奥地利专利AT517819A1 Flushable device for measuring flow processes of fluids

专利PDF首页>>奥地利专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
The invention relates to a device for measuring flow processes of fluids with an inlet (20), an outlet (22), a positive displacement meter (14) driven by a drive unit (24), the displacement chamber (36) of which via an inlet channel (30) Inlet (20) and via a drainage channel (40) to the outlet (22) fluidically connected + list, a bypass line (42), over which the Veordrängerlähler (14) is bypassed, a Druckdifferenzaufnehmer (18), which is arranged in the bypass line (42) and an evaluation and control unit (26) via which the drivable positive displacement counter (14) in dependence on the Druckdifferenzaufnehmer (18) applied pressure difference is controllable. Problematic are often measurement errors due to dissolving air bubbles in the system. In order to avoid this, it is proposed that the inlet channel (30) and the outlet channel (40) are formed rising in the flow direction of the fluid.
公开号:AT517819A1
申请号:T601/2015
申请日:2015-09-15
公开日:2017-04-15
发明作者:Dipl Ing Derschmidt Otfried
申请人:Avl List Gmbh；
IPC主号:

专利说明:

Flushable device for measuring flow processes of
fluids
The invention relates to a device for measuring flow processes of fluids with an inlet, an outlet, a driven by a drive unit Verdrängerzähler whose displacement chamber via an inlet channel with the inlet and a
Flow channel fluidly connected to the outlet-Ist, ----- one
Bypass line over which the positive displacement is bypassed, a Druckdifferenzaufnehmer, which is arranged in the bypass line and an evaluation and control unit, via which the drivable positive displacement is adjustable in response to the applied pressure difference on the pressure difference.
Such devices have been known for many years and are used, for example, for injection quantity measurement in internal combustion engines.
The original version of such a device for flow measurement was described in DE-AS 1 798 080. This electronically controlled flowmeter has a main line with an inlet and an outlet, in which a rotary displacement meter is arranged in the form of a gear pump. Parallel to the main line runs a bypass line through which the rotary displacement meter is bypassed and in which a serving as Druckdifferenzaufnehmerender piston is arranged in a measuring chamber. To determine the flow rate, the deflection of the piston in the measuring chamber is measured by means of an optical sensor. The speed of the gear pump is continuously readjusted due to this signal via an evaluation and control unit in such a way that the piston is always returned to its original position, so that only small currents arise in the bypass line. From the measured via an encoder number of revolutions or partial revolutions of the gear pump and the known delivery volume of the gear pump in one revolution so the flow is calculated within a predetermined time interval.
Such a constructed flow meter is also disclosed in DE 103 31 228 B3. To determine the exact
Injection volume curves, the gear pump is set to a constant speed ......... before starting each injection, so that subsequently the movement of the piston is measured and this deflection is used to determine the injection curves. In addition, a pressure sensor and a temperature sensor are arranged in the measuring chamber, the measured values of which are likewise fed to the arithmetic unit for calculating and correcting the injection quantity profiles.
To increase the accuracy of measurement, it is necessary in particular during commissioning of the device to free this from air bubbles, which lead to significant measurement errors in the measurement process due to the compressibility of the air.
Accordingly, in WO 2014/118045 Al a flowmeter is proposed, in which the measuring chamber of the pressure differential sensor limiting housing a bypass channel is formed, via which a connection of the piston front side to the piston back is made when the piston against an axial stop at the outlet end of the measuring chamber is applied. In this way, air inclusions can reach the outlet side surface of the piston, so that when conveyed through the positive displacement meter, the air is transported in the direction of the outlet. In this bypass channel a non-return valve is additionally arranged, which prevents flow from the drain side to the inlet side, ie in the reverse direction to simply move the piston back into its center position at startup after flushing can.
However, it has been shown that existing air pockets can not be completely removed from the flow meter by this measure, but accumulate in different dead spaces of the device and sometime there solve, which leads to measurement errors below. In particular, in measuring devices that operate at high pressures and whose positive displacement is driven by an electric motor with intermediate magnetic coupling, problems arise due to air pockets in the. Magnetic coupling. -
It is therefore an object to provide a device for measuring flow processes of fluids available, with which the measurement results are improved by air inclusions are removed as completely as possible during commissioning of the device. For this purpose, no additional components should be used or connected as possible. A corresponding flushing should be done without the connection of additional flushing lines from the outside. In addition, an emergency drainage of liquid should be possible if, for example, block the gears of the gear counter.
This object is achieved by a device for measuring flow processes of a fluid having the features of claim 1.
Characterized in that the inlet channel and the drain channel are formed rising in the flow direction of the fluid, air present in the channels or in the positive displacement is reliably dissipated. Dead spaces in which air collects are avoided. Instead, the air from the inlet channel automatically rises into the delivery chamber, is conveyed with the measurement fluid to the outlet opening and rises again by its lower density along the discharge channel in the direction of the outlet. Accordingly, air bubbles which worsen the measurement results are reliably removed during startup.
To further improve the measurement results, a bypass channel is formed on the pressure difference sensor, which extends from the interior of a measuring chamber of the pressure difference sensor into a flushing line, which opens into a rotor chamber of the drive unit. By virtue of this measure, air present on the piston front side can be removed via the bypass channel and the flushing line in the direction of the rotor chamber of the drive unit.
In addition to this, an inflow opening is preferably formed on the rotor chamber in the geodesic lower region, into which the flushing line opens and in the geodetically upper region an outflow opening is formed which is fluidically connected to the outlet. Thus, during the flushing process, all of the air that is in the measuring chamber or in the rotor chamber is completely conveyed to the outlet and correspondingly completely removed from the device.
In a further embodiment, a piston is axially displaceably arranged in the interior of the measuring chamber, via which a bypass opening from the measuring chamber to the bypass channel can be closed or released, wherein the bypass opening released by the piston and thus a fluidic connection between an inlet opening into the measuring chamber and the Bypass channel is made when the piston abströmseitig rests on a piston movement axially limiting stop. Thus, at standstill of the positive displacement liquid for flushing is introduced into the system, whereby the piston shifts so far that the bypass opening is released and in the measuring chamber existing air is discharged in the direction of the rotor chamber.
In a further advantageous embodiment, the measuring chamber is bounded by a hollow cylinder, at its opposite axial ends of the radially delimiting lateral surface, the inlet opening and a
Drain port are formed, which open at the opposite ends of the pressure difference in the bypass line, wherein on the lateral surface, the bypass opening is formed and in the bypass passage a check valve is arranged. Accordingly, the bypass opening is released by the movement of the piston. The check valve prevents a flow of the fluid and the air in the reverse direction, so that the air over the bypass channel can only ever flow in the direction of the rotor chamber. The task of the mostly flap-trained check valve is to facilitate the release of the piston from its end position after the flushing process.
In this case, advantageously, the purge line extends from the bypass channel through a piston housing, in which the pressure difference sensor is arranged and by a displacer housing, in which the positive displacement is arranged, to an inlet opening of the rotor chamber. Thus, no additional lines must be provided or mounted for ventilation.
A particularly simple production of the line sections in
Displacer housing is provided by the displacement chamber is formed in a bushing in a receiving opening of the
Displacer housing is arranged, wherein the Spülleitungsabschnitt, which extends through the displacer housing, is formed by a bore in the socket.
Preferably, the purge line branches downstream of the check valve from the bypass channel, whereby a back flow of air is prevented from the purge line.
In addition, the purge line extends from the drain opening through the displacer housing and the piston housing to the outlet, so that these line sections do not have to be provided as separate lines, but a fluidic connection during assembly of the housing parts without additional assembly steps arises.
Advantageously, the bypass opening is formed in a first operating position of the device at a geodetically highest point of the measuring chamber, thereby ensuring that trapped air to the bypass opening and can be removed.
In a preferred embodiment, the first bypass channel is fluidically connected exclusively via the rotor chamber with the discharge opening of the measuring chamber. Thus, a flow through the purge line is ensured regardless of the existing pressure conditions and still maintain the function of the bypass channel, so the possible removal of fluid flows, for example, when blocking the Verdrängerzählers.
A particularly simple sealing and assembly results when the rotor chamber is bounded radially by a split pot, which can then be fastened, for example via screws on the displacer housing.
In a further advantageous embodiment, the split pot separates an inner rotor from an outer stator of a split pot motor. Additional couplings are no longer needed in such an embodiment. Instead, a direct drive of the positive displacement over the split pot motor can be performed, which costs incurred by mounting and additional components are significantly reduced.
In an alternative embodiment of the invention, the containment shell separates an internal rotor from an external magnetic rotor of a magnetic coupling. In this embodiment, a standard
Electric motor can be used to drive, which has no contact with the fluid and thus is easily replaceable.
Preferably, a second bypass opening facing the inlet and outlet is formed on the measuring chamber, which opens into a second bypass channel, which opens into the measuring chamber on the outlet side. This bypass channel ensures venting of the measuring chamber in a second installation position in which the inlet and the outlet are directed upwards. ---------- ------------- -
For this purpose, a bypass outlet channel is formed at the outlet side of the measuring chamber, which extends from the measuring chamber into the outlet channel, so that the air conveyed during purging or the liquid present when the displacement counter is blocked can be led off to the outlet.
Preferably, the second bypass opening is smaller than the first bypass opening. In this way it is ensured that in addition there is a flow through the rotor chamber, so that it can be vented reliably even in the second installation position.
In addition advantageously branches off from the first bypass channel from an emergency line, which opens either directly or via an outlet of the bypass line in the drainage channel. This serves for the additional removal of liquid in the event of sudden high pressure increases, for example by jamming the gears of the positive displacement meter and prevents damage to the device.
Preferably, a pressure limiting valve is arranged in the emergency line, so that this emergency line opens only when a defined too high pressure in the device is present.
This emergency line preferably branches off downstream of the purge line from the first bypass channel, so that the emergency line is not acted upon at lower pressures with liquid from the device.
Thus, there is provided an apparatus for measuring fluid flow events which ensures rapid and complete venting during commissioning in two mounting positions. In this case, all flowed through parts of the device are vented, including the rotor chamber. In addition, damage to the device at ---- sudden pressure peaks reliably avoided. Accordingly, with this device measurement results can be achieved that are very accurate over the entire service life, so that over a long period of time, temporally resolved flow processes can be measured with high accuracy. In this case, the device is easy to manufacture and assemble, so that despite the additional features incurred no significant additional costs.
A device according to the invention for measuring flow processes of fluids is described below with reference to a non-restrictive embodiment shown in the figures.
FIG. 1 shows a perspective external view of the device according to the invention.
Figure 2 shows a perspective view of the piston housing of the device according to the invention of Figure 1 in a sectional view and with dashed lines formed in the interior channels.
FIG. 3 shows a sectional view of the piston housing according to FIG. 2 in the region of the outlet.
Figure 4 shows a partially sectioned view through the measuring chamber of the pressure difference sensor and with a view of the displacer housing.
FIG. 5 shows a perspective external view of the measuring chamber.
FIG. 6 shows a perspective view of the displacer housing with not yet mounted bush and gears.
FIG. 7 shows a containment shell of a drive unit connectable to the displacer housing.
FIG. 8 shows a sectional representation of the drive unit fastened to the displacer housing.
FIG. 1 shows an external view of a device according to the invention for measuring time-resolved flow processes. The device according to the invention has a housing 10, which is made in two parts, wherein in the first housing part serving as Verdrängergehäuse 12 a positive displacement 14 is arranged and in the piston housing 16 serving as a second housing part Druckdifferenzaufnehmer 18 is arranged. In addition, an inlet 20 and an outlet 22 are formed on the piston housing 16. A drive unit 24 of the displacement counter 14 and the evaluation and control unit 26 are arranged within a hood 28, which, like the piston housing 16, is fastened to the displacement housing 12.
In the figure 2, the piston housing 16 is shown. Via the inlet 20, the fuel flows into an inlet channel 30, which extends through the piston housing 16 up to its end wall bounding wall 32. In the wall 32 several more channels are milled. The inlet channel 30 first opens into a first inlet opening 34 of the displacement counter 14, which is of kidney-shaped design and leads into a displacement chamber 36 of the displacement counter 14 to be recognized in FIGS. 4 and 6. Furthermore, a likewise kidney-shaped outlet opening 38 is formed on the wall 32 from the displacement chamber 36, which leads into a drainage channel 40 which extends through the piston housing 16 and opens into the outlet 22. In addition, extending from the end of the inlet channel 30, a first, serving as an inlet 41 section of a bypass line 42, which leads into a measuring chamber 44 of the pressure differential sensor 18. A second section of the bypass line 42, which serves as a drain 45, extends from the opposite side of a piston 46, which is displaceably arranged in the measuring chamber 44, from the measuring chamber 44 and opens into the outlet channel 40. --- Same specific gravity as the measuring fluid and is like the measuring chamber 44 cylindrically shaped; the measuring chamber 44 thus has an inner diameter which substantially corresponds to the outer diameter of the piston 46. In FIG. 3, the piston 46 is shown smaller for better distinction from the measuring chamber 44.
In addition, an axial groove 48 is formed on the end wall 32, which surrounds the channels formed in the piston housing 16 and which serves to receive a seal, not shown, against the
Displacer housing 12 rests after assembly, so that a tight connection of the two housing parts 12, 16 is produced.
In Figures 4 and 6, the displacer 12 is shown in a view of a contact surface 50, with which the displacer 12 abuts against the displacement chamber 36 frontally bounding wall 32 of the piston housing 16. In the displacer housing 12, a receiving opening 52 is formed, in which a drive shaft 54 of the
Drive unit 24 of the displacement counter 14 protrudes. In this receiving opening 52, a bush 56 is used, which is the
Displacement chamber 36 radially bounded and correspondingly serving as a drivable Verdrängerrad 58 inner gear and a radially outer, internally toothed outer gear 60 of the Verdrängerzählers 14 receives. The essentially pot-shaped bushing 56 has correspondingly on its rear side the displacement chamber 36 defining rear wall 62 an opening 64 through which the drive shaft 54 projects into the displacement chamber 36.
On a radially delimiting outer wall 66 of the bushing 56, two grooves 68 are formed on the outer circumference, and bores connected to these grooves 68 are formed on the rear wall 62, via which the inlet channel 30 and the outlet channel 40 with a second kidney-shaped inlet opening 70 and second kidney-shaped outlet opening 72, respectively Displacement counter 14 are connected so that it is supplied from both - end faces with the measuring fluid.
During operation of the device for measuring flow processes, the fuel serving as the measuring fluid now passes via a high-pressure pump and one or more injectors to the inlet 20 and continues to flow via the inlet channel 30 to the two inlet openings 34, 70 in the displacement chamber 36, which thus both frontally also filled on the back. After being conveyed through the rotation of the driven displacement wheel 58, the fuel leaves the displacement chamber 36 again via the two outlet openings 38, 72 and flows via the outlet channel 40 back to the outlet 22.
By conveying the fuel by means of the displacement counter 14 and by injecting the fuel into the inlet 20 and by fluidically connecting the inlet 20 to the front of the piston 46 and the outlet 22 to the rear of the piston 46 via the bypass line 42, a pressure difference between the Front and the back of the piston 46 arise, which leads to a displacement of the piston 46 from its rest position. Accordingly, the deflection of the piston 46 is a measure of the applied pressure difference. At the measuring chamber 44, therefore, a displacement sensor is arranged, which is in operative connection with the piston 46 and in which by the deflection of the piston 46, a dependent on the size of the deflection voltage is generated. This displacement sensor attached to the measuring chamber 44 is, in particular, a magnetoresistive sensor, by means of which the field strength of a magnet acting on it is converted into a voltage. As displacement sensors and light sensors can be used.
The displacement sensor is connected to the evaluation and control unit 26, which receives the values of this displacement sensor and transmits corresponding control signals to the drive unit 24, which is possibly controlled in such a way that the piston 46 is always in a defined starting position. The rotary displacement meter 14 is thus driven in such a way that it constantly compensates for the pressure difference due to the injected fluid on the piston 46 by conveying approximately. In the measuring chamber 44, a pressure sensor and a temperature sensor are further arranged, which continuously measure the pressures and temperatures occurring in this area and in turn the evaluation and control unit 26 to account for changes in density in the calculation can.
The sequence of the measurements is such that in the calculation of a total flow to be determined in the evaluation and control unit 26, both a resulting from the movement or position of the piston 46 and thus displaced volume in the measuring chamber 44 flow in the bypass line 42 and a actual flow of the displacement counter 14 are taken into account in a fixed time interval and both flows are added together to determine the total flow.
The flow rate at the piston 46 is determined, for example, by differentiating the deflection of the piston 46 in the evaluation and control unit 26, which is connected to the displacement sensor, and then multiplying it by the base area of the piston 46, so that a volumetric flow rate in the bypass line 42 results in this time interval.
The flow through the positive displacement counter 14 can either be determined from the determined control data or calculated via the rotational speed, if it is measured directly at the positive displacement counter 14 or at the drive unit 24, for example via optical encoders or magnetoresistive sensors.
According to the invention, the inlet channel 30 and the outlet channel 40, as can be seen in particular in FIGS. 2 and 3, are formed obliquely, so that there is a gradient for two mounting positions in the direction of flow of the measuring fluid. The first possible installation position or operating position corresponds in each case to the one shown in the figures.
Position, while in the second operating position, the inlet and the outlet pointing upwards. As a result of this inclined design, air bubbles in the fuel are always conveyed from the inlet to the displacement chamber 36 and from the displacement chamber 36 towards the outlet 22 and can not settle in dead spaces and accumulate, since the air rises in the fuel due to its lower density, even without active support. This is particularly advantageous when the device is put into operation, in which a flushing of the device has to be carried out in order to reliably remove the air which otherwise falsifies the measured values from all units and lines of the device.
For this purpose, a special embodiment of the measuring chamber 44 is additionally selected, as can be seen in particular in Figure 5. The hollow cylinder 74 forming the measuring chamber 44 has bores and millings, or in its radially delimiting lateral surface 76, which serve as channels, the millings being closed by the surrounding piston housing 16 in order to form the channels. At the opposite axial ends of the hollow cylinder 74 openings are formed, one of which serves as an inlet opening 78 and the axially opposite as drain opening 80, wherein the inlet opening 78 is connected to the inlet 41 of the bypass line 42 and the drain opening 80 with the outlet 45 of the bypass line 42nd connected is. On the upper side, a first bypass opening 82 is formed on the radially delimiting lateral surface 76 of the measuring chamber 44, which has an axial distance to the axially limiting stop 84 of the piston at the outlet end of the hollow cylinder 74, which corresponds approximately to the axial length of the piston 46 so that this bypass opening 82 is released when the piston 46 abuts against the stop 84, as shown in Figure 4. The bypass opening 82 leads into an axially extending bypass channel 86 and can be closed by a check valve 88 arranged at the bypass opening 82, which ensures that the measuring fluid flows exclusively into the bypass channel 86 from the measuring chamber 44. ..... can, but not ..... in-converted ............... -...
Direction. From the bypass channel 86, a purge line 90 branches off, which initially extends from the measuring chamber 44 through the piston housing 16, as can be seen in FIG. The purge line 90 continues in the displacer housing 12 in the form of an axial through-bore 92 in the bushing 56, as shown in FIG. The through hole 92 opens into a groove 94 on the rear wall 62 of the displacer 12th
In this rear wall 62, the opening 64 is formed, on which the drive unit 24 is attached. In FIG. 6 it can be seen that a recess 100, which extends the groove 94 in the axial direction, is formed on the wall 98 which delimits the opening 64 radially. On the radially delimiting wall 98, a collar 102 of a split pot 104 of the drive unit 24 shown in FIG. 7 is located radially inwardly, on which an inflow opening 106 in the form of a bore is formed in the lower area, which is formed in a rotor chamber 108 formed in the interior of the can 104 leads, this inflow opening 106 is formed immediately adjacent to the recess 100, so that the purge line 90 leads into the lower region of the rotor chamber 108.
In the rotor chamber 108, a permanent magnet bearing rotor 110 of a designed as gap pot motor 111 electric motor is arranged, which is fixed to the drive shaft 54 and arranged in a known manner with a radially outside of the gap pot 104 and surrounding the rotor 110 stator 112 and corresponding to the energization of Stators 112 is driven. The containment shell 104 separates the
Rotor chamber 108 sealingly outward in the direction of the stator 112 from. Correspondingly, the two bearings 114 for supporting the drive shaft 54 within the collar 102 of the can 104 or on the axially opposite side in a bearing receptacle 116 of the can 104 are arranged. Via a flange plate 118, which extends radially adjacent to the protruding into the opening 64 collar 102, the gap pot 104 and with it designed as a gap pot motor 111 electric motor on the displacer housing 12 is attached. - ------------------------------------- -
On the upper side of the collar 102 of the can 104, a radially outwardly leading out of the rotor chamber 108 outflow opening 120 is formed, which in turn opens into a further recess 122 on the opening 64 radially bounding wall 98 of the displacer 12. A partially extending around the opening 64 groove 124 extends this recess 122 to an axial bore 126 in the socket 56, which opens into the groove 68 of the sleeve 56, which is fluidically connected to the drain passage 40. Accordingly, there is a fluidic connection of the purge line 90 with the outlet 22 of the device via the rotor chamber 108. A direct connection of this bypass channel 86 to the discharge opening 80 does not exist. Accordingly, a forced flow of the rotor chamber 108 arises in the case of the opened first bypass opening 82.
Accordingly, the measuring fluid is conveyed via the inlet at non-actuated positive displacement counter 14 in the inlet channel 30 during commissioning. This results in a pressure difference across the piston 46, so that it is displaced so far that the bypass opening 82 is released and a purge flow via the purge line 90 and the rotor chamber 108 reaches the outlet 22. Since the components in which air bubbles could collect have the respective inlet openings 78, 106 in the lower region and the corresponding outlet openings 80, 120 in the upper region, it is ensured that the air present in the system is completely removed from these chambers 44, 108 , After subsequent activation of the displacement counter 14, the air which may still be present in the displacement chamber 36 is additionally reliably removed via the oblique discharge passage 40, so that the system is completely freed of air. For the second operating position of the device, in which the inlet 20 and the outlet 22 point upwards, a second bypass channel 128 facing the inlet 20 or outlet 22 is connected to the measuring chamber 44 via a second bypass opening 130 at the radially delimiting lateral surface 76 of the measuring chamber 44. Also, this bypass opening 130 is released when the piston 46 abuts the stop 84 at the outlet end. The bypass channel 128 extends from the bypass opening 130 axially to the outlet-side axial end of the measuring chamber 44 and has a groove 129 at this end, so that there is a fluidic connection to the drain opening 80. Furthermore, this drain-side end is provided with a further groove 131 which leads to a formed in the piston housing 16, serving as bypass drain passage 132 bore through which the drain-side end of the measuring chamber 44 is directly connected to the drain passage 40 of the device. When designing it is important to ensure that the second bypass channel 128 is designed significantly smaller than the purge line 90, so that it is ensured in both mounting positions that a flushing of the rotor chamber 108 takes place. Accordingly, in the second installation position, the air is forced out of the measuring chamber 44, especially via the second bypass channel 128, in the direction of the outlet 22, both via the bypass outlet channel 132 and via the outlet 45 of the bypass line 42. In the event that the pressure in the Purge line 90 rises too far, which may occur in particular when blocking the Verdrängerzählers, branches off from the first bypass channel 86 in the flow direction downstream of the purge line 90, an emergency line 134 from. In this emergency line 134, a pressure limiting valve 136 is arranged, which opens when a pressure of, for example, about 0.4 bar is exceeded. When this pressure is exceeded, the measuring fluid can be discharged via the through the piston housing 16 to the outlet 45 of the bypass line 42 guided emergency line 134 to the outlet 22, so that damage to the device is prevented.
The described device according to the invention for measuring flow processes can thus be reliably and completely freed from air in two different installation positions or operating positions, which would falsify the measurement results due to the compressibility of the air as soon as an air bubble is released during operation from the rotor chamber of the measuring chamber or the displacement chamber would. An accumulation of air in the channels is reliably avoided by their position relative to each other. Correspondingly, improved measured values are achieved. In addition, damage to the device is avoided when pressure peaks occur, as they can occur especially in blocking or other failure of the positive displacement. These benefits are achieved without having to install additional lines for flushing. Accordingly, the structure and the assembly of the device according to the invention remain inexpensive.
It should be understood that the invention is not limited to the embodiment described, but various modifications are possible within the scope of the main claim. Thus, the arrangement of the channels and the housing divisions can be changed as well as the design of Verdrängerzählers, which can be performed for example as a double gear pump or vane pump. Also, instead of the sleeve, the positive displacement meter can be arranged directly in the recess or the socket can be designed without its own rear wall and, accordingly, the channels in the displacement housing itself can be formed. Instead of the described split pot motor, it is also possible to use a magnetic coupling in the rotor chamber, in which the inner rotor is arranged in the split pot and the outer rotor, which is driven by an electric motor is arranged radially outside of the stator. Other design changes within the scope of the main claim are also conceivable.

权利要求:
Claims (20)
[1]
Device for measuring flow processes of fluids with an inlet (20), an outlet (22), a positive displacement meter (14) which can be driven via a drive unit (24), whose displacement chamber (36) has an inlet channel (30) with _______________________________dem .. ........ inlet (20) ......... and via a discharge channel (40) ...... is fluidically connected to the outlet (22), a bypass line (42), via which the positive displacement meter (14) can be bypassed, a pressure difference sensor (18) which is arranged in the bypass line (42), and an evaluation and control unit (26), via which the drivable positive displacement counter (14) in dependence on the pressure difference sensor ( 18) applied pressure difference is controllable, characterized in that the inlet channel (30) and the outlet channel (40) are formed rising in the flow direction of the fluid.
[2]
2. A device for measuring flow processes of fluids according to claim 1, characterized in that at the Druckdifferenzaufnehmer (18) a bypass channel (86) is formed, which extends from the interior of a measuring chamber (44) of the pressure differential sensor (18) in a purge line (90). extends, which opens in a rotor chamber (108) of the drive unit (24).
[3]
3. A device for measuring flow processes of fluids according to claim 2, characterized in that on the rotor chamber (108) in the geodesic lower region, an inflow opening (106) is formed, in which the purge line (90) opens and in the geodesic upper region, a drain opening (120) is formed, which is fluidly connected to the outlet (22).
[4]
4. A device for measuring flow processes of fluids according to one of claims 2 or 3, characterized in that -------- in the interior of the measuring chamber (44), a piston (46) is arranged axially displaceably, via which a bypass opening (82) from the measuring chamber (44) to the bypass channel (86) is closable or releasable, the bypass opening (82) released by the piston (46) and thus a fluidic connection between an inlet opening (78) in the measuring chamber (44) and the bypass channel (86) is produced when the piston (46) abuts the downstream of a piston-movement axially limiting, drain-side stop (84).
[5]
5. A device for measuring flow processes of fluids according to claim 4, characterized in that the measuring chamber (44) by a hollow cylinder (74) is limited, at its opposite axial ends of the radially delimiting lateral surface (76), the inlet opening (78) and a Drain port (80) are formed, which open at the opposite ends of the Druckdifferenzaufnehmers (18) in the bypass line (42), wherein on the lateral surface (76), the bypass opening (82) is formed and in the bypass channel (86) has a check valve (88 ) is arranged.
[6]
6. A device for measuring flow processes of fluids according to one of claims 2 to 5, characterized in that the flushing line (90) from the Bypasskanai (86) by a piston housing (16), in which the Druckdifferenzaufnehmer (18) is arranged and through a displacer housing (12), in which the positive displacement meter (14) is arranged, extends to the inlet opening (106) of the rotor chamber (108).
[7]
7. A device for measuring flow processes of fluids according to claim 6, ------- characterized in that --------------- ----------- The displacer chamber (36) is formed in a bush (56) which is arranged in a receiving opening (52) of the displacer housing (12) wherein a portion of the purge line (90) extending through the displacer housing (12) is formed by a bore (92) in the bushing (56).
[8]
8. Device for measuring flow processes of fluids according to one of the preceding claims 4 to 7, characterized in that the purge line (90) branches off downstream of the check valve (88) from the bypass channel (86).
[9]
9. A device for measuring flow processes of fluids according to one of claims 3 to 8, characterized in that the flushing line (90) from the outlet opening (120) of the rotor chamber (108) through the displacement housing (12) and the piston housing (16). extends to the outlet (22).
[10]
10. A device for measuring flow processes of fluids according to one of claims 4 to 9, characterized in that the bypass opening (82) is formed in a first operating position of the device at a geodetically highest point of the measuring chamber (44).
[11]
11. A device for measuring flow processes of fluids according to one of claims 5 to 10, characterized in that the first bypass channel (86) fluidly connected exclusively via the rotor chamber (108) with the drain opening (80) of the measuring chamber (44).
[12]
12. A device for measuring flow processes of fluids according to one of claims 2 to 10, characterized in that the rotor chamber (108) is bounded radially by a split pot (104).
[13]
13. A fluid flow metering apparatus according to claim 12, characterized in that the containment shell (104) separates an inner rotor (110) from an outer stator (112) of a split pot motor (111).
[14]
14. A fluid flow metering apparatus according to claim 12, characterized in that the containment shell (104) separates an inner rotor from an outer magnetic rotor of a magnetic coupling.
[15]
15. A device for measuring flow processes of fluids according to one of claims 5 to 14, characterized in that on the measuring chamber (44) to the inlet (20) and outlet (22) facing second bypass opening (130) is formed in a second bypass channel (128) opens, the drain side in the measuring chamber (44) opens.
[16]
16. Device for measuring flow processes of fluids according to claim 15, characterized in that ...................... downstream of the ....... measuring chamber (44) a bypass drain passage (432) is formed extending from the metering chamber (44) through the piston housing (16) into the drain passage (40).
[17]
The fluid flow metering apparatus according to any one of claims 15 or 16, characterized in that the second bypass port (130) is smaller than the first bypass port (82).
[18]
18. A device for measuring flow processes of fluids according to one of claims 2 to 16, characterized in that from the first bypass channel (86) an emergency line (134) branches off, either directly or via a drain (45) of the bypass line (42) in the drainage channel (40) opens.
[19]
19. A device for measuring flow processes of fluids according to claim 18, characterized in that in the emergency line (134), a pressure relief valve (136) is arranged.
[20]
20. Device for measuring flow processes of fluids according to one of claims 18 or 19, characterized in that the emergency line (134) branches off downstream of the purge line (90) from the first bypass channel (86).

类似技术:

公开号 | 公开日 | 专利标题

EP3350446B1|2019-10-30|Flushable device for measuring flow processes of fluids

EP2690266B1|2016-02-10|Turbine for a combustion engine

EP0517014A1|1992-12-09|Lubrication gear pump for internal combustion engines, especially for vehicles

EP2304246B1|2014-07-23|Apparatus for impeller sealing in centrifugal pumps

DE1528951B2|1974-11-21|

DE102014000846A1|2015-07-30|Screw Pump

EP3073228B1|2020-04-29|System for measuring time-resolved flow processes of fluids

DE102016124115A1|2018-06-14|rotary damper

DE102016124117A1|2018-06-14|Door component with a controllable rotary damper

WO2017046199A1|2017-03-23|Device comprising a canned motor for measuring flow processes of measuring fluids

EP3350444B1|2019-10-30|Bidirectionally flow-impinged device for measuring flow processes of fluids

EP2326843B1|2021-01-13|Device for branching off a fluidic partial flow

WO2016001109A1|2016-01-07|Melt filter arrangement comprising a reverse-flow screw conveyor device

AT517817B1|2017-08-15|Device with split pot motor for measuring flow processes of measuring fluids

EP3350445A1|2018-07-25|Device comprising a canned motor for measuring flow processes of measuring fluids

DE10135448A1|2002-03-21|Liquid degredation detection device, has liquid fed through flow channel configured for gradual blockage by soil components

DE102018205852A1|2019-10-24|fluid pump

WO2016134968A1|2016-09-01|Method for operating a device for the dosed supply of a liquid

AT517820B1|2017-08-15|Coolable device for measuring flow processes of fluids

DE102007043128B4|2015-06-03|Axial multi-jet impeller volume meter

EP3238901B1|2019-10-30|Function block for a polyurethane installation and use thereof

DE102018212497A1|2020-01-30|Fluid delivery device

EP2112336B1|2012-08-08|Combined oil supply for VCT and camshaft bearings using a hollow camshaft

AT517711B1|2017-04-15|Differential pressure sensor for a flowmeter and flowmeter

DE102015112664B4|2019-09-19|Annular gear pump

同族专利:

公开号 | 公开日

US10584704B2|2020-03-10|

US20190145408A1|2019-05-16|

EP3350446A1|2018-07-25|

JP2018527513A|2018-09-20|

AT517819B1|2017-08-15|

CN108138770A|2018-06-08|

KR101988812B1|2019-06-12|

CN108138770B|2019-08-23|

EP3350446B1|2019-10-30|

JP6567172B2|2019-08-28|

KR20180043256A|2018-04-27|

WO2017046206A1|2017-03-23|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE2728250A1|1977-06-23|1979-01-04|Pierburg Luftfahrtgeraete|FLOW METER AND DOSING DEVICE|

GB2185785A|1986-01-25|1987-07-29|Ford Motor Co|Gear pump type liquid flow meter|

EP1437578A1|2002-12-18|2004-07-14|AVL List GmbH|Method for continuous measurement of dynamic fluid consumption|

DE112014003050A5|2013-06-26|2016-04-07|Avl List Gmbh|Flowmeter|

NL66381C|

US2845031A|1953-01-13|1958-07-29|Francis W Guibert|Gear tooth construction for rotary fluid meters|

US2835229A|1955-07-19|1958-05-20|Liquid Controls Corp|Rotary positive displacement device for liquids|

US3255630A|1963-11-04|1966-06-14|Rockwell Mfg Co|Positive displacement rotary gas meter|

US3273502A|1964-02-24|1966-09-20|Stewart Warner Corp|Pumping and metering device|

DE1798080C2|1968-08-19|1974-05-16|Pierburg Luftfahrtgeraete Union Gmbh, 4040 Neuss|Electronically controlled flow meter and metering device|

US4105377A|1974-10-15|1978-08-08|William Mayall|Hydraulic roller motor|

US4953403A|1989-03-15|1990-09-04|Binks Manufacturing Company|Positive displacement flushable flow meter|

US5435698A|1993-07-29|1995-07-25|Techco Corporation|Bootstrap power steering systems|

JP3520855B2|2001-02-22|2004-04-19|株式会社タツノ・メカトロニクス|Liquefied gas measuring device|

US6629411B2|2001-05-09|2003-10-07|Valeo Electrical Systems, Inc.|Dual displacement motor control|

CN2692638Y|2003-06-17|2005-04-13|赵生益|Liquid flow counter|

DE10331228B3|2003-07-10|2005-01-27|Pierburg Instruments Gmbh|Device for measuring time-resolved volumetric flow processes|

EP1568973A1|2004-02-26|2005-08-31|Signal Lux MDS S.r.l.|Thermal fluid flowmeter|

KR100466317B1|2004-04-12|2005-01-13|장도영|Liquid measuring equipment|

US7513150B2|2005-06-16|2009-04-07|Parris Earl H|Check valve module for flow meters with fluid hammer relief|

US7295934B2|2006-02-15|2007-11-13|Dresser, Inc.|Flow meter performance monitoring system|

JP4246237B2|2007-02-05|2009-04-02|株式会社オーバル|Pump unit type servo type volumetric flow meter|

JP4183096B2|2007-02-05|2008-11-19|株式会社オーバル|Path structure related to flow of fluid to be measured and differential pressure detection in servo volumetric flowmeter|

US20090035121A1|2007-07-31|2009-02-05|Dresser, Inc.|Fluid Flow Modulation and Measurement|

JP4599454B1|2009-09-07|2010-12-15|株式会社オーバル|Volumetric gas-liquid two-phase flow meter and multi-phase flow measurement system|

US9618376B2|2010-07-30|2017-04-11|Ecolab Usa Inc.|Apparatus, method and system for calibrating a liquid dispensing system|

EP2598684B1|2010-07-30|2020-12-16|Ecolab USA Inc.|Apparatus for calibrating a liquid dispensing system|

AT512027B1|2013-01-30|2014-04-15|Avl List Gmbh|Flowmeter|

AT517819B1|2015-09-15|2017-08-15|Avl List Gmbh|Flushable device for measuring flow processes of fluids|AT517819B1|2015-09-15|2017-08-15|Avl List Gmbh|Flushable device for measuring flow processes of fluids|

AT517818B1|2015-09-15|2017-08-15|Avl List Gmbh|Two-way flowable device for measuring flow processes of fluids|

CN109165700A|2018-10-18|2019-01-08|广州智颜科技有限公司|A kind of extrusion control method of beautifying liquid, apparatus and system|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

ATA601/2015A|AT517819B1|2015-09-15|2015-09-15|Flushable device for measuring flow processes of fluids|ATA601/2015A| AT517819B1|2015-09-15|2015-09-15|Flushable device for measuring flow processes of fluids|

CN201680052671.XA| CN108138770B|2015-09-15|2016-09-15|For measuring the flushable device of the through-flow process of fluid|

JP2018513589A| JP6567172B2|2015-09-15|2016-09-15|A flushable device for measuring fluid flow-through processes.|

US15/759,521| US10584704B2|2015-09-15|2016-09-15|Flushable device for measuring flow processes of fluids|

KR1020187003612A| KR101988812B1|2015-09-15|2016-09-15|Flushable device for measuring fluid flow processes|

PCT/EP2016/071766| WO2017046206A1|2015-09-15|2016-09-15|Flushable device for measuring flow processes of fluids|

EP16765992.9A| EP3350446B1|2015-09-15|2016-09-15|Flushable device for measuring flow processes of fluids|

[返回顶部]