AT506020B1 - GAS STORAGE - Google Patents

Abstract

Disclosed is a gas accumulator comprising an outer and an inner diaphragm (1, 2). The inner diaphragm (2) partly surrounds a variable gas accumulator chamber (20). A diaphragm opening (40) for a device for measuring the fill level (41) of the gas accumulator chamber is provided within the outer diaphragm (1). Said device encompasses a level sensor (42) that is attached to a sensor holder (59) which is connected to the edge of the diaphragm opening (40) by means of a connecting element (56'). The connecting element (56') is formed by a tube (46), an end opening of which is connected to the edge of the diaphragm opening (40). The sensor holder (59) comprising the level sensor (42) is mounted on the other end opening of the tube (46) such that the tube (46) is fastened over the diaphragm opening (40) and the level sensor (42) is thus placed at a distance from the diaphragm opening (40) by using the supporting pressure prevailing between the inner diaphragm (2) and the outer diaphragm (1).

Description

äiÄsÄi'itS paleman ^ AT506 020B1 2009-09-15

Description The invention relates to a gas reservoir having an outer and an inner membrane, wherein the inner membrane partially surrounds a variable gas storage space and in the outer membrane a membrane opening is provided for a device for measuring the gas storage space filling level, which comprises a level sensor, which is mounted on a sensor holder, which sensor holder in turn is connected via a connecting element with the opening edge of the membrane opening.

A reliable measurement of the level has proved to be essential for the safe and economic operation of such a gas storage. Used in the conventional level measurement membrane domes with ultrasonic level sensors are made of stainless steel and therefore have a correspondingly high weight, which have proven both from the Fierstellungskosten, from transport and from the stress of the outer membrane ago as unfavorable.

The object of the invention is therefore to provide a gas storage of the type mentioned, for which said disadvantages are not present.

According to the invention this is achieved in that the connecting element is formed by a hose, wherein an end opening of the hose is connected to the opening edge of the diaphragm opening and attached to the other end opening of the hose, the sensor holder with the level sensor, so when using the between supporting pressure of the inner membrane and the outer membrane spans the tube over the membrane opening and thus the filling level sensor is positioned at a distance from the membrane opening.

The thus formed tubular connecting element is characterized by cost Fierstellung, which can be done by means of a flexible material that is much lighter than metal and can be processed in a simple manner. Prerequisite here is the gas and pressure-tight training of the hose and its connection points with the diaphragm opening on the one hand and the sensor holder on the other hand, because otherwise the support pressure between the outer and inner membrane can not be maintained. Also, the transport and assembly simplify significantly, since the invention designed tube is much lighter than the conventional stainless steel diaphragm dome. Furthermore, the sonic behavior can be significantly improved, since due to the flexible tube shape, the noise is low.

As usual, the level sensor may be an ultrasonic sensor, wherein the length of the tube is greater than the blocking distance of the ultrasonic sensor. For ultrasonic reflection distance measurement, this blocking distance in conventional stainless steel domes was a hindrance to the measurement. In the gas storage device according to the invention this disadvantage can be overcome insofar as the inner membrane can be guided up to the outer membrane, since the blocking distance can be bridged by appropriate adaptation of the hose length through the hose. The usable volume of the gas reservoir according to the invention is thereby increased.

Other technical embodiments of Füllabstandsmeß sensors, such. B. optical sensors can also be realized.

According to one embodiment of the invention, the tube may be formed of a flexible material, preferably a fabric-reinforced plastic film which is formed tubular along a longitudinal weld. Compared with the known stainless steel dome, this results in a simplification of the production, which can be generated due to the simplicity of the longitudinal weld with extremely low error rate.

A further cost savings is obtained if, according to a further embodiment of the invention, the tube is formed of the same material as the outer membrane. [0010] It has proved to be very advantageous for the acoustic properties to conically form the tube in a further development of the invention, the diameter of the one end connected to the opening edge of the membrane opening being larger than the diameter of the other end connected to the sensor holder. Disturbing reflections of the reflected sound waves are thereby minimized. A restriction on a particular form of the hose should not be connected with it. It can also z. B. be cylindrical.

Material technically, the boundary of the membrane opening is exposed when using an increased mechanical load, which can be best handled in practice, if in accordance with a further embodiment of the invention, the membrane opening is circular and bounded by an annular flange which is connected to the outer Membrane is connected, and that the one end opening of the hose is sealingly secured by a clamping ring on the annular flange. However, another form of membrane opening of the outer membrane is also included in the scope of protection.

A simple attachment of the sensor holder to the inventive tube is achieved in that the sensor holder is formed from a circular plate and the level sensor is arranged in the center of the circular plate. The plate edge can be permanently and pressure-tightly connected via a flange construction with the end of the tube remote from the outer membrane. Accordingly, the other end of the hose connected to the sensor support may be connected to an annular flange on which the circular plate is mounted with the level sensor. Other geometrical shapes of the sensor holder and other types of connection between the sensor holder and hose can also be provided within the scope of the invention. The formation of the flexible material tube according to the invention makes it possible to improve the acoustic properties of the level measuring device, resulting in improved reproducibility of the device Sets measurement results. An additional improvement according to a further embodiment of the invention, therefore, consist in that the circular plate is formed of plastic, which reduces the disturbing sound reflections in the measurement.

The invention will be explained in detail with reference to the embodiment shown in the drawings. FIG. 1 shows a schematic side view of a gas reservoir according to the invention; FIG. FIG. 2 shows a schematic section through the gas reservoir according to FIG. 1; FIG. Fig. 3 shows a section through a detail of a known apparatus for measuring the level in a gas storage and Fig. 4 shows a detail of the gas storage of FIG. 1 in section.

Fig. 1 and Fig. 2 show a gas storage 10 with an existing gas storage space 20 in its interior, which is partially surrounded by an outer membrane 1, which is spanned in the form of a three-quarter sphere starting from a base foundation 11.

In addition to the outer membrane 1, which forms the outer shell, a variable inner membrane 2 is provided, which can assume a different extent depending on the amount of gas contained in the gas storage 10. The gas supply and discharge lines and other details are not shown. A pressure-controlled support volume or an air volume in the intermediate space 15 between the outer membrane 1 and the inner membrane 2 ensures compensation for expansion or contraction of the inner membrane 2. The shape of the gas reservoir 10 shown in FIGS. 1 and 2 is merely illustrative and may be in another embodiment with an inner and an outer membrane.

In order to measure the level of the gas storage space 20 reliably, a device for measuring the gas storage level 41 is preferably provided at the highest point of the outer membrane 1, which tertiöisd'is the distance between the inner membrane 2 and the 2/6 AT506 020B1 2009-09-15 outer membrane 1 monitored.

Fig. 3 shows a known attachment of the apparatus for measuring the gas storage level 41, which has a level sensor 42 which is mounted on a sensor holder 59, which in turn via a cylindrical connecting element 56 made of metal, for. B. stainless steel is connected by means of a flange construction with the opening edge of the diaphragm opening 40.

Fig. 4 shows the intended for the gas storage 10 according to the invention attachment for measuring the gas storage level 41, wherein the connecting element 56 'is formed by a hose 46. An end opening of the tube 46 is connected to the opening edge of the membrane opening 40 and at the other end opening of the tube 46, the sensor holder 59 is attached to the level sensor 42, so that when using the existing between the inner membrane 2 and the outer membrane 1 support pressure the tube 46th spans over the diaphragm opening 40 and thus the level sensor 42 is positioned at a distance from the diaphragm opening 40.

The tube 46 is formed of a flexible material, preferably a fabric reinforced plastic film, which is formed tubular along a longitudinal weld. In a preferred embodiment, the tube is formed of the same material as the outer membrane.

Preferably, the level measurement by means of acoustic measurement of the distance between the outer and inner membrane 1,2 based on the measured transit times of emitted and reflected sound wave, so that in the illustrated embodiment, the level sensor 42 is an ultrasonic sensor, wherein the length of the tube larger as the blocking distance of the ultrasonic sensor. The distance measurement can also be with other known, z. B. optical sensors are running.

In the embodiment of FIG. 4, the tube 46 is conical, wherein the diameter of the one end connected to the opening edge of the diaphragm opening 40 is greater than the diameter of the other, with the sensor holder 59 connected end. It may be the tube 46 but also cylindrical or in any other suitable form.

The membrane opening 40 is circular and bounded by an annular flange 50 which is connected to the outer membrane 1 by the circularly recessed at this point membrane 1 beaten around the flange 50 and the membrane edge region on the underside of the outer Membrane 1 is welded. At the same time, the one end opening of the hose 46 is sealingly secured by a clamping ring 51 on the annular flange 50. Along the circumference of the flange 50 to evenly spaced bolts 70 are arranged, with the aid of the clamping ring 51 relative to the flange 50 can be tightened. Other types of fasteners are known to those skilled in the art and can be applied accordingly.

Fig. 4 shows the present during operation of the gas storage, stretched by the support pressure position of the tube 46, in which the level sensor 42 is located just above the diaphragm opening 40. The sensor holder 59 is formed of a circular plate 57, wherein the level sensor 42 is disposed at the center of the circular plate 57, which is made of plastic.

The other, connected to the sensor holder 59 end of the hose 46 is connected to an annular flange 58, on which the circular plate 57 is attached to the level sensor 42. 3.6

Claims (9)

1. A gas reservoir with an outer and an inner membrane (1, 2), wherein the inner membrane (2) partially surrounds a variable gas storage space (20) and in the outer membrane (1) Membrane opening (40) for a device for measuring the gas storage space filling level (41) is provided, which comprises a level sensor (42) which is mounted on a sensor holder (59), which sensor holder (59) in turn via a connecting element (56, 56 ') is connected to the opening edge of the diaphragm opening (40), characterized in that the connecting element (56') is formed by a hose (46), wherein an end opening of the hose (46) is connected to the opening edge of the diaphragm opening (40) and at the other end opening of the tube (46), the sensor holder (59) is mounted with the level sensor (42), so that when using the between the inner membrane (2) and the outer Membrane (1) existing support pressure spans the hose (46) over the diaphragm opening (40) and thus the level sensor (42) is positioned at a distance from the diaphragm opening (40). 2. Gas storage according to claim 1, characterized in that the hose (46) made of a flexible material, preferably a fabric-reinforced plastic film is formed, which is formed tubular along a longitudinal weld. 3. Gas storage according to claim 1, characterized in that the hose (46) made of the same material as the outer membrane (1) is formed. 4. Gas storage according to one of claims 1 to 3, characterized in that the hose (46) is conical, wherein the diameter of the one, with the opening edge of the diaphragm opening (40) connected to the end of the end of the larger diameter of the other, with the sensor holder (59) connected end. 5. Gas store according to one of claims 1 to 4, characterized in that the membrane opening (40) is circular and bounded by an annular flange (50) which is connected to the outer membrane (1), and in that one end opening of the Hose (46) by a clamping ring (51) on the annular flange (50) is sealingly secured. 6. Gas storage according to one of claims 1 to 5, characterized in that the sensor holder (59) formed from a circular plate (57) and the level sensor (42) in the center of the circular plate (57) is arranged. 7. diaphragm accumulator according to claim 6, characterized in that the circular plate (57) is formed of plastic. 8. diaphragm accumulator according to claim 6 or 7, characterized in that the other, with the sensor holder (59) connected to the end of the hose (46) having an annular flange (58) is connected, on which the circular plate (57) with the level sensor (42) is attached. 9. diaphragm accumulator according to one of the preceding claims, characterized in that the level sensor (42) is an ultrasonic sensor, and that the length of the tube (46) is greater than the blocking distance of the ultrasonic sensor. For this 2 sheets of drawings 4/6