Abstract
A pressure measuring system is provided in which a closing element supported in the pressure fitting channel is activated or displaced by a pressure surge or a pressure wave and thereby seals the channel to the measuring element and thus prevents an outflow of the fluid.
Claims
1. A pressure measuring system comprising: a pressure fitting; a measuring element connected to the pressure fitting pressure-tight, the pressure fitting having a pressure channel on an inner side, which is connected pressure-tight to the measuring element an evaluation or signal transmitter; and a movable closing element arranged in the pressure channel that seals the pressure channel when the pressure or volume rises.
2. The pressure measuring system according to claim 1, wherein the closing element is at least one molded body or a sphere, a cylindrical molded body, a hollow cylinder, a sleeve, a sleeve which is closed on one side, or a piston, or wherein the closing element a two-part arrangement including a hollow, piston-shaped body and a closing element disposed in the body or including a movable molded body as a closing element and a holder.
3. The pressure measuring system according to claim 1, wherein the closing element is a deformable molded body made from rubber, silicone, or an elastic injection-molded part.
4. The pressure measuring system according to claim 1, wherein the closing element is a sleeve that is closed on one side and/or a cylindrical molded body, and wherein the closing element has at least one circumferential seal on its outer circumference.
5. The pressure measuring system according to claim 1, wherein the closing element is adapted to be brought from a setpoint position into a sealing position in the pressure channel due to a pressure surge or a pressure wave in the pressure channel.
6. The pressure measuring system according to claim 1, wherein the closing element is brought from a setpoint position into a sealing position within the guide part due to a pressure surge or a bulk wave and then closes the pressure channel to the measuring element pressure-tight.
7. The pressure measuring system according to claim 1, wherein the closing element traverses a volume section of the pressure fitting due to a pressure surge or a bulk wave and compresses a defined volume into the inner volume of the measuring element and/or the pressure channel and closes the pressure channel pressure-tight.
8. The pressure measuring system according to claim 7, wherein a defined volume is compressed into the inner volume of the measuring element and/or the pressure channel, and wherein a defined pressure sets in due to the define volume displacement, which is indicated as an overpressure, including a warning indication, on the evaluation display.
9. The pressure measuring system according to claim 1, wherein a warning message is continuously displayed as an evaluation of the pressure increase on a display or a dial due to a pressure surge or bulk wave.
10. The pressure measuring system according to claim 9, wherein the warning indication is continuously displayed on the evaluation display in that the pointer is caught and/or held in a warning position via ramps or stops.
11. The pressure measuring system according to claim 1, wherein the movable closing element seals the pressure channel in the case of a pressure rise, including a sudden or intermittent pressure increase.
12. The pressure measuring system according to claim 1, wherein a sudden or intermittent pressure increase comprises a pressure gradient of 5 to 150 bar/minute, or a pressure gradient of a multiple of 10 bar/second, or a pressure increase to greater than or equal to 350 bar or from 350 to 450 bar, and results in the rupture of the measuring system and the escape of a fluid, and wherein the movable closing element seals the pressure channel due to the resulting increase in the volume of the escaping fluid in the pressure channel.
13. The pressure measuring system according to claim 1, wherein the pressure measuring system measures pressure in pressure systems or on compressed gas cylinders filled with a welding gas, an acetylene-containing gas or gas mixture.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0025] The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus, are not limitive of the present invention, and wherein:
[0026] FIG. 1 shows a manometer;
[0027] FIG. 2 shows a shows gearless manometer;
[0028] FIG. 3 shows a schematic view of a manometer;
[0029] FIG. 4 shows an arrangement of a compressed gas cylinder including a pressure measuring system;
[0030] FIG. 5a shows a pressure fitting;
[0031] FIG. 5b shows a closing element;
[0032] FIG. 5c shows a throttle;
[0033] FIG. 6 shows a spherical closing element in a guide part;
[0034] FIG. 7 shows a pressure fitting including measuring tube and measuring channel;
[0035] FIGS. 8a and 8b show a closing element in the form of a modified guide part;
[0036] FIG. 9 shows a closing element, comprising a spherical molded body;
[0037] FIG. 10 shows a closing element in the form of a guide part;
[0038] FIG. 11 shows a two-part throttle arrangement of a closing element;
[0039] FIG. 12 shows a pressure fitting having a closing element in the form of a stopper;
[0040] FIG. 13 shows a closing element in the form of a piston;
[0041] FIG. 14 shows a modified measuring instrument;
[0042] FIG. 15a shows a measuring instrument;
[0043] FIG. 15b shows the measuring instrument from FIG. 15A in a sectional view; and
[0044] FIG. 16 shows a pressure characteristic curve.
DETAILED DESCRIPTION
[0045] FIG. 1 shows a manometer 1 as the pressure measuring system, including a measuring element 8 which comprises a warning area 2 upon reaching impermissible overpressure or a pressure range representing an endangerment.
[0046] An evaluation of the pressure at pressure fitting 3 may be implemented within pressure measuring system 2 gearlessly, with the aid of a transmission mechanism or electronically and as a pointer 4 on a dial 5 or digital display 42 (FIG. 13).
[0047] FIG. 2 shows gearless manometer 1, in which the change in pressure or evaluation of the change in pressure is implemented by the pointer 4, which is connected directly to a part or end of spiral Bordon tube 6 (measuring tube). Measuring tube 6 is connected pressure-tight to pressure fitting 3.
[0048] FIG. 3 shows a schematic view of a manometer 1, in which a displacement of Bourdon tube 6 drives pointer 4 via a movement 7.
[0049] FIG. 4 shows an arrangement 13 of a compressed gas cylinder 10 including pressure measuring system 1. Compressed gas cylinder 10 includes a main valve 11 and a bleed unit 12 having a manometer 1. The arrangement is illustrated in simplified form in FIG. 4, without a pressure reducer or pressure controller.
[0050] FIG. 5A shows a pressure fitting 3, including a measuring tube 6 and a measuring channel 27, having a spherical closing element 20 in a guide part 22 fixed in a channel bore 21, synonymous with the pressure fitting channel, the guide part, for example, being pressed into pressure fitting channel 21 of pressure fitting 3 of a manometer 1 illustrated at the outset or having a different design. Spherical throttle 20 (synonymous with closing element)preferably made from a deformable material such as rubberis held in an exposed holding zone 23.
[0051] FIG. 5B also shows a closing element, which comprises a throttle in the form of a sleeve-like guide part 22A having a defined through-channel 24A and an originally preferably spherical closing element (20A) in the form of a deformable molded body 20A, which is movably supported in a holding zone 23 in the through-channel, the throttle and the closing element being integrated into the pressure fitting connecting piece 3 of a manometer 1 or a pressure sensor in pressure fitting channel 21. Sleeve-like guide part 22A may be fixedly pressed in. If a pressure surge occurs, including a sudden pressure increase, closing element 20A may be lifted up and seal through-channel 24A in guide part 22A in that the element is deformed. Guide part 22A has an upper through-channel 24A.1 as well as a lower through-channel 24A.2 below deformable molded body 20A inside guide part 22A.
[0052] FIG. 5C shows a throttle (closing element), which comprises a guide part 22B having holding areas 23B and a spherical closing element 20B, similar to FIG. 5A, which may be integrated into pressure fitting channel 21 of pressure channel connecting piece 3 of a manometer 1 or a pressure sensor, and which has a lower through-slot/channel 24B.2 for a fluid in the lower area on the outside of sleeve-like guide part 22B. Guide part 22B also has an upper through channel 24B.1.
[0053] FIG. 6 shows spherical closing element 20B in a guide part 22B, including holding zone 23B and lower through-channel 24B.2 from FIG. 5 in a spatial representation.
[0054] FIG. 7 illustrates a pressure fitting 3 including measuring tube 6 and measuring channel 27, in whose pressure channel 21, synonymous with the pressure fitting channel, a spherical closing element 20C is disposed in a guide part 22C having a seal 25, in particular a sealing ring. Sphere 20C may seal through-channel 24C.1 in a clamping manner by being lifted out of setpoint position X into sealing position Y. In the case of a greater pressure wave, however, guide part 22C may also execute a lift H and displace a volume defined with the aid of H upward into measuring element 8 (not illustrated), in particular into warning position Z, and it may thus fix pointer 4 from FIG. 1 in an overpressure range. The overpressure range may then be displayed as the warning position. Pressure fitting 3 has a free space or through channel 26 on the inside in the pressure fitting channel; holder 23C, synonymous with holding zone, and through channel 24C.1 establish the fluid communication with measuring channel 27. A sealing ring 25 supports guide sleeve 22C in pressure channel 21, forming a seal.
[0055] FIGS. 8A and 8B also show a closing element 20D in the form of a modified guide part, pressure fitting channel 21 having a through channel 26 or a free space 26 on the side for the purpose of facilitating a fluid communication to measuring tube 6 under normal measuring pressure. In the event of a pressure surge or a pressure wave, guide part 20D may be lifted, in particular by lift H, out of setpoint position X into sealing position Y, and may thus seal measuring channel 27.
[0056] FIG. 9 shows a closing element, comprising a spherical molded body 20E, similar to FIG. 7, in a guide part 22E from setpoint position X, the guide part being able to execute a lift H for the purpose of closing upper through-channel 24E.1 and thus also pressure channel 27, synonymous with measuring channel, to the measuring element (sealing position Y), the guide part, including sealing ring 25, also being able to execute a lift H and subsequently displace a defined volume of hollow upper area 28 of guide element 22E from the lift, upward into measuring element 8, which is not illustrated, and thus fix the pointer from FIG. 1, 14 or 15 in an overpressure range. In this position, guide part 22E is in warning position Z.
[0057] A groove or through-channel in the inner circumference of pressure channel 21 of pressure fitting 3 establishes a fluid communication to the sensor or measuring element in the normal state. Guide part 22E is held, in particular, in an idle position by its compressed sealing ring 25, and the guide part in the form of a piston 22E is displaced only by a pressure/volume surge in the direction of the sensor for the purpose of completely sealing pressure channel 21E/27E, a defined and calculated slip-stick effect of sealing rings 25 being helpful to avoid false activation, e.g., in the event of shocks.
[0058] FIG. 10 shows a closing element 20D, similar to FIG. 8, in the form of a guide part, which is brought by a first lift H1 from setpoint position X into sealing position Y, and closes pressure channel 21. A second lift H2 may guide the guide part from sealing position Y into warning position Z, in that a defined volume element is displaced into the measuring element. In addition, a defined volume is displaced upward by second lift H2 into measuring element 8 (not illustrated), thus fixing pointer from FIG. 1, 14 or 15 in an overpressure range.
[0059] FIG. 11 shows a two-part throttle arrangement of a closing element, comprising a disk-shaped molded body (20F) including a sealing ring 30 as well as a holder 34. The disk-shaped molded body is illustrated as plate 20F, which has a throttle channel 31, and seals pressure channel 27 upwardly via an integrated sealing plate 32, preferably made from a rubber material, upon activation and displacement.
[0060] FIG. 12 shows a pressure fitting 3 having a closing element 20G in the form of a stopper, which is preferably manufactured from a rubber material and which directly seals input 35 of measuring tube 6 in the case of a pressure surge.
[0061] FIG. 13 shows a closing element 20H in the form of a piston, including a seal 25, which closes pressure channel 21H against measuring channel 27 to form a seal, similarly to FIG. 10, in the case of a pressure surge and thus protects a pressure sensor 40 against irreversible damage and/or prevents leaks. An impermissible overpressure may be indicated by means of electronic evaluation 41 by the flashing of display 42, the output of WARNING or another alarm that can be visual and/or audible.
[0062] FIG. 14 shows a modified measuring instrument, including a pressure fitting 3 from FIG. 2, in which a dial 5, preferably injection-molded from plastic, has a molded-on ramp 50 and stop 51, which is able to gearlessly catch pointer 4 on a measuring tube 6 in an overpressure position and is able to fix it to prevent further forward or backward rotation. A warning state is thus also detectable, when the pressure has already dropped again, while a possible endangerment still remains.
[0063] FIG. 15A shows a modified measuring instrument from FIG. 14, in which measuring spring 6 has a helical shape, and in which a dial 5, preferably injection-molded from plastic, also has a molded-on ramp 50 and a stop 51, which is able to gearlessly catch pointer 4 on a measuring tube 6 in an overpressure position and is able to fix it to prevent further forward or backward rotation. A mountable viewing window 52 having blow-out openings 53 is again illustrated, which are closed by a cover 54.
[0064] FIGS. 1, 14 and 15 show designs which represent a dial which differs from EN 837, since the usual range over 270 is not used as a pressure range indicator and evaluation for the dial. Instead, according to the invention, a smaller partial area is configured only for the pressure display, and a larger partial area is provided with warning symbols or a red or orange or cross-hatched warning area, which signals a critical overpressure state. Thus, the normal display range, for example to 180 or another range, is used in a departure from the standard.
[0065] It is simultaneously conceivable that a ramp or dog 50 is also painted red, and special functions for an overpressure are furthermore integrated into the device.
[0066] A horn, siren, blinking light or flashing light on or in the housing of the measuring instrument may thus be activated via a light barrier, contact actuator or reed switch with magnetic activation, which is powered from a battery or is powered from the surroundings of the measuring instrument using a buffer store via a photovoltaic cell or another power converter. In addition to light, heat, motion or the fluid itself, e.g. in the case of hydrogen, are also conceivable as the source therefor, if a fuel cell is used.
[0067] It is also conceivable that a warning message, which contains the position via satellite and status of the cylinder, is sent to a warning center over a network, by SMS text messaging or via GPRS or according to another radio standard or protocol.
[0068] The ramp, dog 50 illustrated in this FIG. 15A, which fixes the pointer in the warning field, is, of course, conceivable in this combination with a dial face, even in another manometer design, for example in FIG. 1.
[0069] FIG. 15B shows the measuring instrument from FIG. 15A in a sectional view, including closing elements (20, 22) in pressure fitting 3 with transparent cover pane 52, disposed on top, which may be mounted on housing 55 with the aid of an engagement mechanism or press fit.
[0070] FIG. 16 shows a pressure characteristic in a compressed gas cylinder, e.g., in the case of impermissible heating or after being knocked over, a pressure drop also be able to first take place, e.g. by a cooling, after a period of 15 minutes. During the further progression, the fluid may still react, despite further cooling, and a pressure wave may occur, including an abrupt pressure increase to more than 200 bar, in particular to greater than or equal to 300 bar. At point A of FIG. 16 at the latest, the pressure increases intermittently in the compressed gas cylinder. This may result in the fact that the measuring element is impermissibly inflated, and the measuring element is at risk of rupturing.
[0071] During this phase, the pressure increase may rise at a rate of 5 to 50 bar/minute; in extreme cases, it may rise intermittently at rates of 50 to 150 bar/minute or up to 2 to 50 bar/second.
[0072] At this point at the latest, the defined response of the illustrated throttle and closing elements sets in and prevents an outflow of fluid and protects the users and staff who work in the rooms or who want to protect the cylinder against dangerous, uncontrollable situations. These persons may include firefighting units who extinguish a fire in a company using, for example, acetylene compressed gas cylinders or users who have inadvertently knocked over the cylinder. A continuous warning display enables necessary security measures to be initiated at an early point.
[0073] In principle, however multiple activation mechanisms are possible, two of which are mentioned here:
[0074] In the first case, the pressure rises abruptly from a pressure of 40 to 50 bar to a pressure of more than 300 bar. The pressure gradient in this case is a multiple of 10 bar/second or even faster and is viewed as being abrupt or intermittent. The throttle will seal the instrument port as soon as the pressure wave reaches the closing element, e.g. a rubber sphere.
[0075] In the second case, it is possible that the pressure rises slowly from the normal fluid pressure of the cylinder to the rupturing pressure of the measuring element. The pressure gradient is a multiple of 10 bar/minute (i.e., comparatively slower than the preceding case). In this case, the throttle responds only after the measuring element ruptures, since volume is first displaced, which sets the closing element in motion for triggering.
[0076] The abrupt pressure difference which is only then generated, for example 350 to 450 bar rupture pressure in a gearless pressure measuring instrument, as shown, for example in FIG. 14 or 15, may result in this case in a short-term escape of gas; however, the throttle will immediately start up and safely prevent further leaks, because the throttle also abruptly closes the pressure channel.
[0077] The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.
