measuring device 1 is screwed by means of a device flange 11 to a container flange 20 which encloses the opening 21 of a container 2 . The container 2 is indicated by a short piece of the container wall or the container cover 22 . The fill level measuring device has a housing 12 , in the interior of which are the electrical / electronic components with which the fill level measuring device is operated and the measurement signal is generated and transmitted. In the direction of the interior of the container, the antenna tube 13 extends from the device flange 11 and the combined microwave transmitter and receiver 14 is arranged at the end facing away from the flange. Between the device flange 11 and the microwave transmitter and receiver 14 , a parabolic antenna 3 is connected to the antenna tube 13 in such a way that the parabolic screen 31 rotates symmetrically about the axis of symmetry of the antenna tube 13 . The distance between the transmitting and receiving device 14 and the parabolic antenna 3 is selected such that the transmitter and receiver 14 are located exactly in the focal point of the parabolic antenna 3 . The transmitting part of the transmitting and receiving device 14 emits a microwave in the direction of the inner wall of the parabolic screen 31 . This is reflected by the tangent property of the paraboloid in such a way that the microwave is directed parallel to the longitudinal axis of the antenna tube 13 onto the filling material located in the interior of the container and after reflection on the surface of the filling material acting as a plane of reflection again reaches the parabolic screen 31 of the parabolic antenna 3 as an echo wave. is reflected there again and is now focused in such a way onto the receiver 14 located at the focal point.

In order to arrange the parabolic antenna 3 inside the container 2 , the opening 21 must correspond to the outside diameter of the antenna 3 . Such a large opening is very often not available at all or can only be introduced into the container wall or the container lid with great effort, or existing large flange openings have already been assigned elsewhere. In addition, the introduction of such a large opening, which must be closed again pressure-tight, means a considerable amount of work and costs. The measuring device must then also have such a large device flange that its diameter corresponds to the diameter of the container opening and thus the parabolic antenna. In order to remedy this disadvantage, it has already been proposed to make the parabolic antenna 3 foldable, so that the antenna can be inserted through the opening of the container wall or the container lid in the closed state and opened inside the container. In the further development of this prior art, the pivoting of the antenna elements is to be done by means of the adjusting device 15 . The hexagon 16 indicates these adjustment options through the effect of the torque of an attached wrench. When such antennas are used in process technology, they are exposed to enormous environmental pollution. Changing temperatures, dry and moist dusts, caked filling goods, etc. limit the mobility of the adjustment segments considerably after a short time. In addition, it is important that the opening and closing of the parabolic antenna take place completely in order to achieve the functionality, therefore the invention proposes to forcefully open and close the antenna from the opening 21 . In order to also be able to clean the antenna from the outside in the event of a functional impairment due to extreme dirt or extreme caking, a cleaning device 17 , 18 is arranged on the antenna tube 13 . With the help of nozzles, a jet of compressed air or a cleaning liquid is directed onto the antenna and this frees it from extreme dirt which impairs its function, or extreme caking in the case of filling goods such as tar, bitumen and the like. A feed line 19 penetrates the flange 11 and can thus be connected from outside the container.

Fig. 2 shows a first embodiment of the invention. Here, with the same position numbers, part of the fill level measuring device 1 , the container 2 , the flanges 11 and 20 , the opening 21 , the container wall 22 , and the antenna tube 13 are shown. The parabolic antenna 3 is only represented by two shield rails 32 , 33 . All other parts have been omitted for clarity. In FIG. 2, the left shield rail 32 takes up a position in the pivoted-out position, that is to say as with the antenna open, and the right shield rail 33 , shown in broken lines, takes a position with the antenna closed. The two shield rails 32 , 33 are each mounted in a pivot bearing 42 . In a position as shown on the right, the antenna is inserted through the opening 21 into the container 2 and unfolded by means of the actuating gear 34 before the flange 11 is put on. For this purpose, the spindle 35 is rotated about its axis with the torque of a key placed on the fit 36 such that the slide 37 moves in the direction of the bearing ring 38 . The spindle 35 is moved in a translatory manner via the spindle nut 39 attached to the antenna tube 13 . On the side facing the transmitting and receiving device 14, receptacles 40 are formed on the slide 37 . The spherical ends 41 of the short leg of the shield rails 32 , 33 engage in the receptacles 40 . The parallel plates of the receptacles 40 are in a positive connection with the spherical ends 41 . The movement of the slide 37 causes a moment to be exerted on the spherical legs 41 of the shield rails 32 , 33 so that they are pivoted about the pivot point of the pivot bearings 42 and assume a precisely defined position in the stop of the slide 37 on the bearing ring 38 , which of the Functional position of the antenna 3 corresponds. In this position, the level meter can now be placed correctly on the flange 20 and the flanges 11 and 20 can be screwed together.

In the opposite sense, the spindle 35 exerts a pull on the slide 37 via the abutment 43 . By this train, the slide is moved in the direction of the opening 21 and the spherical legs of the shield rails 32 , 33 are pivoted so that the shield rails assume a position as shown on the right-hand side and in which the antenna 3 easily passes through the opening 21 can be guided from the container 2 . It is now easy to see that, with the aid of the actuating gear 34, the parabolic antenna 3 can assume any position, even from considerable contamination, from completely closed to fully open.

The embodiment shown in FIG. 3 differs from that shown in FIG. 2 only in that instead of the spindle 35, the antenna tube 13 itself is provided with a movement thread 51 . Instead of the receptacles 40 , this embodiment shows a pressure plate 52 in a positive connection with the spherical legs of the shield rails 32 , 33 . Furthermore, the antenna tube 13 has a spring holder 53 running around the tube. Tension springs 54 , 55 are arranged between the spring holder 53 and the shield rails 32 , 33 . In this embodiment, the spring elements 54 , 55 cause the antenna 3 to be in a folded position when it is introduced into the container 2 through the opening 21 . In contrast to the embodiment according to FIG. 2, the pivoting open of the antenna takes place in that the slide 37 is rotated about its axis and moved along the thread 51 in the direction of the bearing ring 38 . Through this movement, the pressure plate 52 exerts a moment on the spherical legs of the shield rails 32 , 33 , so that these are pivoted and opened against the action of the tension springs 54 , 55 .

A rotary movement of the slide 37 in the other direction will lead to a movement of the slide 37 in the direction of the opening 21 so that the shield rails 32 , 33 are pivoted back under the action of the spring force of the tension springs 54 , 55 . If the movement of the slide 37 occurs far enough, the two shield rails 32 , 33 will assume a position in which the antenna is closed and can be easily carried out from the container 2 . In this embodiment, too, the parabolic antenna 3 can be opened in any position from the opening 21 and closed again under the action of the tension springs even when it is dirty.

FIG. 4 shows the further development of the exemplary embodiments shown in FIGS. 2 and 3. Here, too, a smaller section of the microwave level measuring device 1 is shown. The illustration is limited to the parabolic antenna 3 and the actuating device. Also in Fig. 4 is back on the left side of the opened and demonstrated the closed position of the parabolic antenna on the right side.

The parabolic antenna 3 consists of a number of shield rails 133 , of which only 5 are shown in the exemplary embodiment. For insertion through the opening 21 into the container 2 , the antenna will take a shape as shown on the right side. To reflect the microwaves, the shielding rail 133 spans a flexible metal foil 144 , which is made of a temperature-resistant, pressure-resistant, corrosion-resistant and is neutral against static charges. This foil can be made of steel, stainless steel, aluminum or a nickel-chrome-manganese alloy, for example. A metallized plastic film with the necessary rigidity can also be used. In order to give the film antenna the rigidity necessary for the function, cross struts 134 extend between the shield rails 133 . However, these do not run around the entire parabolic screen, but leave symmetrical sections 135 between adjacent screen rails free, through which the film can fold in when the antenna is closed. For opening and closing of the antenna at the antenna tube 13 is a sleeve 145 is integrally formed or permanently connected. The sleeve 145 has grooves 146 extending in the axial direction along its circumference. These are provided symmetrically at the same distance on the outer surface of the sleeve 145 . The grooves 146 are usually made in a machining process. The actuator has a screw gear 147 for opening and closing the screen. The screw gear 147 is formed from a pair of elements, namely the screw slide 148 and the clamping nut 149 . A retaining ring 150 runs around the outer surface of the clamping nut 149 in a groove at the end facing the sleeve 145 . At the periphery of the retaining ring 150 bearing elements are formed, to intervene at which the expansion braces 151st The connection between the retaining ring 150 and the clamping nut 149 is designed to fit a light sliding block, so that the bearing elements of the retaining ring 150 maintain their position on the circumference of the clamping nut 149 even when the clamping nut 149 is rotated about its own axis.

Further bearing elements 152 form a form-fitting functional unit with the screw slide 148 and have guide rollers, via which the bearing elements 152 are movably mounted in the grooves 146 of the sleeve 145 . The bearing elements 152 form the end of the antenna rails 133 which faces the antenna tube 13 . They form the attachment and pivot point and thus the crown of the dish 3 .

Due to the rotary movement of the clamping nut 149 about its own axis by means of the action of a torque on the key surfaces 136 , the screw gear 147 is set in motion and causes the screw slide 148 to be moved in the direction of the microwave sensor and receiver 14 . At the same time, the bearing element 152 is moved in the same direction and the shield rails 133 are held in position by the mounting 153, which forms a sewing bracket, of the expansion struts 151 , so that the shield rails 133 perform a pivoting movement about the pivot point 153 and the parabolic antenna opens. This movement continues until the bearing elements 152 have reached a position at the end of the grooves 146 . After completing this process, the parabolic antenna assumes a position as shown on the left side of FIG. 4. Conversely, due to the opposite rotation of the clamping nut 149, the bearing elements 152 are moved in the direction of the opening 21 until the rollers have reached the upper end point of the grooves 146 and the shield rails 133 have returned to their original position.

The metallic parts of the dish are either out a material resistant to the measuring media, such as. B. high-alloy steels or with one of these Media resistant plastic covered. But you can also be made of a suitable plastic.

The execution of the thread of the screw gear 147 as a fine thread, for. B. metric fine thread, e.g. B. according to DIN 13 extends the possibility of determining the position of the shield rails considerably. As a result, the shape of the parabolic screen can be reproducibly adjusted precisely according to the greatest efficiency of the reflection of the microwave lobe, depending on the nature of the reflection plane.

If the parabolic antenna has to be folded up and running the microwave meter gives the Application of a screw gear through its translation the advantage that the antenna despite a considerable Pollution can be closed again without damage to the screen rail struts and Slide is done.

Of course, the invention is not limited to that Embodiment of the formed from a flexible film Parabolic antenna limited. The forced closing and Opening by means of the device according to the invention is also for one made of stable individual elements or segments composite antenna shield possible.

Claims (21)

1. Parabolic antenna for focusing transmit pulses when measuring the fill level in closed containers with a combined transmitting and receiving device with which transmit pulses are directed via the parabolic antenna onto the surface of a medium whose fill level is to be measured, and whose echo pulses after reflection on the surface of the contents are received again by the combined transmitting and receiving device via the parabolic antenna, the antenna for carrying out the measuring device being foldable through an opening in the container, characterized in that the parabolic antenna ( 3 ) has a device ( 15 , 34 , 37 , 54 , 55 , 147 ), by means of which a closing folding and opening unfolding of the parabolic screen ( 31 ) is forced. 2. Parabolic antenna according to claim 1, characterized in that by the device ( 15 , 34 , 37 , 54 , 55 , 147 ), the shape of the paraboloid-determining shield rails are held in any desired position from open to closed. 3. Parabolic antenna according to claim 1, characterized in that you device is formed by an axially movable actuator ( 34 ). 4. Parabolic antenna according to claim 1, characterized in that the device is formed by the interaction of axially movable rotary valve ( 37 ) and spring elements ( 54 , 55 ). 5. Parabolic antenna according to claim 1, characterized in that the device is formed by a screw gear ( 147 ). 6. Parabolic antenna according to claim 3, characterized in that the axial movement of the actuating gear ( 34 ) causes the pivoting of the shield rails ( 32 , 33 ) about a pivot point ( 42 ). 7. Parabolic antenna according to claim 4, characterized in that the pivoting of the shearers ( 32 , 33 ) about a pivot point ( 41 ) against and / or with the action of spring elements ( 54 , 55 ). 8. parabolic antenna according to claim 5, characterized in that the screw gear ( 147 ) from the pair of elements screw slide ( 148 ) and clamping nut ( 149 ) is formed. 9. parabolic antenna according to claim 5, characterized in that the crown of the parabolic antenna forming the ends of the shield rails ( 133 ) as axially in grooves ( 146 ) movable bearing elements ( 152 ) are formed, which the point of engagement of one of the axial movement of the helical gear ( 147 ) caused pivoting movement about a pivot point coinciding with a sewing bracket ( 153 ) of the shield rails ( 133 ). 10. Parabolic antenna according to claim 5, characterized in that the parabolic screen ( 31 ) has expansion struts ( 151 ) which on the one hand are mounted on a retaining ring ( 150 ) of the clamping nut ( 149 ) and on the other hand coincide with the sewing bracket ( 153 ) of the screen rails ( 133 ) form the pivot points of the pivoting movement of the shield rails ( 133 ). 11. Parabolic antenna according to claim 1, characterized in that the parabolic screen ( 31 ) from a screen rails ( 133 ) and cross struts ( 134 ) formed from a lattice frame and from a flexible film ( 144 ) is formed. 12. Parabolic antenna according to claim 11, characterized in that the, the surface of the antenna forming film ( 144 ) is formed from a measuring medium-resistant metal foil or a metallized plastic film. 13. Parabolic antenna according to claim 11, characterized in that the parabolic screen ( 31 ) forming the screen rails ( 133 ) and cross struts ( 134 ) made of a media-resistant metal or are coated with a media-resistant plastic. 14. Parabolic antenna according to claim 11, characterized in that on the circumference of the parabolic screen ( 31 ) of cross struts ( 134 ) released sections are distributed symmetrically between adjacent screen rails ( 133 ), in which fold the segment of the screen film ( 144 ). 15. Parabolic antenna according to claim 11, characterized in that the screen film ( 144 ) with the screen rails ( 133 ) and cross struts ( 134 ) is connected by gluing, welding, and any other method known to the person skilled in the art. 16. Parabolic antenna according to claim 11, characterized in that the parabolic screen ( 31 ) forming screen rails ( 133 ) and cross struts ( 134 ) are connected by welding, or any other method known to the person skilled in the art. 17. Parabolic antenna according to claim 1, characterized in that the one that triggers the folding and unfolding movement Drive by hand or by means of electrical or pneumatic auxiliary energy takes place.   18. Parabolic antenna according to claim 5, characterized in that the screw gear ( 147 ) forming element pair ( 148 , 149 ) has a movement thread, advantageously a fine thread. 19. Parabolic antenna according to claim 1, characterized in that the paraboloid consists of dimensionally stable individual elements or segments is formed. 20. Parabolic antenna according to claim 1, characterized in that the level measuring device ( 1 ) has means for cleaning the parabolic antennas ( 3 ). 21. Parabolic antenna according to claim 20, characterized in that the means connected to an outer supply line ( 19 ) are pneumatic or fluidic cleaning nozzles ( 17 , 18 ).