DE102017119879A1 - Flow detector and associated installation method - Google Patents

Abstract

The present invention relates to a flow detector and an associated installation method for detecting fluid flows in a fluid channel (2), comprising a closure element (3) made of an elastic material, which is adapted to be arranged in the fluid channel (2) and a cross section of the Fluid channel (2) in a state of rest, in which no fluid flows through the fluid channel (2) to close, and a detector element (4) which is spaced from the closure element, wherein the closure element (3) is adapted to be in the idle state to be in a blocking position, and to be in a flow state, in a release position, wherein the closure element (3) at least partially a holding element (31) comprising magnetic or magnetizable material, wherein the detector element (4) arranged thereto is, based on the magnetic field of the holding element (31) a flow signal in dependence to provide the position of the closure element (3). According to the invention, restrictions with respect to the installation position and the detectable flow direction are avoided.

Description

The present invention relates to a flow detector for detecting fluid flows in a fluid channel, in particular of extinguishing agent flows in section lines, as well as an associated method for installing such a flow detector. The invention finds particular application in the field of fire protection technology, whereby the use in other areas is possible.

It is known, especially in the fire protection technology, to provide flow detectors for the detection of extinguishing agent flows in section lines. In section lines, the pressure in the idle phase and in the flow phase remains unchanged, which is why a fluid flow can not be detected by a pressure change.

For example, flow detectors are known based on electronic or optical detection means, their production and maintenance, however, is complex and expensive.

It is also known to provide solutions based on electromechanical components as flow detectors. The operation of solutions based on electromechanical components is usually based on flexible barriers that block the flow cross section in the fluid channel. In a flow then the flexible barriers are moved, this movement then generates a signal, for example by a switch operation.

However, such electromechanical solutions have the disadvantage that the barriers are indeed flexible, but require a costly separation of the pipe network for disassembly in case of maintenance. In other words, it is not possible to simply remove the barrier from a fluid line without having to separate the portion of the fluid line with barrier from the rest of the fluid line. Furthermore, such solutions are only suitable for detecting flows in one direction. Finally, the flexible barriers are only stored at one point, which leads to a restriction of the possible construction position, since the center of gravity of the barrier must be aligned linearly to the bearing point.

Against this background, it was an object of the present invention to improve a flow detector such that the disadvantages known from the prior art are at least partially eliminated. In particular, an object was to improve a flow detector to the effect that there is no restriction regarding the installation position and the detectable flow direction.

According to the invention, the object is achieved by a flow detector for detecting fluid flows in a fluid channel. The flow detector comprises a closure member made of an elastic material adapted to be disposed in the fluid channel and to close a cross-section of the fluid channel in an idle state in which no fluid flows through the fluid channel, and a detector element spaced from the closure member is arranged. The closure element is adapted to be in a rest position in a blocking position, and to be in a flow state in which a fluid flows through the fluid channel, to be in a release position, wherein a flow resistance of the closure element in the flow direction of the fluid channel in the blocking position higher than in the release position. The closure element has, at least in sections, a holding element which comprises magnetic or magnetizable material. The detector element is configured to provide a flow signal as a function of the position of the closure element based on the magnetic field of the holding element.

In that the closure element is elastic and thus differs, for example, from the flexible barrier of the prior art, there is no restriction on the deformation from the blocking position to the release position with respect to the flow direction. Thus, the flow detector according to the invention makes it possible to detect a fluid flow in both directions. Furthermore, after the detector element is driven based on the magnetic field of the holding element, which is in turn connected to the closure element or designed as part of the closure element, no electrical connection between closure element and detector element is necessary. This allows a simplified mounting of the flow detector on or in the fluid channel, since no mechanical or electrical connection between the interior and the exterior of the fluid channel is necessary.

The fluid channel is preferably a section of a fire protection system, which are adapted to the extinguishing agent flows through them.

In one embodiment, the closure element comprises a membrane. The membrane is preferably impermeable, but in other embodiments may also have a certain permeability to the fluid, whereby a certain fluid flow through the membrane is possible. The closure element or the membrane preferably has rubber or silicone.

Rubber or silicone are preferred materials of the closure element, as these advantageously allow the required elasticity. In other embodiments, however, of course, completely or partially other materials, such as plastic materials, metallic materials, etc. possible.

That the closure element closes the cross-section of the fluid channel in the idle state means in one embodiment that the fluid channel is completely closed by the closure element except for necessary manufacturing tolerances. In other embodiments, the sealed fluid channel means that a significant portion of the cross-section is blocked by the closure element. Preferably, the closure element closes in the idle state at least 90%, preferably 95% and in particular more than 99% of the cross section of the fluid channel.

In one embodiment, the closure element is configured to deform into the blocking position without external force. Due to the fact that the pressure within the fluid channel is constant when no fluid flows, no external force acts on the closure element in this state. Nevertheless, this preferred embodiment makes it possible for the closure element to deform itself into the blocking position in which the closure element closes the fluid channel. For example, the closure element is elastically deformed, the blocking position corresponding to the original shape of the closure element. Alternatively or additionally, shape memory materials, such as metallic shape memory materials or shape memory polymers may also be used.

In one embodiment, the closure element in the blocking position is flat and deformed in the release position, preferably curved, formed.

In the release position, the projection of the closure element into the plane in which the closure element is in the blocking position is thus smaller. The closure element can thus have a larger area in the flow channel in the blocking position, which has a greater flow resistance than in the release position result.

In one embodiment, the detector element can be arranged on an outer side of the fluid channel.

An arrangement of the detector element on an outer side of the fluid channel is, without making changes to the fluid channel, possible with the simplest means. In particular, there must be no opening of the fluid channel or the like. By virtue of the fact that the detector element detects the magnetic changes of the holding element, the signal can be transmitted from the interior to the detector element arranged on the outside.

In one embodiment, the flow detector further comprises a magnetic or magnetizable strip configured to extend at least partially circumferentially about the fluid channel. The magnetic or magnetizable strip is in contact with the detector element. The magnetic or magnetizable strip is therefore advantageously suitable for detecting the change in the magnetic field of the holding element and transmitting it to the detector element. This can be done a precise detection of fluid flow within the fluid channel.

In one embodiment, a width and / or a length of the magnetic or magnetizable strip is adapted to a switching region of the detector element. In particular, in a case in which the detector element is designed as a fluid switch, by adjusting the width and / or length of the magnetic or magnetizable strip, a measurement accuracy or triggering threshold of the flow detector can be adjusted. In this case, the hysteresis is also preferably used in assessing the switching range.

In one embodiment, the holding element is designed as part of the closure element, wherein the part of the closure element that forms the holding element comprises a magnetizable material, in particular magnetic powder.

The holding element can therefore be integrated as a magnetizable material, in particular in the form of magnetic powder, in the closure element or designed as part thereof. The retaining element can be integrated into the surface of the closure element in a part or entire surface of the closure element.

In one embodiment, the retaining element is arranged at least in sections radially outward, with respect to the cross section of the fluid channel to be closed.

The arrangement of the holding element two advantageous effects of the flow detector can be achieved. First, the radially outer arrangement of the holding element ensures that the holding element itself would like to expand as far as possible, which promotes the flattening of the closure element in the rest position. Next, a holding force between the holding element and the fluid channel is made possible by the arrangement of the holding element close to the fluid channel. The fact that the holding force acts independently of the mounting position against gravity, no restrictions are placed on the orientation of the fluid flow sensor. In particular, the retaining element ensures regardless of the installation position that the closure element is held in the rest position. Preferably, the holding element is designed to enclose the closure element radially. However, complete encircling is not absolutely necessary, so that the magnetic field generated by the holding element is sufficiently strong to both generate a sufficient holding force and to provide a sufficient magnetic field that is detected by the detector element.

In one embodiment, the holding element is axially magnetized, that is to say that the magnetic north pole and the south pole of the holding element are arranged axially with respect to the flow direction of the fluid channel. Preferably, in the case that the closure element is curved in such a way that outer ends of the closure element almost touch each other, a repulsion is achieved by the same poles of the holding element. As a result, the return of the closure element is simplified in the rest position. The axial magnetization allows a particularly good magnetic force transmission both to the fluid channel and to the outside to the detector element. Alternatively, for example, radial magnetizations, that is with magnetizations formed radially outward from the fluid channel, are possible.

In one embodiment, the holding element is configured to provide a holding force that is asymmetrical with respect to the closure element. Thus, since the closure element on the side on which the holding element provides a smaller holding force, already at lower flow rates trigger and thus allow detection by the detector element of lower flow rates. Thus, a request for the detection of a predefined minimum flow rate can be ensured.

Preferably, a lower holding force is provided by the holding element on one side of the detector element than on the opposite side. As a result of the proximity to the detector element, the deflection of the holding element with a lesser holding force, which produces a lower magnetic force, can thus be reliably detected.

In one embodiment, the closure element for both directions of fluid flows in the fluid channel in a respective release position deformable.

In other words, in this embodiment, the shutter member has no limitation on deformation in a certain direction. In particular, the detector element is configured to provide a flow signal indicative of the direction of fluid flow. The flow signal of the detector element is thus suitable not only to indicate the flow but at the same time the direction of the flow. For example, the direction of the flow can be registered by different signs of the magnetic field change at the detector element. In other embodiments, a plurality of detector elements are conceivable, wherein the plurality of detector elements are adapted to detect one direction of the fluid flow.

In one embodiment, the detector element has a magnetic switch element, in particular a reed switch. Reed switches are a well-known example of magnetic switch elements, although other magnetically based switch or detector elements are conceivable. Other advantageous examples of detector elements are magnetic coils or Hall sensors, although other detector elements known to those skilled in the art can be used in the same way.

In one embodiment, the flow detector comprises a positioning device for positioning the closure element in the fluid channel.

By means of the positioning device, the closure element is positioned in the fluid channel, that is held at a certain position. For this purpose, the positioning device is preferably innelastic and does not change its position even in the presence of flow in the fluid channel. Preferably, the closure element is insertable and removable by means of the positioning device in the fluid channel, which allows easy installation.

In one embodiment, the positioning device comprises a fastening element, wherein the fastening element defines a first axis in the cross section of the fluid channel, wherein the closure element deforms in the release position about the first axis, preferably bulges.

The fastening element is designed in one embodiment as a linear rod. On the fastening element formed as a rod, the closure element can be fastened by means of screws or the like.

Preferably, the fastening element is designed as two parallel linear fastening elements, which form a kind of pliers in between and are designed to receive the closure element. In this preferred embodiment, the closure element is thus clamped between two linear bars of the fastening element, which are arranged one behind the other in the flow direction. This allows a better support or attachment to the positioning device.

In one embodiment, the fastener is attached centrally to the closure member. In other words, the fastening element divides the closure element symmetrically into two halves. In other embodiments, of course, another arrangement of the fastener to the closure element is possible. The central attachment allows a particularly simple positioning, namely in the middle of the fluid channel.

The object is further achieved by a flow detector arrangement according to the invention. The flow detector arrangement comprises a fluid channel segment, in particular a segment of a section line, and a flow detector according to the invention. The fluid channel segment has at least one closable connecting piece, wherein the closing element can be arranged by means of the positioning device via the closable connecting piece in the fluid channel segment.

No particular requirements are made on the fluid channel segment, that is to say that any desired fluid channel or section thereof can be used for the flow detector arrangement according to the invention. In particular, existing parts of a section line can be expanded to provide a flow detector arrangement according to the invention by providing a closable connecting piece, for example in the form of a sleeve. By means of the positioning device, the closure element is arranged in the fluid channel and the advantages which have been described with reference to the flow detector can be achieved by the flow detector arrangement according to the invention.

In other words, the fluid channel segment can thus be a section or segment of an already existing fluid channel or a separate component which can be inserted into a gap between, for example, two section lines. Thus, the flow detector arrangement according to the invention can be offered for example as a retrofit kit to retrofit existing fluid lines with the flow detector according to the invention. The retrofitting can then either be performed on the existing section line or performed by introducing the separate fluid channel segment between two parts of the section line.

In one embodiment, the fluid channel segment is formed as a housing of the closure element of the flow detector. This means that the closure element is received within the fluid channel segment, which is a housing.

In one embodiment, the closure element in the blocking position has a diameter that is greater than an opening defined by the connecting piece.

The closure element can thus close the entire cross section of the fluid channel, without an opening to be defined by the connector, which corresponds to the diameter of the fluid channel segment. Such an opening is not easy to predict even on a fluid channel segment. The closure element must be rolled up for insertion or removal, particularly advantageous here is the fastener out, around which the closure element can be rolled. After this Inserting the closure element will automatically and without external force return to the rolled-out rest position and close the fluid channel.

In one embodiment, the flow detector assembly further includes the magnetic or magnetizable strip that extends at least partially circumferentially about the fluid channel segment. The magnetic or magnetizable strip is in contact with the detector element. The magnetic or magnetizable strip is therefore advantageously suitable for detecting the change in the magnetic field of the holding element and transmitting it to the detector element. This can be done a precise detection of fluid flow within the fluid channel segment.

In an embodiment, the fluid channel segment comprises a magnetizable and / or magnetic material, wherein the retaining element is arranged to hold the closure element in the blocking position when no fluid flows in the fluid channel segment. A magnetic holding force between the holding element and fluid channel thus enables a position-independent installation of the flow detector or the entire flow detector arrangement.

In one embodiment, the fluid channel segment and the closure element have a circular cross-section. The holding element in sections preferably has a ring shape. Preferably, the holding element is arranged radially on the outside of the circular closure element. In other embodiments, other cross-sectional shapes for fluid channel segment and closure element are possible, wherein the holding element is adapted according to the shape of the closure element.

In one embodiment, the detector element is attached to the fluid channel segment at a position that has a maximum distance from the fastening element in the cross-sectional direction of the fluid channel.

Due to the maximum distance between the fastening element and the detector element, the deformation of the closure element in the release position at the location of the detector element is maximum. The axis of the fastener is the axis about which the closure member deforms or bulges. The further the closure element from this axis, the greater the deflection of the deformation. Thus, such an arrangement of the detector element allows optimal detection of the deformation and thus of the flow.

In one embodiment, the fluid channel segment on two opposite, designed as guides for the positioning device, closable connecting pieces, wherein the connecting pieces are designed in particular as oppositely aligned guide sleeves.

The oppositely aligned guide sleeves allow the positioning device to be located in the direction of escape in the fluid channel. In particular, the positioning device is adapted to position the fastener in the connection of the two attachment pieces. Thus, the connectors can define the axis of the fastener and thus the axis about which the fastener deforms. Alternatively, however, the fluid channel segment may also have only one or more than two connecting pieces.

In one embodiment, the positioning device comprises a guide element, wherein the guide element is adapted to guide the closure element within the at least one connecting piece, wherein the guide element comprises a first opening and a second opening, which are arranged on opposite sides of the closure element.

The connector is thus adapted to receive the guide element. The guide element itself is set up to guide the closure element. In other words, the guide element thus enables the secure positioning and guidance of the closure element in the fluid channel or the fluid channel segment. Preferably, the positioning device comprises a first and a second guide element, wherein the first and second guide element is arranged in each case for guiding within one of the oppositely arranged connecting pieces. Compared to only one guide element, this embodiment has the advantage that the closure element is guided on both sides of the fluid channel. However, embodiments with only a guide element and a connector are possible.

In one embodiment, the flow detector assembly is further configured to receive a recirculation pump between the first opening and the second opening.

For regular checking of the flow detector arrangement, the function of the flow detector must be checked by applying a flow. In order not to require flow through the entire pipeline network, flow detector assemblies typically include a recirculation pump connected in front of and behind the flow detector to allow local flow. Previous systems require the presence of this circulation pump, which means a high investment requirement and beyond a more complex maintenance, since the circulating pump itself must be maintained. According to the invention, the flow detector arrangement is now adapted to receive a dockable or separable circulating pump between the first opening and the second opening. For maintenance of multiple flow detector arrangements, a service technician therefore only has to carry a single circulating pump, which can easily be docked to the connections prepared for this purpose. While the first and the second opening are formed in this embodiment as part of the guide element received in the connector, in other embodiments also prepared for connection of a circulation pump ports may be provided on both sides of the closure element directly to the flow channel. The circulation pump may be a stationary or a mobile circulation pump.

The object is further achieved by a method for installing a flow detector, in particular a flow detector according to the invention or a flow detector arrangement, in particular a flow detector arrangement according to the invention, in a fluid channel. The method comprises winding a closure element of elastic material along a first axis defined by a fastener of a positioning device and inserting the positioning device into the fluid channel via a connector, the closure element leveling within the fluid channel in a blocking position, that of the closure element closed cross-section of the fluid channel in the blocking position is greater than in the rolled up state.

The inventive method for installing a flow detector thus allows easy installation of the flow detector only in that the closure element in rolled-up form, wherein the rolling takes place about the axis of the fastening element, is inserted into the connecting piece. The detection of the flow can then take place via a detector element, which is for example attached to the outside of the fluid channel. The advantages which are achieved by the flow detector arrangement according to the invention or the flow detector according to the invention and described above, can be made as it were by adaptations of the method according to the invention. Preferred embodiments of the flow detector arrangement or of the flow detector can be transferred analogously to the method according to the invention.

• 1 einen Querschnitt durch eine erfindungsgemäße Strömungsmelderanordnung senkrecht zu einer Strömungsrichtung schematisch und exemplarisch,
• 2 einen Querschnitt einer erfindungsgemäßen Strömungsmelderanordnung parallel zu der Strömungsrichtung schematisch und exemplarisch,
• 3 eine schematische perspektivische Ansicht eines erfindungsgemäßen Strömungsmelders, und
• 4 eine perspektivische exemplarische Ansicht einer erfindungsgemäßen Strömungsmelderanordnung.

Advantages of the invention will be described below with reference to an embodiment shown in attached figures. Hereby shows:

• 1 a cross section through a flow detector arrangement according to the invention perpendicular to a flow direction schematically and by way of example,
• 2 a cross section of a flow detector arrangement according to the invention parallel to the flow direction schematically and by way of example,
• 3 a schematic perspective view of a flow detector according to the invention, and
• 4 a perspective exemplary view of a flow detector assembly according to the invention.

1 and 2 show two cross sections of a flow detector according to the invention 1 which is in a fluid channel 2 is mounted. 1 shows schematically and exemplarily the cross section of the flow detector 1 perpendicular to a flow direction 28 of the fluid channel 2 , in which 2 the cross-section of the flow detector 1 parallel to the flow direction 28 of the fluid channel 2 shows.

The particular in 2 visible portion of the fluid channel 2 goes from a fluid inlet 21 to a fluid outlet 22 which are part of, for example, a fire extinguisher network of a fire protection system. fluid inlet 21 and fluid outlet 22 are not openings of the fluid channel, but designate inlet and outlet of the flow detector 1 relevant area of the fluid channel 2 ,

Core of the flow detector 1 is a closure element 3 , which is shown in both figures in a rest position, in which the closure element 3 a cross section of the fluid channel 2 closes. This is the situation where no fluid flows. The closure element 3 has in this example at its outer periphery a holding element 31 on, in particular than in the closure element 3 implemented integrated magnetic powder is and a magnetic force between the closure element and the fluid channel 2 , Which reasonably steel or other magnetizable material, causes.

The closure element 3 has an elastic material, such as silicone or rubber, which is arbitrarily deformable and yet assumes its original shape, when no external force on the closure element 3 acts. The closure element 3 may include in its structure the embedding by sintering or other thermal processes of foreign bodies.

The holding element 31 , which is designed for example as a magnetic ring, can be radial or, preferably, axially magnetized or magnetizable.

The flow detector 1 further comprises a detector element 4 in this example, outside the fluid channel 2 is arranged and a magnetic field of the holding element 31 within the fluid channel 2 detected. By changing the magnetic field, the detector element 4 a flow within the fluid channel 2 detect.

In the area of the flow detector 1 has the fluid channel 2 a first connector 23 and a second connector 24 on, the opposite and opposite to the fluid channel 2 are arranged. In this example, the connectors are 23 . 24 as simple sleeves to the fluid channel 2 appropriate.

Between the first connector 23 and the second connector 24 provides a positioning device 5 for positioning the closure element 3 within the fluid channel 2 , For this purpose, the positioning device 5 a fastener 51 on, on which the closure element is attached. The fastener 51 For example, screws, rivets or the like for securing the closure element 3 along a linear, first axis. Preferably, the fastener 51 designed as two parallel rods, which the closure element 3 pinch in between. The fastener 51 defines the axis around which the closure element 3 deform or buckle. With a slight flow in the fluid channel 2 the fluid seeks the path of the smallest flow resistance through the closure element 3 , The smallest flow resistance is at the point where the closure element 3 is the most flexible, namely at the point of the fastener 51 farthest away. This is the point in 1 shown vertically in the middle, on which also preferably the detector element 4 , In particular, a magnetic switch with reed contact is arranged.

At this point, the flow causes the largest deflection of the closure element 3 and thus offset the magnetic effect of the holding element 31 at this point. The detector element detects the change in the magnetic field and can convert the change in the magnetic field into a message signal. This is independent of the flow direction in both a flow of fluid inlet 21 to fluid outlet 22 and vice versa possible.

At a larger flow, the closure element folds 3 in the corresponding flow direction about the axis of the fastener 51 and gives the cross section of the fluid channel 2 almost completely free. Ends the flow takes the closure element 3 again the rest position, which is shown in the figures, a. The positioning device 5 is designed to the closure element 3 within the fluid channel 2 to arrange and position. For assembly, the closure element 3 around the fastener 51 wrapped so that the closure element 3 through the first connector 23 is insertable, that is, the diameter of the closure element 3 is reduced such that the closure element the diameter of the connector 23 does not exceed. The positioning device 5 is designed to be in the first connector 23 and the second connector 24 to be led. When the positioning device 5 including closure element 3 within the fluid channel 2 is arranged, it is rotated in the right direction, that the closure element 3 within the fluid channel 2 can unfold, that is, the rest position occupies, in which there is the fluid channel 2 closes. The positioning device 5 is in this example then on the formed as sockets connectors 23 . 24 with union nuts 25 . 26 fixed.

The elastic closure element 3 tends to be within the fluid channel, preferably designed as a steel pipe 2 to take the flat undeformed rest position and winds from the fastener 51 from. The comprehensive radial magnetic flux of the designed as a magnetic ring holding element 31 exerts the largest magnetic force only at the shortest distance to the inner circumference of the fluid channel 2 because there the magnetic flux is the most dense. The holding element 31 preferably supports the flattening of the closure element 3 , so that the fluid channel 2 always closes radially. At the same time, the retaining element transmits 31 a radial magnetic flux around the fluid channel 2 around. Due to the adhesive effect holds the holding element 31 the closure element 3 regardless of the mounting position level and stable within the fluid channel 2 , Thus, the holding element eliminates 31 the gravitational effect on the closure element 3 , As already mentioned, the detector element 4 at the maximum effective position of the magnetic flux around the fluid channel 2 positioned, preferably at the point of maximum distance of the closure element 3 from the fastener 51 ,

For disassembly, the exemplary union nuts are simply removed and the positioning device pulled out, for example, by rotary motion. As a result, the closure element is wound 3 around the fastener 51 the positioning device 5 and thereby fits through the opening of the first and second connecting pieces without being damaged 23 . 24 ,

For functional test has a first guide element 52 the positioning device 5 that in the first connector 23 is guided, a first opening 521 and a second opening 522 on, on opposite sides of the closure element 3 with respect to the flow direction of the fluid channel 2 are provided. This first or second opening 521 . 522 are designed to with a first connection element 61 and a second connection element 62 a circulation pump 6 to be connected. The state of the flow detector 1 can by connecting and operating the circulation pump 6 be monitored, as the circulation pump 6 for a flow around the closure element 3 ensures the case of a flow through the fluid channel 2 is simulated. By the circulation pump 6 is removable, it does not have to be configured stationary as part of the flow detector, the flow detector 1 is only for connection of the circulation pump 6 prepared. Several flow detectors 1 within a network of fluid channels 2 can therefore be operated during the maintenance or function check by a single pump, which reduces the investment and maintenance of the entire system.

Instead of the first opening 521 and second opening 522 as part of the first guide element 52 in the flow detector 1 can also be used to connect a circulating pump 6 Prepared connection elements directly to two on different sides of the closure element 3 arranged sides of the fluid channel 2 to be provided. The same advantages as those at the first opening 521 and second opening 522 connectable circulation pump 6 can be achieved are possible with such connections.

Alternatively, both guide elements as a second guide element 53 be configured, that is, have no opening. Also a one-sided tour with just one of the elements 52 . 53 is possible.

3 and 4 show schematically and exemplarily perspective views of another embodiment of the flow detector according to the invention 1 or the flow detector arrangement according to the invention 10 , 3 and 4 show essentially the same arrangement, taking 4 in addition a Fliudkanalsegment 20 of the fluid channel 2 shows.

Opposite the in 1 and 2 embodiment shown, the embodiments of the 3 and 4 a magnetic or magnetizable strip 42 on, in a plane with the closure element 3 on the outside of the fluid channel 2 or the fluid channel segment 20 is arranged. In this case, the strip is 42 starting from the first connector 23 around the entire circumference of the fluid channel segment 20 back to the first connector 23 designed on the opposite side. The stripe 42 is in a recess of the fluid channel segment 20 secured and can, for example, by the union nut 25 be held in position. The magnetic or magnetizable strip 42 is in contact with the detector element 4 , the width and extent of the strip 42 controls the sensitivity of the detector element 4 ,

In this embodiment, the fluid channel segment 20 of a non-magnetizable material, in particular brass or aluminum. The transmission of the magnetic force of the retaining element 31 outwards thus takes place on the magnetic or magnetizable strip 42 , The flow detector arrangement 10 is in this example including the fluid channel segment 20 can be used in an existing fluid line. The fluid channel segment 20 forms a separate housing for the flow detector, which can thus be mounted as a complete component. In other words, the fluid channel segment 20 around a particular exchangeable segment of the fluid channel 2 ,

The fluid channel segment 20 has a single connector 23 on. In other versions, of course, as well as in 1 respectively. 2 be provided two connectors.

The positioning device 5 has an alignment support at its top 54 formed as an exemplary groove on. By means of registration support 54 can the orientation of the closure element 3 in a plane with the magnetic or magnetizable strip 42 be ensured. This is a safe functioning of the flow detector assembly 10 easily verifiable by moving the direction of the registration support 54 is checked. At the same time, the alignment support allows 54 , removing the flow detector 1 from the fluid channel segment 20 to support.

The closure element 3 is not completely round, but flattened at its top, as the guide element 52 a part of the cross section of the fluid channel segment 20 occupies. This is a simple guide and secure attachment of the closure element 3 ensured in the fluid channel. In 3 may be the parallel orientation of the retaining element 31 or the closure element 3 with the magnetic strip 42 be seen very well.

The holding element 3 has in this example a split into two parts retaining element 31 each spaced from the fastener 51 on opposite sides in sections along the circumference of the closure element 3 extending. The holding elements 31 are not symmetrical, that is, the same magnetic force causing, designed, but one of the two holding elements 31 causes a lower magnetic force than the opposite holding element 31 , This opens the closure element 3 on the side on which the holding element 31 generates the lower holding force, at a lower flow rate than it with evenly designed holding elements 31 the case would be. This can ensure that the requirement to detect a predefined minimum flow rate is met.

LIST OF REFERENCE NUMBERS

Water flow detectors 1 Flow detector arrangement 10 fluid channel 2 Fluid passageway segment 20 fluid inlet 21 fluid outlet 22 First connecting piece (of the fluid channel) 23 Second connecting piece (of the fluid channel) 24 Nut 25 Nut 26 flow director 28 closure element 3 retaining element 31 detector element 4 magnetic or magnetizable strip 42 positioning device 5 fastener 51 First guide element 52 Second guide element 53 alignment support 54 First opening (of the first guide element) 521 Second opening (of the first guide element) 522 circulating pump 6 First connection element (the circulating pump) 61 Second connection element (the circulating pump) 62

Claims (26)

Flow detector (1) for detecting fluid flows in a fluid channel (2), in particular of extinguishing agent flows in section lines comprising a closure member (3) made of an elastic material adapted to be disposed in the fluid channel (2) and to close a cross section of the fluid channel (2) in an idle state in which no fluid flows through the fluid channel (2) , and a detector element (4), in particular a magnetic switch element, which is arranged at a distance from the closure element, wherein the closure element (3) is arranged to be in a blocking position at rest and to be in a release position in a flow state in which a fluid flows through the fluid channel (2), wherein a flow resistance of the closure element ( 3) in the flow direction of the fluid channel (2) in the blocking position is higher than in the release position, wherein the closure element (3) has, at least in sections, a holding element (31) which comprises magnetic or magnetizable material, wherein the detector element (4) is adapted to provide, based on the magnetic field of the holding element (31), a flow signal as a function of the position of the closure element (3). Flow detector (1) after Claim 1 wherein the closure element (3) comprises a membrane and / or the elastic material comprises rubber or silicone. Flow detector (1) according to one of the preceding claims, wherein the closure element (3) is adapted to deform without external force into the blocking position. Flow detector (1) according to one of the preceding claims, wherein the closure element (3) in the blocking position is flat and deformed in the release position, preferably curved, is formed. Flow detector (1) according to one of the preceding claims, wherein the detector element (4) on an outer side of the fluid channel (2) can be arranged. A flow detector (1) according to any one of the preceding claims, further comprising a magnetic or magnetizable strip (42) in contact with the detector element (4) and adapted to extend at least partially circumferentially about the fluid channel (2) , Flow detector (1) after Claim 6 wherein a width and / or length of the magnetic or magnetizable strip (42) is adapted to a switching region of the detector element (4), in particular including a hysteresis. Flow detector (1) according to one of the preceding claims, wherein the holding element (31) is designed as part of the closure element (3), wherein the part of the closure element (3) which forms the holding element (31), a magnetizable material, in particular magnetic powder, includes. Flow detector (1) according to any one of the preceding claims, wherein the retaining element (31) at least partially radially outward, based on the cross-section of the fluid channel (2) to be closed, in particular the closure element (3) radially enclosing, is arranged. Flow detector (1) according to one of the preceding claims, wherein the holding element (31) is axially magnetized. Flow detector (1) according to one of the preceding claims, wherein the holding element (31) is adapted to provide a respect to the closure element (3) asymmetric holding force, wherein in particular on one side of the detection element (4) provided a lower holding force than on the opposite side becomes. Flow detector (1) according to one of the preceding claims, wherein the closure element (3) is deformable for both directions of fluid flows in the fluid channel (2) in a respective release position, wherein in particular the detector element (4) is adapted to a flow signal, which for the Direction of fluid flow is indicative to provide. Flow detector (1) according to one of the preceding claims, wherein the detector element (4) comprises a reed switch. Flow detector (1) according to one of the preceding claims, wherein the flow detector (1) comprises a positioning device (5) for positioning the closure element (3) in the fluid channel (2). Flow detector (1) after Claim 14 wherein the positioning device (5) comprises a fastening element (51), wherein the fastening element (51) defines a first axis in the cross section of the fluid channel, wherein the closure element (3) in the release position around the first axis, deformed, preferably bulges. Flow detector (1) after Claim 15 , wherein the fastening element (51) is fastened centrally to the closure element (3). Flow detector arrangement (10), with a fluid channel segment (20), in particular a segment of a section line, and a flow detector (1) according to one of Claims 12 to 14 wherein the fluid channel segment (20) has at least one closable connecting piece (23, 24), wherein the closing element (3) can be arranged in the fluid channel segment (20) by means of the positioning device (5) via the closable connecting piece (23, 24). Flow detector according to Claim 16 , wherein the fluid channel segment (20) is formed as a housing of the closure element (3) of the flow detector (1). Flow detector according to Claim 17 or 18 wherein the closure element (3) in the blocking position has a diameter which is greater than an opening defined by the connecting piece (23, 24). Flow detector arrangement according to one of Claims 17 to 19 wherein the fluid channel segment (20) comprises a magnetizable and / or magnetic material, wherein the retaining element (31) is arranged to hold the closure element (3) in the blocking position when no fluid flows in the fluid channel segment (20). Flow detector arrangement according to one of Claims 17 to 20 wherein the detector element (4) is secured to the fluid channel segment (20) at a position having a maximum distance from the fastener (51) in the cross-sectional direction of the fluid channel segment (20). Flow detector arrangement according to one of Claims 17 to 21 , wherein the fluid channel segment (20) has two opposite, as guides for the positioning device (5) configured closable connecting pieces (23, 24), wherein the connecting pieces (23, 24) are designed in particular as oppositely aligned guide sleeves. Flow detector arrangement according to one of Claims 17 to 22 wherein the positioning device (5) comprises a guide element (52), wherein the guide element (52) is adapted to guide the closure element (3) within the at least one connecting piece (23, 24), wherein the guide element (52) is a first Opening (521) and a second opening (522), which are arranged on opposite sides of the flow of the closure element (3). Flow detector according to Claim 23 wherein the flow detector assembly is further adapted to provide a recirculation pump (6) between the first port (521) and the second port (522). Flow detector arrangement according to one of Claims 17 to 24 in that the fluid channel segment (20) has two connecting elements which are arranged in the flow direction of the fluid channel (2) on opposite sides of the connecting piece (23, 24) and are prepared for connection of a circulating pump (6) between the two connecting elements. Method for installing a flow detector (1), in particular a flow detector according to one of Claims 1 to 16 , in a fluid channel (2), or a flow detector arrangement (10), in particular a flow detector arrangement according to one of Claims 17 to 25 comprising: rolling up a closure element (3) made of an elastic material along a first axis defined by a fastening element (51) of a positioning device (5), inserting the positioning device (5) into the fluid channel via a connecting piece (23, 24) 2), with the closure element (3) leveling within the fluid channel (2) in a blocking position, the cross-section of the fluid channel (2) closed by the closure element (3) being greater in the blocking position than in the rolled-up state.

Images