DE19523816A1 - Dosing device with spring return - Google Patents

Abstract

The invention concerns an electromagnetically operable and controllable dosing device for dispensing precise volumes of fluids (F) of various types and viscosities. It is proposed that the armature element (3) should be mounted outside the dosing housing (8a, 8b) and downstream of the pump chamber so as to be capable of sliding and coupled mechanically (9, 10) with the sliding flap valve (5) which forms the pump element. The valves (5, 7), which can move relative to one another and define the pump chamber, are connected to one another so as to form a seal via a spring restoring element (12) which is radially rigid and non-deformable but axially compressible.

Description

The invention relates to an electromagnetically actuated and controllable dosing device for the volumetrically precise Dosage of products of various types and viscosities.

There are metering devices with an electromagnetic Actuator and one included in this Dosing housing known, in which by two relative to each other movable and only opening in the direction of flow Check valves limited pump chamber is provided, the Pumping movement with the help of a through the actuator cyclically with a relatively high frequency, e.g. B. the frequency of one AC network, moving anchor element is generated. The Anchor element is inside the metering housing and in Flow path arranged while being relative to each other movable check valves over a single fold forming bellows are compliant and sealed connected. It turns out that these known metering devices only in a limited viscosity range of the products to be dosed and only volumetrically accurate at relatively low pump pressures work. This limits the scope as well also the forwarding of the metered product quantities, so that a liquid to be mixed with it, such as hot or cold water up to the outlet of the dosing device, in order to be able to take up the dosed product quantities there.

It is an object of the invention to provide a metering device of this type to train so that this in a much larger Can be used regardless of the application Viscosity operated with high volumetric accuracy can, and indeed in such a way that the metered product quantities can be transported over sufficient distances, so as to the metering device in the normal flow path of the Mixed liquid to be transferred.

This object is achieved according to claim 1.  

On the one hand, essential for the solution of the task Arrangement of the anchor element outside the metering housing and thus outside the flow path of the product to be dosed. The anchor element can thereby be dimensioned larger on the one hand and on the other hand much cheaper than before in the arranged magnetic field generated by the actuator will. This allows the actuator generated driving force much more optimal and lossless transferred to the moving pump element of the metering device, with which the external anchor element directly and mechanically is coupled. The higher transferable driving force enables the exercise of significantly higher pump pressures, which is the application of the dosing system also for products with higher viscosity enables and also the transport of the metered product quantities enabled over sufficient path lengths.

The main characteristic of the new teaching is that in specially designed and arranged spring return Element that is at the same time the relatively movable parts connects the pump chamber together and the pump chamber is effective seals to the outside. This training ensures that the volume of the pumping chamber is cyclical Pump movements in a precisely predetermined and reproducible way Modified, even with a relatively high pump pressure, the is achieved by the external anchor element.

The invention is described below with the aid of schematic drawings explained in more detail using several exemplary embodiments.

Fig. 1 shows a vertical section through a metering device according to the invention in a preferred embodiment.

FIG. 2 shows in detail and on a larger scale a detail of the device according to FIG. 1.

Fig. 3 shows in section and in vertical section a modified embodiment of the metering device, while

Fig. 4 shows in a similar representation as Fig. 2 and on a larger scale a modified version of the spring return element.

Fig. 5 shows a toothing 11 b, 9 b of the inner support 9 , 11 of the spring element; it is offset against each other in the upper and lower half.

In Fig. 1, the electromagnetic actuating device is indicated at 1 , which has a working air gap 2 , compared to which an anchor element 3 is provided in a particularly favorable arrangement, based on the electromagnetic field generated by the actuating device, which is arranged outside the housing of a metering device, which is in turn arranged in a recess or opening in the actuating device. The metering device 4 has a metering housing formed from an inlet part 8 a and an outlet part 8 b, which, as shown at 8 c, can be snap-connected to one another. A first support part 11 for an outlet check valve 7 is immovably provided in the housing, and the support part 9 of an inlet check valve 5 is spaced apart from it in the direction of flow. The supporting part 9 with the check valve 5 is movably arranged in the housing and for this purpose directly and mechanically coupled via coupling elements and force transmission elements 9 , 10 , possibly also via a snap connection or a bayonet-like connection, with the anchor element 3 arranged in the flow direction behind the pump chamber . The check valve 5 and the armature 3 thus move as a common movement unit.

The supporting parts 9 and 11 of the two check valves are connected to one another in a sealing manner by a compressible spring return element 12 , the details of which can be seen even better from FIG. 2. The two check valves 5 and 7 are also connected to one another by a central pin arrangement, via which a stroke limitation in both directions of movement can take place at the same time. Furthermore, a seal 6 is connected to the support part 9 of the inlet check valve 5 , which is moved with the movement unit and rests like a lip on the inner surface of the inlet housing 8 a of the metering device.

As can be clearly seen from FIG. 2, the spring return element 12 is dimensioned and arranged in such a way that it is practically resistant to deformation in the radial direction and is essentially compressible only in the axial direction. For this purpose, the spring return element 12 has end sections 15 and 16 , with which it is connected in a sealing and fixed manner to the two support devices 9 and 11 of the check valves. A middle section is provided between the end sections and has a slight bulge 17 towards the outside, on the inner surface of which a projecting annular bead 19 is provided. In FIG. 2, the spring return element is thus shown in the compressed position, at the end of the pump stroke. It can be seen that the spring return element in this position is largely enclosed by solid surfaces, namely by surfaces of the housing 8 a and by fixed surfaces on collars 9 a and 11 a of the two supporting parts 9 and 11 of the check valves. The shape and position of the spring return element in the compressed position are thus precisely defined, since the middle part 17 , 19 is also supported on fixed surfaces in a form-retaining manner. At the end of the suction movement there is also a defined position for the spring return element, as shown in FIG. 1, right half shows a toothing 11 b, 9 b of the inner support 9 , 11 of the spring element; it is staggered in the upper and lower half. In this position, the annular bead 19 bears against the collar 11 a and prevents the spring return element from being pulled radially inward during the suction vacuum of the pump movement and thereby falsifying the initial volume before the pump stroke. In addition, since the spring return element is particularly strong, it has considerable radial rigidity anyway and also develops a considerable restoring force when compressed. This does not affect the pumping capacity, since the favorable arrangement of the armature element allows the driving force generated by the actuating device to be optimally absorbed by the armature element and transmitted to the movable pump element 5 .

In the embodiment according to FIG. 3, the two parts 20 and 24 of the housing of the metering device are connected to one another by a corrugated tube 28 , which has a high degree of radial rigidity, but can be sufficiently axially compressed by the anchor element 23 during the pumping stroke and thereby has a sufficient restoring force for the housing part 24 , which also serves as a pump element, is produced. The inlet check valve is designated 21 and the outlet check valve 22 . The arms 25 cooperate with a recess 26 of the housing part 20 for the exact limitation of the pumping movements, so that in this embodiment too the pumping chamber 27 produces a precisely determined reproducible volume and corresponding reproducible volume changes.

In the embodiment according to FIG. 4, the elastic restoring element 12 of FIG. 2 is replaced by an elastomeric sleeve body 30 , which consists of a plurality of sealing rings arranged one above the other and integrally connected to one another. Here too, the element 30 inherently has a relatively large radial deformation stiffness, while it is sufficient in the axial direction and compressible with the development of the restoring force. In addition, the element in its end positions, but also in all intermediate positions, is largely and optimally supported in the radial direction outwards and inwards by the surfaces of fixed wall parts.

In all embodiments, a minimal radial Pump chamber elasticity reached. The compression of the Spring return elements developed restoring force can advantageously over half the effective anchor force be. The spring return element forms in all Embodiments also seal the pump chamber. The internal friction of the spring return element and the friction the surfaces of the solid wall parts lead to one - not relevant - performance loss of the pump, but has the special Advantage of a high damping, so that with pump cycles accordingly the AC frequency falsifications due to rebound effects cannot occur on the pump element.

Claims (7)

1.Electromagnetically actuated and controllable metering device for the volumetrically accurate metering of products of different types and viscosities with an elongated metering housing and one in the metering housing between a product inlet and a product outlet check valve - one of which is immovable with its supporting part in the direction of flow and that the other, with its supporting part, is arranged to be movable in the flow direction via an anchor element ( 3 ) which can be moved by an electromagnetic actuation and control device - limited pressure chamber, in which

• (a) the armature element ( 3 ) is arranged movably outside the metering housing ( 8 a, 8 b) and in the flow direction behind the pump chamber ( 13 ) and is mechanically coupled ( 9, 10 ) to the movable check valve ( 5 ) forming the pump element, and
• (b) the parts ( 5 , 7 ) which are movable relative to one another and delimit the pump chamber are connected to one another in a sealing manner by means of a radially rigid but axially compressible spring return element ( 12 ).

2. Dosing device according to claim 1, characterized in that the spring return element consists of a corrugated tube ( 28 ), in particular made of metal. 3. Dosing device according to claim 1, characterized in that the spring return element ( 12 ; 30 ) consists of elastomeric material and is supported mechanically or hydraulically radially rigid at least in each of the two end positions inside and outside. 4. Dosing device according to one of the mentioned claims, characterized in that the spring return element ( 12 ) consists of a substantially cylindrical sleeve made of elastomeric material and of a thickness resistant to radial bulging, which sleeve distributed one or more over its axial length, radially projecting areas ( 17 , 19 ) for radial support on radially inside and radially outside provided fixed wall sections ( 18 ; 9 a, 11 a). 5. Dosing device according to claim 3, characterized in that a surrounding the elastomeric restoring element, in axial direction by movable relative to each other Sealing elements hermetically sealed ring chamber with a predetermined amount of - possibly to a predetermined extent compressible - hydraulic fluid is filled. 6. Dosing device according to claim 4, wherein the inner support ( 18 , 9 a, 11 a) is toothed ( 11 b, 11 c, 11 d; 9 b, 9 c, 9 d). 7. Dosing device according to claim 6, in which the inner support is offset in its upper and lower halves from one another, is segmented circumferentially so that a circumferential largely inelastic pump chamber is formed in the pumping state ( FIG. 5).