DE29709860U1 - Device for flow monitoring in pipelines - Google Patents

Description

H-V

PATENT ATTORNEYS *..*·.«' .· «AbDERBAUMER strasse 20

D-33602 BIELEFELD

DIPL-ING. BODO THIELKING phone: <o ₅ 21) eoe21

DIPL- ING. OTTO ELBERTZHAGEN fax: (0521) 173725

POSTAL ACCOUNT HANNOVER
(Bank code 25010030) 3091 93-302

ATTORNEY FILE: 5329

date: 03.06.1997/Sg

Applicant: Bulthaup, Horst

Fisherman's stalemate 15
32120 Hiddenhausen

Designation: Flow monitoring device

in pipelines

The invention relates to a device for monitoring the conveyance of viscous media, such as fluid greases, in pipelines, such as those of a central lubrication system.

In central lubrication systems, it is important to transport the fluid grease, such as oil or similar, from a centrally installed fluid grease reservoir to the lubrication points on various mechanical devices in a machine system using a feed pump. Unfortunately, in practice it often happens that the pipes to the individual parts of the system are damaged, which is why the relevant lubrication points are either not supplied at all or are at least under-supplied. The resulting damage is considerable, and devices of the type mentioned above have therefore been developed in order to be able to monitor the delivery of the fluid grease in each of the pipes in the central lubrication system.

In the known design, such monitoring devices work depending on the temperature. They are based on the principle

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zip that a flowing medium extracts energy from a heat source and the resulting temperature loss is recorded and evaluated to generate a signal. The disadvantage of such monitoring devices is that they are susceptible to interference from the environment, particularly changes in the ambient temperature.

The invention is therefore based on the object of creating a device of the generic type which allows a more precise detection of the conveying state in the monitored pipeline even with the smallest conveying quantities.

This object is achieved according to the invention in a device of the generic type by a housing which can be inserted or attached into the respective pipeline and through which the medium flows, with an inlet opening and an outlet, and with a closure body which is pressed against the inlet opening by the force of a spring and around which the medium can flow, and for detecting the change in position of the closure body, a sensor device which can be connected to an evaluation unit is arranged on the housing.

It is essential for the invention that the signal for the flow state is derived from the change in position of the closure body in the housing when medium flows through it via the sensor device. There are suitable sensor devices with which even slight changes in position of the closure body in the housing can be detected. The closure body reacts spontaneously to each conveying stroke of the medium through the housing, thus

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With the monitoring device according to the invention, a significantly higher clock rate is achieved and even the smallest delivery quantities can be recorded. Environmental influences, such as the ambient temperature in particular, are negligible for the device according to the invention, and in particular electrical interference fields can be largely eliminated by compensation and shielding.

The sensor devices for detecting the change in position of the closure body can work according to different principles. Inductive detection can be achieved by making the closure body magnetic or containing a magnet, whereby the sensor device then has sensor elements that detect magnetic fields. This requires that the housing of the device is made of a material that is permeable to magnetic fields. In another way, the change in position of the closure body can also be detected capacitively, whereby the housing of the device must be made of a material that is permeable to an electric field. The closure body in the housing is then given a dielectric constant that differs from the medium, and a sensor device is provided that has components that generate an electric field and sensor elements that detect changes in capacitance.

In a preferred embodiment, an optically operating sensor device is used. For this purpose, it is necessary to make the housing at least partially transparent and to use a medium that is also transparent, which is usually the case with lubricating greases.

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is the case. The sensor device on the housing comprises an optical transmitter and an optical receiver, the optical connection of which through the housing is either interrupted after the position of the closure body changes from the starting position at the inlet opening of the housing or is established after a previous interruption in the starting position. The optical sensor device can be adjusted best if, in the starting position of the closure body at the inlet opening of the housing, there is a correspondingly full light passage between the optical transmitter and the optical receiver, which is then completely or partially reduced as soon as the closure body moves from its starting position as a result of being carried along by the medium flowing through it in the housing.

Further advantageous features of the invention emerge from the subclaims.

The invention is explained in more detail below using exemplary embodiments in the drawing. In the drawing:

Fig. 1 shows a schematic longitudinal section through a

Monitoring device for the promotion of a
Fluid grease in a pipeline in first design
during idle fluid grease production,

Fig. 2 shows a longitudinal section corresponding to Fig. 1
by the monitoring device, but in
Delivery condition of the fluid grease,

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Fig. 3 a longitudinal section analogous to Fig. 1 through

a monitoring device in a second version and

Fig. 4 a longitudinal section analogous to Fig. 1 through

a monitoring device in a third design.

Fig. 1 shows in detail an essentially tubular housing 1, which can be inserted into a pipeline conveying fluid grease and has suitable connecting means at both of its ends, which are not shown in detail in the drawing. In the conveying state, the fluid grease transported in the pipeline flows through the housing 1; for this purpose, a stepped through-bore extends through the housing 1. In the main part of the housing 1, this through-bore forms a hollow cylinder 2, into which an inlet opening 3 opens on one of its end faces 4, which has a smaller diameter than the hollow cylinder 2. On the side opposite the end face 4 in the housing 1, a drilled insert 6 is inserted into the hollow cylinder 2, through which a bore forming an outlet 5 is passed.

A closure piece 7 is guided in the axial direction inside the hollow cylinder 2, which is essentially polygonal in cross section and is supported in the longitudinal edge area at the polygon corners on the inner wall of the hollow cylinder 2 in the housing 2. This creates continuous flow channels 18 around the closure piece 7 in the longitudinal direction.

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formed so that during continuous conveying or during a conveying stroke the fluid grease can pass from the inlet opening 3 through the hollow cylinder 2 to the outlet 5. For this purpose the closure piece 7 functions differently than the closure body of a valve because here a blocking of the flow of the fluid medium through the housing 1 is not an option.

The closure piece 7 is acted upon at its end facing the outlet 5 by a compression spring 8, which is supported on an inner end face 9 of the insert 6 in the hollow cylinder 2 and is coaxially aligned with the latter and with the closure piece 7. Due to the pressure, the closure piece 7 is pressed in the direction of the inlet opening 3 and rests against the end face 4 in the housing 1 when the fluid grease is not being pumped. If there is a continuous or discontinuous conveyance of the fluid grease in the relevant pipeline and accordingly through the housing 1, which usually takes place under considerable pressures of around 50 bar, then the piston-like closure piece 7 is carried along by the fluid grease flowing into the hollow cylinder 2 through the inlet opening 3 against the pressure of the compression spring 8 and moves in the axial direction away from the inlet opening 3, whereby the closure piece 7 assumes a position shown in Fig. 2. For the conveyance of the fluid grease through the housing 1, the flow resistance of the closure piece 7 is negligible, and the flow channels 18 around the closure piece 7 also provide enough space to ensure a sufficient passage cross-section for the fluid grease within the hollow cylinder 2.

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The displacement of the closure piece 7 is used to detect the delivery state of the fluid grease. A sensor device 10 is used for this purpose, which in the embodiment according to Figures 1 and 2 is essentially optical. The sensor device 10 also includes an electronic evaluation unit, which is also not shown in the drawing.

The main components of the sensor device 10 in optical design are an optical transmitter 11 with a light source 12 and an optical receiver 13 with a photo element 14, such as a photodiode or a phototransistor, which are arranged diametrically opposite one another on the outside of the housing 1. At least in the area of the optical transmitter 11 and the optical receiver 13, the housing 1 is designed to be translucent, and the fluid grease is also generally translucent to at least a limited extent so that the light from the optical transmitter 11 can reach the optical receiver 13. So that the light rays from the optical transmitter 11 form a limited light barrier that passes through the housing 1, there is a slit diaphragm 15 with a slit opening 16 on the exit side of the optical transmitter 11, which is similarly opposite a slit opening 16 of another slit diaphragm 15 on the input side of the optical receiver 13.

In the initial position of the closure piece I ₁ , which corresponds to the resting state of the fluid grease, the light barrier formed between the optical transmitter 11 and the optical receiver 13 is not interrupted, although the closure piece

7 itself consists of an opaque material. In the initial position of the closure piece 7, a slot 17 formed by a radial recess, which consequently extends in the direction of a radial plane of the closure piece 7 and thus forms a sharply defined constriction of the closure piece 7, is aligned with the slot openings 16 of the two slotted diaphragms 15 on the optical transmitter 11 and on the optical receiver 13. If, on the other hand, the closure piece 7 is displaced away from the inlet opening 3 by the fluid grease flowing through the housing 1, as shown in Fig. 2, then the slot 17 of the opaque closure piece 7 is no longer aligned with the slot openings 16 of the two slotted diaphragms 15 and the light barrier between the optical transmitter 11 and the optical receiver 13 is interrupted. Between the state of the uninterrupted and the interrupted light barrier, there are of course intermediate positions of the closure piece 7 in which its slot 17 is only partially aligned with the slot openings 16 in the slotted apertures 15, which is why, with appropriate evaluation in the electronic unit to which the photo element 14 is connected, it is also possible to record the respective delivery quantity via the respective stroke of the closure piece 7, so that not only a determination can be made about the delivery state or non-delivery.

The embodiment according to Fig. 3 differs from the previously described embodiment only in the structure of the sensor device 10 and the corresponding adaptation of the closure piece 7 to a different principle, with

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in which the displacement of the closure piece 7 as a result of the fluid grease flowing through the housing 1 is detected. A permanent magnet 21 is inserted into the closure piece 7, which induces a voltage in a coil 19 surrounding the housing 1 when the closure piece 7 is displaced. It is understood that in this design the housing 1 is made of a material which does not prevent the formation of the magnetic field of the permanent magnet 21 through the housing 1 to the induction coil 19.

Fig. 4 shows a further embodiment in which the displacement of the closure piece 7 is detected by means of an electric field, and for this purpose capacitor plates 20 are arranged on the outside of the housing 1, between which the housing 1, the fluid grease and the closure piece 7 together form a dielectric. In this case, the closure piece 7 has a different dielectric constant than the fluid grease, so that when the closure piece 7 is displaced, a change in the electric field occurs between the capacitor plates 20, which can be recorded in an appropriately designed evaluation unit for detecting the change in position of the closure piece 7.

The light barrier described is connected electrically in the usual way via a downstream amplifier to an evaluation electronics, which - as mentioned - is not shown in the drawing. The output signal of the light barrier can therefore be used, for example, in the central control of a central lubrication system with the pump signal

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be checked for compliance. In principle, it is also possible to separate the light-active, elementary components of the optical transmitter 11 and/or the optical receiver 13 from the associated electronic assembly in accordance with the zone by means of a light guide, so that the monitoring device according to the invention can also be operated in potentially explosive areas. Explosion protection is particularly important for applications in petrochemical areas or for petrochemical products.

Claims (10)

1. Device for monitoring the delivery of viscous media, such as fluid greases, in pipelines, such as those of a central lubrication system, characterized by a housing (1) through which the medium flows, which can be inserted or attached into the respective pipeline, and which has an inlet opening (3) and an outlet (5), and with a closure body (7) which is pressed against the inlet opening (3) by the force of a spring (8) and around which the medium can flow, and for detecting the change in position of the closure body, a sensor device (10) which can be connected to an evaluation unit is arranged on the housing (1). 2. Device according to claim 1,
characterized, that the housing (1) consists of a material permeable to magnetic fields and the closure body (7) is magnetic or contains a magnet and that the sensor device (10) has sensor elements that detect magnetic fields. 3. Device according to claim 1,
characterized, that the housing (1) consists of a material permeable to an electric field and the closure body - 2 - 5329 (7) has a dielectric constant that differs from the medium and that the sensor device (10) has components that generate an electric field and sensor elements that detect changes in capacitance. 4. Device according to claim 1,
characterized, that the housing (1) and the medium are at least partially transparent to light and the closure body (7) is opaque, whereby the sensor device (10) on the housing (1) has an optical transmitter (11) and an optical receiver (13), the optical connection of which through the housing (1) is either completely or partially interrupted after the position change of the closure body (7) from the starting position at the inlet opening (3) of the housing (1) or is established after a previous interruption in the starting position. 5. Device according to claim 4,
characterized, that the optical connection between the optical transmitter (11) and the optical receiver (13) consists of a directional light barrier, for the passage of which the closure body (7) has a slot (17). 6. Device according to claim 5,
characterized, that the optical transmitter (11) and/or the optical receiver (13) have slit diaphragms (15) whose slit openings (16) are aligned with the slot (17) of the closure body (7) in its respective position. - 3 - 5329 7. Device according to one of claims 1-6,
characterized, that the housing (1) encloses a hollow cylinder (2), on one end of which the inlet opening (3) is arranged and on the other end of which the outlet (5) is arranged. 8. Device according to claim 7,
characterized, that the spring (8) is arranged as a compression spring coaxially in the housing (1) between the side of the closure body (7) remote from the inlet opening (3) and the end face (9) in the housing (1) with the outlet (5). 9. Device according to claim 7 or 8,
characterized, that the closure body (7) is guided in the housing (1) in the manner of a piston and has an approximately polygonal cross-sectional shape for the purpose of partial support on the hollow cylinder (2) while forming longitudinal flow channels (18) for the medium. 10. Device according to claim 6 and 9,
characterized, that the slot (17) of the closure body (7) is formed by a circumferential recess.