DE29821673U1 - Fluid power device, in particular flow sensor with housing made of line connecting elements - Google Patents

Description

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"Fluid technology device, in particular flow sensor with housing made of line connection elements"

Description

The invention relates to a fluid power device and in particular to a flow sensor with a housing which contains a particularly cylindrical flow chamber for the measuring medium.

Well-known examples of such flow sensors include float flow meters, impeller flow meters and the like. Flow sensors of the type mentioned at the beginning are also known in which a bluff body is arranged in the flow chamber which can be moved axially against the force of a return spring under the effect of the dynamic pressure of the flowing medium and whose respective axial position depends on the flow. The bluff body comprises a permanent magnet whose axial position in the flow chamber is monitored by a reed contact switch arranged on the housing outside the flow chamber. The switching state of the reed contact switch is evaluated in order to obtain information about the flow or throughflow. Such flow sensors can be used as flow monitors to monitor whether a predetermined flow rate value is exceeded or not reached, or to distinguish between the states "flow present" and "no flow". Known flow sensors or flow monitors of the type mentioned above sometimes have complicated housings for the flow chambers and for the flow detection means housed therein.

The object of the present invention is to provide a fluid power device and in particular a flow sensor of the type mentioned at the outset with a housing that can be realized in a simple and cost-effective manner.

To achieve this object, it is proposed according to the invention that the housing is formed from two line connection elements, preferably standardized standard assembly elements from the field of installation technology, each of which has two axially opposite connection ends, and a sleeve body which connects a connection end of one of the line connection elements to a connection end of the other line connection element.

The line connection elements selected from standard assembly elements can in particular be commercially available fittings, hose connectors, etc., which are inexpensively manufactured in large quantities for the sanitary or chemical engineering sector and offered at low cost.

The pipe connection elements considered here are usually rotationally symmetrical and have two connection ends or connection nipples that protrude outwards from a central section on opposite sides. An inexpensive component that is also available as a standard assembly element in the sanitary or chemical engineering sector, such as a sleeve, can be used as the sleeve body, the dimensions of which are selected so that the pipe connection elements with their connection ends can be connected directly to its opposite ends.

The ensemble of two line connecting elements and a sleeve body thus assembled forms a housing with a flow chamber located therein, which is filled by the cavities of the mutually

facing connection ends of the line connection elements and connected to one another by the sleeve body and/or by the hollow space of the sleeve body. The assembly consisting of the sleeve body and the line connection elements attached to both sides automatically has external connection ends, namely the free connection ends or connection nipples of the line connection elements that protrude axially outwards from the sleeve body. These connection ends are used as external connections when integrating the flow sensor into a line system.

Line connection elements in the form of hose connectors, pipe fittings and matching sleeve bodies are available in various standard sizes, so that a wide range of different housing sizes can be covered according to the inventive concept.

Preferably, line connection elements and sleeve bodies are used which have respective connection threads for mutual screwing. In this case, a sleeve body provided with an internal thread can be provided, into which connection ends of the line connection elements equipped with a respective external thread can be screwed from both axial sides.

Alternatively, the sleeve body may have an external thread so that the respective connection ends of the line connecting elements are provided with a complementary internal thread in order to establish the screw connection.

Depending on the type of cable connection elements and the sleeve body, alternative types of connection between the sleeve body and the relevant connection ends of the cable connection elements can be used instead of a screw connection, for example plug connections, clamp connections, press connections or shrink-on connections.

The line connection elements are preferably identical to one another and can be made of metal and/or plastic in a known manner.

In the flow chamber, devices for flow detection are arranged according to the respective embodiments of the flow sensor according to the invention, which respond to the flow of the measuring medium.

Such devices may, for example, be an impeller in the case of a vane flow meter, a float in the case of a variable area flow meter, etc.

In a preferred embodiment, the device for flow detection accommodated in the flow chamber has an axially displaceable bluff body which is to be displaced by the flowing medium in accordance with the static pressure against the restoring force of a spring in the axial direction of the flow chamber. The axial deflection of the bluff body depends on the respective flow rate per unit of time and can therefore be used as a measure of the flow.

Preferably, the bluff body comprises a permanent magnet, the axial position of which is detected by a magnetic field sensor outside the flow chamber. The magnetic field sensor can be, for example, a reed switch or a Hall sensor.

The sensor housing according to the invention can also be used, for example, as a housing for a magnetic inductive flow meter or the like.

In generalization of the above remarks, the invention also relates to a fluid power device, in particular a flow sensor or pump, with a housing to be integrated into a fluid line system, which

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Functional elements of the fluid power device and has an input connection and an output connection. The fluid power device is characterized in that the housing is formed from two line connection elements, each of which has two axially opposite connection ends, and a sleeve body which connects a connection end of one of the line connection elements to a connection end of the other line connection element, the line connection elements and in particular also the sleeve body being selected from standard assembly components from the installation technology sector.

From one aspect, the invention can also be considered as the use of standard assembly elements, namely line connection elements and sleeve bodies, to produce a housing for a fluid power device.

The fluid power device can be, for example, the flow sensor already mentioned. The housing is also suitable as a pump housing, for example for an oscillating piston pump. The features of claims 2 - 9 can also be provided in such a pump housing.

The invention is explained in more detail below with reference to the figures.

Fig. 1 shows a first embodiment of a flow sensor according to the invention in a schematic, not to scale, sectional side view with an internally threaded sleeve body.

Fig. 2 shows a housing for a second embodiment of a flow sensor according to the invention with external thread of the sleeve body.

The housing 1 of the flow sensor according to the invention shown in Fig. 1 consists of two identical, commercially available hose connectors 3a and 3b and of a likewise commercially available sleeve body 5 which connects the two hose connectors 3a and 3b to one another.

The hose connectors 3a and 3b each have two standardized connection ends 7a, 9a and 7b, 9b, respectively, which protrude from a central section 11a and 11b to axially opposite sides. The connection ends (connection nipples) 7a and 7b facing each other in the assembly according to Fig. 1 have an external thread 13a and 13b, respectively, at which they are screwed to the internal thread 15 of the sleeve body 5. The facing end faces 17a and 17b of the connection ends 7a and 7b act on an O-ring seal 18 from opposite sides. The housing 1, which is firmly screwed at 13a, 13b and 15 and is made up of the standard mounting elements 3a, 3b, 5 and 19, defines a flow chamber 21 for the measuring medium, which flows in at the connection end 9a and flows out of the connection end 9b when the flow sensor is used as intended. The connection ends 9a and 9b in the example are plug-in connections for attachable hose connection sleeves.

The connectors 3a and 3b used in accordance with Fig. 1 are reducing connectors with a respective annular shoulder 19a and 19b at the transition from the smaller to the larger cross-section or from the larger to the smaller cross-section. The annular shoulder 19b serves as a spring abutment for the axial support of a pressure-loaded helical spring 22, which preloads a bluff body 23, which is guided in the flow chamber 21, towards the annular shoulder 19a of the hose connector 3a. In the example, the bluff body 23 rests against the annular shoulder 19a in a manner that closes the inlet channel 25, provided that the measuring medium is stationary, i.e. no flow takes place. However, if measuring medium flows into the inlet channel 25 with sufficient pressure, the

The bluff body 23 is displaced to the right in Fig. 1 against the restoring force of the spring 22, whereby the flow path through the flow sensor is opened. The bluff body 23 comprises a permanent magnet 29 as a position indicator. A reed contact switch 27 arranged on the outside of the sleeve body 5 changes its switching state as a magnetic field sensor as soon as the bluff body 23 with its permanent magnet 29 exceeds a predetermined axial position in the flow chamber 21 to the right or falls below it again to the left. The switching state of the reed contact switch 27 is monitored by an electronic circuit (not shown) in order to provide information about the flow state of the sensor according to Fig. 1. The flow sensor according to Fig. 1 is therefore a flow monitor that can be implemented inexpensively using the simplest means.

Fig. 2 shows a housing according to the invention for a flow sensor or the like, in which the line connection elements 3a' and 3b' have an internal thread 13a', 13b' on the mutually facing connection ends 7a' and 7b' and are screwed to the external thread 15' of the sleeve body 5' at these internal threads 13a' and 13'. The line connection elements 3a' and 3b' in Fig. 2 are, for example, pipe screw fittings with connection threads 30a' and 30b' also on the axially outward-facing connection ends 9a' and 9b'. Not shown in Fig. 2 are means for flow detection arranged in the flow chamber 21', for example a float or an arrangement with the elements provided at 22, 23, 29 in Fig. 1.

In the embodiments shown, the line connection elements 3a, 3b; 3a', 3b' are designed in the same way. In certain application situations, it may be useful to use different line connection elements, e.g. a hose connector on one side and a pipe screw fitting on the other side.

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In the illustrated connecting pieces 3a, 3b there is a step (annular shoulder 19a or 19b) at the transition between the different diameters of the passage opening. Within the scope of the invention, connecting pieces can also be used in which this transition is gradual and conical.

If the flow measurement principle allows it, line connection elements can also be used whose passage opening does not show any change in diameter.

The housings 1 and T shown in Figures 1 and 2 can alternatively accommodate functional elements of a pump, i.e. be used as pump housings.

Claims (14)

1. Flow sensor with a housing ( 1 ) which contains a flow chamber ( 21 ) for the measuring medium, characterized in that the housing ( 1 ) is formed from two line connecting elements ( 3a , 3b ), each of which has two axially opposite connection ends ( 7a , 9a ; 7b , 9b ), and a sleeve body ( 5 ) which connects a connection end ( 7a ) of one of the line connecting elements ( 3a ) to a connection end ( 7b ) of the other line connecting element ( 3b ). 2. Flow sensor according to claim 1, characterized in that the sleeve body ( 5 ) is screwed to the respective connection ends ( 7a , 7b ) of the line connecting elements ( 3a , 3b ). 3. Flow sensor according to claim 2, characterized in that the connection ends ( 7 a, 7 b) screwed to the sleeve body ( 5 ) have an external thread ( 13 a, 13 b), said external threads being in screw engagement with an internal thread ( 15 ) of the sleeve body ( 5 ). 4. Flow sensor according to claim 2, characterized in that the sleeve body ( 5 ') has an external thread ( 15 ') which is in screw engagement with complementary internal threads ( 13 a', 13 b') of the line connecting elements ( 3 a', 3 b'). 5. Flow sensor according to one of claims 1-4, characterized in that the two line connecting elements ( 3 a, 3 b) are identical to one another. 6. Flow sensor according to one of the preceding claims, characterized in that the connection ends ( 7 a, 7 b) of the line connection elements connected to one another by the sleeve body ( 5 ) jointly act on an annular seal ( 18 ), in particular an O-ring seal, from opposite sides. 7. Flow sensor according to one of the preceding claims, characterized in that the line connecting elements ( 3 a, 3 b) are hose connectors. 8. Flow sensor according to one of the preceding claims, characterized in that the line connection elements are pipe screw connection elements ( 3 a', 3 b'). 9. Flow sensor according to one of the preceding claims, characterized in that the line connecting elements ( 3 a, 3 b) and the sleeve body ( 5 ) are made of metal and/or plastic. 10. Flow sensor according to one of the preceding claims, characterized in that a device ( 22 , 23 , 29 ) for flow detection, which responds to the flow of the measuring medium, is arranged in the flow chamber ( 21 ). 11. Flow sensor according to claim 10, characterized in that the device for flow detection has a dam body ( 23 ) arranged axially displaceably in the flow chamber ( 21 ), which is to be displaced by the measuring medium in accordance with the dynamic pressure against the effect of a restoring force of a spring ( 22 ) in the axial direction of the flow chamber ( 21 ). 12. Flow sensor according to claim 11, characterized in that the bluff body ( 23 ) comprises a permanent magnet ( 29 ) and that outside the flow chamber ( 21 ) a magnetic field sensor ( 27 ), in particular a reed switch or Hall sensor, which monitors the position of the permanent magnet ( 29 ) is provided on the housing ( 1 ). 13. Fluid power device, in particular flow sensor or fluid pump, with a housing ( 1 ; 1 ') to be integrated into a fluid line system, which contains functional elements ( 22 , 23 ) of the fluid power device and has an input connection ( 9a ; 9a ') and an output connection ( 9b ; 9b '), characterized in that the housing ( 1 ; 1 ') is formed from two line connection elements ( 3a , 3b ; 3a ', 3b '), each of which has two axially opposite connection ends ( 7a , 9a , 7b , 9b ; 7a ', 9a ', 7b ', 9b '), and a sleeve body ( 5 ; 5 ') which connects a connection end ( 7a ; 7a ') of one of the line connection elements ( 3a ; 3a ') to a connection end ( 7b ; 7 b') of the other line connection element ( 3 b'), wherein the line connection elements are selected from standard assembly elements from the installation technology sector. 14. Fluid power device according to claim 1, characterized in that the sleeve body is also a standard mounting element from the installation technology sector.