DE102005040057A1 - Rotary mass flow measurement unit has a magnetic rotor with an elongated core element on the rear end of which is an annular magnet with poles of alternating polarity - Google Patents

Abstract

Rotary mass flow measurement unit has a tubular body (10) with an axial inlet for fluid and a magnetic sensor in a hollow space (15) to one side of a tubular body of the flow unit. A magnetic rotor (14) that rotates in a central chamber (13) has an elongated core element (17) on the rear of which in an annular magnet with poles or alternating polarities (N, S). At the fluid outlet a holding shaft (27) for the rotor runs radially in the central chamber.

Description

The The invention relates to the field of rotary flow meters, and more particularly a rotary flow meter, which measures the fluid flow rate or flow and the type is that of a tubular body includes, with a chamber for a magnetic rotor is provided, wherein the fluid causes the He freely rotates so that he forms a magnetic sensor, the can supply electrical signals whose frequency is proportional to the number the magnetic poles of the rotor and the speed of the rotor is that of the flow rate of the fluid depends along a path flows, the one mentioned above Chamber in the tubular Body of Flowmeter includes.

Rotary flow meter are well known and z. B. in heating systems or for others Hydraulic applications, eg. B. in small wall gas boilers used, to control signals or a flow signal indication of the circulation of the fluid to deliver.

Examples of flow meters are disclosed in GB-A-1 008 508, US-A-3 878 711, EP-A-1 308 702, GB 2 234 824 and DE-A-10 111 993, which constitute the closest prior art to this invention.

in the Generally, the flowmeters of the known type have one slightly complicated construction, consisting of several separately manufactured parts composed in the following, in a tubular body, the between an inlet side and an outlet side, a flow path for a Fluid must be defined, assembled.

In the tubular body the device is arranged a magnetic rotor or a magnetic impeller, which can rotate freely; the magnet rotor essentially comprises a hub, which is provided with a set of leaves that through the flow of the through the tubular body of the flowmeter flowing Can rotate fluids.

Of the Rotor is common with several leaves provided, which are made of a magnetic material and in With respect to the longitudinal axis of the Rotors are inclined to from the axially flowing through the flow meter fluid the for to receive the rotation necessary thrust.

Besides that is the rotor both on the inlet side and on the outlet side held directly or indirectly by spoke holder, which in the tubular body of the meter are arranged.

As an alternative to a rotor with magnetic blades strikes EP 1 308 702 the installation of one or more axially polarized permanent magnets, which are arranged radially on a T-shaped head at the flow inlet side facing the end of the rotor.

These solutions are not only structurally complicated and therefore expensive, but the special construction and functional features of the impeller and the usual Spoke holding systems cause excessive throttling and obstacles which in turn is undesirable Causes turbulence, which tends to impurities and / or Retain filaments that may be entrained by the fluid; thus can the rotation of the impeller and negatively affect the proper function of the flowmeter over time or endangered become.

DE-A-10 111 993 discloses a solution which is an improvement from a certain point of view, because it uses a rotor with flat-shaped magnetic wings suitable according to the flow direction of the fluid are oriented in an axial direction of the rotor; wherein at the Flusseinlassseite a Flußablenker is arranged. Nevertheless, this solution also has a big Part of the aforementioned Disadvantage; In particular, the cylindrical configuration of the Central hub of the rotor and as before the presence of a spoke holder on both sides, for the fluid turbulence and excessive throttling to create.

Finally in rotors with leaves out magnetic material generally uses only four radial wings, what a limit of the magnetic poles and the number of each Rotation of the rotor has generated electrical signals, unless more complicated and expensive rotors with large diameter be used.

A lower number of pulse signals per revolution means that must be made that the rotor rotates at higher speeds to within the time unit, the required number of signal pulses to create.

Taking into account that the current tendency is to use plastic material for the rotor or the impeller and the respective holders to a greater extent, all this leads to a greater wear, in particular of the rear holder on the outlet side, which consequently further a failure of the flowmeter causes; furthermore, at low flow rates, it may result in an insufficient number of signals or, at low speeds, electrical signals with insufficient frequency and too low a value.

Of the The invention is therefore based on the object to provide a rotary flow meter, which is constructionally simple, causes very low costs and thus existing in the previously known flow meters Disadvantages eliminated.

These The object is achieved by a rotary flow meter according to claim 1. Further developments of the invention are specified in the dependent claims.

According to one Feature of the invention is a flow meter of the type mentioned above created, which can provide a high flow passage for the fluid and with it possible Causes of turbulence and accumulation of foreign bodies such as filaments entrained by the fluid or ironstone, which will come off the pipeline over time and become uncontrolled Way at the leaves deposit the rotor and bring it out of balance, can reduce.

According to one Another feature of the invention provides a flow meter as mentioned above. the more reliable is in operation and thus possible Causes of wear or failure a minimum is reduced.

One Yet another feature of the invention is that it provides a flow meter that by means of a simple and inexpensive solution even for low values of the river and / or the rotor speed provide suitable electrical control signals can.

According to the invention becomes a flow meter the above mentioned Art created in which a special shape of the rotor and special Features and a special arrangement of the magnets and a sensor device to generate electrical control signals, the turbulence of the Reduce river to a minimum and a satisfactory To ensure protection of the magnet from the deposition of foreign bodies by the magnet itself is subjected to an uninterrupted flushing action by the fluid is.

There for the Rotor is applied a special holding system, in addition to particular the restricted Flow points on the rear holding side of the rotor a more effective Cleaning effect can be achieved and allows the flowmeter either installed in a horizontal or in a vertical position becomes.

In particular, the invention provides a rotary flow meter comprising:
a tubular body defining an axial passage for a fluid from an inlet side through a central chamber to an outlet side;
a magnet rotor which freely rotates in the central chamber and has a plurality of flat blades which are parallel to the longitudinal axis of the rotor;
a flow deflector at the inlet side of the central chamber; and
a magnetic sensor in a cavity on one side of the tubular body of the flowmeter,
characterized in that
the rotor comprises an elongated core member extending axially in the central chamber of the core member, diverge rearwardly to the fluid outlet;
a ring magnet is provided on the back of the core element, which has a plurality of radially oriented pole faces with alternating polarities; and
at the fluid outlet, a support shaft for the rotor extends radially into the central chamber.

Further Features and advantages of the invention will become apparent upon reading the following description of a preferred embodiment based on the drawing Refers; show it:

1 a perspective view of the flow meter, wherein a part of the tubular body is removed;

2 a longitudinal sectional view;

3 a cross-sectional view taken along the line 3-3 2 ;

4 a view of the rotor; and

5 a view of the river deflector.

As in the 1 - 3 is shown, the flowmeter comprises a tubular body 10 made of plastic molding material with a Flusseinlassende 11 and with a river outlet end 12 that the inlet end 11 is opposite and axially aligned thereon.

The tubular body 10 defines a middle chamber 13 for a magnet rotor 14 who is in the chamber 13 of the tubular body 10 is held freely rotating. The reference number 15 denotes in the various figures a lateral cavity in which an electromagnetic sensor 16 , z. B. a "Hall" probe is housed, the or the by the rotation of the magnet rotor 14 is exposed to the generated magnetic field; the cavity 15 , in which the sensor is housed, is tangential to the body 10 arranged and extends in the longitudinal direction of the axis of rotation of the rotor 14 on one side over a greater width than the ring magnet 18 ,

As more detailed in 4 is shown, the rotor comprises 14 an elongated core element 17 as well as a lot of radial leaves 22 ; the core element 17 is essentially conically shaped and goes in the outflow direction of the fluid to a ring magnet 18 apart; the magnet 18 is radially polarized so that it has on its peripheral surface a plurality of magnetic poles, for. B. has six pole faces, which have alternately opposite polarities N and S.

According to the example 4 includes the core element 17 with respect to the flow direction of the fluid of the rotor, a front cylindrical portion 17A with a relatively small diameter and a conical intermediate section 17B , which gradually up to a hub section 19 diverge, with the conical section 17B having a diameter that is substantially equal to the outer diameter of the ring magnet 18 is. In this way, the through the rear end of the core element 17 protected front surface of the magnet 18 is not exposed to the fluid while the outer surface of this magnet is effectively covered by the flow of fluid and rinsed continuously, which helps to remove any filament and debris deposits that may have been retained by the magnet so as to be kept clean ,

It is also noted that a flow meter according to the invention can be installed in either a vertical or a horizontal position; Further, the weight of the rotor 14 mainly by the cylinder magnet 18 conditionally, which has a smaller diameter than the types with magnetic sheets; thus subject to the entire rotor 14 lower centrifugal forces, which utilizes its adaptation and sensitivity to changes in the flowrate flow.

Both ends of the core element 17 are with a respective rotor shaft 20 and 21 Mistake.

In addition, the rotor includes 14 several flat leaves 22 whose number does not depend on the number of north and south poles of the magnet 18 depends, in the figures z. B. four poles that go in the longitudinal direction and in radial planes through the axis of rotation of the rotor. The leaves 22 go from a point near the front end of the center core 17 make a new center point and end near with a sloped edge that conforms to the inner shape of the tubular body 10 is adjusted.

At the flow inlet side at the front end of the chamber 13 a flow deflector is provided which is designed to transversely direct the thin incoming fluid flow to cause its swirl and leaves 22 of the rotor, causing them to rotate.

The flow deflector essentially comprises an annular element 23 which is in a suitable seat in the inlet 11 is housed; the annular element 23 is with several inner wings 24 provided which are angled off from each other and are inclined in the same direction; Preferably, the wings 24 to distract the river helical and their number is different from that of the leaves 22 of the rotor and z. B. larger than this.

The wings 24 are in the middle with a hollow hub 25 connected to the front shaft 20 penetrates the rotor. On the opposite side of the rotor penetrates the shaft 21 in a second hollow hub 26 one at the end of a holding shaft 27 is arranged, which radially into the chamber 13 protruding from the rotor; In this way, not only is it possible to maintain ample cross-sectional area to allow the fluid to flow on the outlet side, but also to substantially reduce the potential causes of vortex formation and accumulation of contaminants entrained by the fluid. In addition, reduce the substantially conical shape of the center core 17 of the rotor, which diverge in the same direction in which the fluid flows, the flat shape and the longitudinal arrangement of the leaves 22 as well as the absence of end faces of the magnet 18 in contact with the fluid greatly the axial thrust on the rotor and the possible causes of wear of the rotor shafts; Thus, the construction of the rotor is also ideally balanced.

Out It is clear from the description and from the attached drawing that a flow meter with new features have been created that achieve the desired improvements; however, you can on the tubular Body, on the rotor, on the flow diverter, and on the rotor retention system itself, of course further modifications and changes without departing from the scope of the claims.

Claims (9)

A red blood cell flowmeter comprising: a tubular body ( 16 ), which has an axial Passage for a fluid from an inlet side ( 11 ) through a middle chamber ( 13 ) to an outlet side ( 12 ) Are defined; a magnetic rotor ( 14 ), which is in the middle chamber ( 13 ) freely rotates and several flat leaves ( 22 ), which is parallel to the longitudinal axis of the rotor ( 14 ) run; a flow deflector ( 23 . 24 ) on the inlet side ( 11 ) of the middle chamber ( 13 ); and a magnetic sensor ( 16 ) in a cavity ( 15 ) on one side of the tubular body ( 10 ) of the flowmeter, characterized in that the rotor ( 14 ) an elongated core element ( 17 ) which axially in the middle chamber ( 13 ) of the core element ( 17 ), pointing back to the fluid outlet (FIG. 12 ) diverge; at the back of the core element ( 17 ) a ring magnet ( 18 ) is provided, which has a plurality of radially oriented pole faces with alternating polarities (N, S); and at the fluid outlet ( 12 ) a holding shaft ( 27 ) for the rotor ( 14 ) radially into the middle chamber ( 13 ) runs. Rotary flowmeter according to claim 1, characterized in that the magnetic sensor ( 16 ) comprises a Hall probe. Rotary flow meter according to claim 1 or 2, characterized in that the core element ( 17 ) of the rotor comprises a rear portion, the diameter of the outer diameter of the ring magnet ( 18 ) corresponds. Rotary flowmeter according to one of claims 1 to 3, characterized in that the number of pole faces (N, S) of the magnet ( 18 ) greater than the number of rotor blades ( 22 ). Rotary flow meter according to any one of the preceding claims, characterized in that the number of blades ( 24 ) of the flow deflector ( 23 . 24 ) of the number of rotor blades ( 22 ) is different. Rotary flow meter according to any preceding claim, characterized in that the number of blades ( 24 ) of the flow deflector ( 23 . 24 ) greater than the number of rotor blades ( 22 ). Rotary flow meter according to any preceding claim, characterized in that the blades ( 24 ) of the flow deflector ( 23 . 24 ) are helical. Rotary flow meter according to any preceding claim, characterized in that the cavity ( 15 ), in which the sensor ( 16 ), near the ring magnet ( 18 ) of the rotor ( 14 ) tangential to the tubular body ( 10 ) is arranged. Rotary flow meter according to claim 8, characterized in that the cavity ( 15 ), in which the sensor ( 16 ), over a greater width than the ring magnet ( 18 ) runs.