EP0559223B1 - Module for attachment to a device for dispensing from a bottle - Google Patents

Description

The invention relates to a bottle dosing device with a plug-on module.

Bottle dosing devices are already generally known. The bottle dosing device described in DE-A-26 49 014 consists of a housing with a valve block which can be placed on a container in which the liquid to be dosed is located. A cylinder is connected to the valve block, in which a piston is mounted so as to be longitudinally displaceable. Liquid is sucked in by an upward movement of the piston. The subsequent downward movement of the piston releases this liquid through an ejection cannula. An intake valve and an exhaust valve are located in the valve block and control the intake and dispensing of the liquid accordingly. The piston is connected to an outer sleeve spanning the cylinder. The liquid volume to be aspirated and dispensed is set using an adjustable stop. In the case of a bottle dosing device of the type just explained, the liquid volume to be dosed can be set by the stop described. However, it is not possible to measure the volume of liquid actually dispensed. This can be achieved with a piston burette. Such a piston burette is described for example in DE-C-35 01 909. It contains a valve block for placing on a container, which is firmly connected to the cylinder of the piston burette. A piston for the metered delivery of liquid from the container is guided in a longitudinally displaceable manner in the cylinder. The piston is for dispensing liquid displaceable from the container in the cylinder by means of a gearwheel which can be actuated by an operating button and a toothed rack. The relative movements between the piston and cylinder are measured. Depending on this, the liquid quantities dispensed from the container can be read on an electronic digital display.

From DE-A-35 34 550 and DE-A-35 16 596 bottle dosing devices are known with which titration can be carried out. The additional device used for titration is connected to a sleeve which in turn is connected to the piston and which engages over the cylinder. As a result, the auxiliary device is moved with it when the piston is actuated. Handwheels through which the piston can be actuated are provided on the additional device. These handwheels take part in the piston movement and thereby load the piston. This also affects and impairs the accuracy of the measurement. The reading angle with which the metered volume of liquid is read changes with the movement of the auxiliary device following the piston movement. Furthermore, the drive for the sleeve is supported on the cylinder, which is also disadvantageous.

From DE-A-19 09 540 and DE-A-37 30 010 burettes are known with which it is possible to titrate and to measure and display the titrated liquid volume. When titrating, an initially undetermined amount of liquid is dispensed and measured. This is necessary, for example, if a liquid has to be added to another medium until a certain reaction takes place, for example until a color change has been reached, until a certain pH value has been reached or another chemical or physical value. As soon as this reaction has occurred, the titration process is ended and the volume of liquid dispensed is measured.

From US-A-24 12 295 a bottle dosing device ("syringe") with a plug-on module according to the preamble of claim 1 is known.

The object of the invention is to provide a way with which a bottle dosing device can be converted quickly and easily into a burette.

According to the invention, this object is achieved by the characterizing features of claim 1. The housing of the plug-on module has locking elements for releasable locking with corresponding locking elements of the bottle dosing device. The latching elements of the plug-on module preferably consist of projections which can be detachably connected to the corresponding latching elements of the bottle dosing device, preferably grooves. To make a burette from the bottle dosing device, the plug-on module is connected to the bottle dosing device. In particular, the plug-on module or its housing is connected to the housing or the valve block of the bottle dosing device, that is to say to a part of the bottle dosing device which does not move during the movement of the piston, as a result of which the one known from DE-A-35 34 550 Device-related disadvantages can be avoided. The driver of the plug-on module engages in an actuating part or adjusting slide which is connected to the piston of the bottle dosing device. The actuating part or adjusting slide is preferably connected to the outer jacket of the bottle metering device, the outer jacket of the bottle metering device engaging over the cylinder of the bottle metering device and being connected to the piston. The connection of the plug-on module with the bottle dosing device can be released again.

The solution according to the invention makes it possible to use a bottle dosing device easy and quick to convert into a burette. The burette created in this way has the further advantage that it can be sterilized. For this purpose, the plug-on module, including any electronics connected to it, is removed. The bottle dosing device can then be sterilized. The plug-on module can then be connected again to the bottle dosing device in order to create a burette again.

If the plug-on module is connected to the bottle dosing device, the driver of the plug-on module is operatively connected to the corresponding actuating part or adjusting slide of the bottle dosing device, for example by the driver engaging in the actuating part or the adjusting slide. In general, the actuating part or the adjusting slide of the bottle dosing device executes a longitudinal movement, so that the driver of the plug-on module must also perform a corresponding longitudinal movement. But it is also possible that the actuating part of the bottle dosing device performs a rotary movement. Then the driver of the plug-on module must also be able to perform a corresponding rotary movement.

The plug-on module according to the invention can be used advantageously in particular if the piston of the bottle dosing device is connected to a sleeve which preferably overlaps the cylinder of the bottle dosing device. The actuating part or the adjusting slide of the bottle dosing device can be longitudinally displaceable and lockable. In particular, the actuating part or the adjusting slide of the bottle dosing device can be a preferably adjustable stop for the piston stroke of the bottle dosing device.

The invention creates the possibility of operating a bottle dosing device in two different ways: on the one hand, the dosing operation normally provided for the bottle dosing device can be carried out. The volume of liquid to be dispensed is adjusted, that is to say predefined, and then dispensed by means of a preferably adjustable stop. On the other hand the plug-on module can be connected to the bottle dosing device. Then the bottle dosing device has become a burette that can be used for titration. In general, the dispensed and measured liquid volume is also displayed by a suitable display device.

Advantageous further developments are described in the subclaims.

A measuring device is preferably provided for measuring the displacement path of the driver. In general, a display device for displaying the displacement path of the driver is also connected to this measuring device. With the displacement of the driver, the displacement of the piston and thus the volume of liquid dispensed is measured and displayed. If the driver does not perform a longitudinal movement but a rotary movement, the angle of rotation of the driver and thus the displacement path of the piston and thus also the volume of liquid dispensed is measured and displayed.

A threaded spindle can be rotatably mounted in the housing of the plug-on module, into which a threaded nut connected to the driver engages. The threaded nut can be integrally connected to the driver. By rotating the threaded spindle, the threaded nut and with it the driver are moved in the longitudinal direction, whereby the piston is also displaced.

The threaded spindle preferably has a first bevel gear, in which a second bevel gear engages. By rotating the second bevel gear, the first bevel gear and with it the threaded spindle are rotated. The axis of rotation of the second bevel gear preferably runs at right angles to the axis of rotation of the first bevel gear and thus also to the axis of rotation of the threaded spindle.

The second bevel gear can be connected to a handwheel and / or to a motor.

The threaded spindle preferably has a rotary encoder which can be scanned by a scanner connected to the housing of the plug-on module. In this way, the rotation of the threaded spindle and thus the stroke of the piston can be measured particularly easily and reliably.

A further advantageous development is characterized in that the housing of the plug-on module has latching elements, preferably projections, for releasable latching with corresponding latching elements, preferably grooves, of the bottle dosing device.

The bottle dosing device generally has a housing with a valve block, in which an intake line and a discharge line (pressure line) are located, as well as a suction valve and a pressure valve. An actuating part can be connected to the piston, which is preferably longitudinally displaceable and lockable and can thus form a preferably adjustable stop.

Fig. 1:

ein Aufsteckmodul für ein Flaschendosiergerät in einer Vorderansicht,

Fig. 2:

das in Fig. 1 gezeigte Aufsteckmodul in einer Seitenansicht,

Fig. 3:

ein Flaschendosiergerät in einer Seitenansicht,

Fig. 4:

das in Fig. 3 dargestellte Flaschendosiergerät in Verbindung mit dem Aufsteckmodul nach den Figuren 1 und 2,

Fig. 5:

einen Schnitt längs der Linie E-F in Fig. 4,

Fig. 6:

das in Fig. 4 dargestellte Flaschendosiergerät mit aufgestecktem Aufsteckmodul in einer Ansicht von hinten, teilweise im Schnitt (längs der Linie A-B in Fig. 8),

Fig. 7:

einen Schnitt längs der Linie G-H in Fig. 6 und

Fig. 8:

einen Schnitt längs der Linie C-D in Fig. 6.

An embodiment of the invention is described below with reference to the accompanying drawings. The drawing shows:

Fig. 1:

a plug-on module for a bottle dosing device in a front view,

Fig. 2:

1 in a side view,

Fig. 3:

a bottle dosing device in a side view,

Fig. 4:

3 in connection with the plug-on module according to FIGS. 1 and 2,

Fig. 5:

3 shows a section along the line EF in FIG. 4,

Fig. 6:

4 in a view from behind, partially in section (along the line AB in FIG. 8),

Fig. 7:

a section along the line GH in Fig. 6 and

Fig. 8:

a section along the line CD in Fig. 6th

The bottle dosing device provided with the reference number 1 consists of a valve block 2, which is provided with an ejection cannula 3, and an upward-pointing cylinder, in which a piston is guided in a longitudinally displaceable manner. The piston is connected to an outer sleeve 4 which engages over the cylinder. On the outer casing of the outer sleeve 4 there is an adjusting slide 5 which projects beyond the outer circumference of the outer sleeve 4. The outer sleeve 4 is preferably connected in one piece to a knob 6 at its upper end.

The plug-on module, designated overall by 7, has a housing 8 which can be detachably connected to the bottle dosing device 1. In the housing 8, a driver 9 is guided in a longitudinally displaceable manner. The housing 8 has parallel, spaced bearing blocks 10, in which a threaded spindle 11 is rotatably mounted. A threaded nut 12, which is connected to the driver 9, engages in the threaded spindle 11. The driver 9 has an extension 13 which engages in the groove formed by two spaced, parallel projections 14, whereby the extension 13 and thus the driver 9 is secured against rotation and reliably guided. At its extension 13 opposite At the end, the driver 9 has two spaced-apart projections 15 which surround the part of the adjusting slide 5 which projects beyond the outer jacket of the outer sleeve.

The threaded spindle 11 has at its lower end below the lower bearing block 10 a first bevel gear 16 aligned with the threaded spindle 11, which engages in a second bevel gear 17, the axis of rotation 18 of which runs at right angles to the axis of rotation 19 of the first bevel gear 16 and thus also the threaded spindle 11 . The second bevel gear 17 is connected to handwheels 20 provided on both sides of the housing 8. Instead of the handwheels 20 or in addition to these, a motor (not shown in the drawings), preferably an electric motor, can be provided for driving the second bevel gear 17.

The threaded spindle 11 has at its upper end above the upper bearing block 10 a rotary encoder 21 which can be scanned by a scanner 22 connected to the housing 8. The rotary encoder 21 can be designed as a grid disk. An embodiment is given in DE-A-38 18 531. The scanner 22 can be configured as a fork light barrier. However, it is also possible to use other scanning elements, for example magnetic scanning elements. The angle of rotation can be detected by pulse sampling and counting.

The housing 8 has at its lower end as projections 23 (FIG. 5) locking elements for releasable locking with locking elements designed as grooves 24, which are provided in the area of the valve block of the bottle dosing device 1. Furthermore, an axial safety catch 26 preloaded by a compression spring 25 is provided at the lower end of the housing 8, which engages behind a projection at the lower end of the valve block of the bottle dosing device 1 and at its lower end has a grooved grip strip 27 projecting downward from the housing 8 having.

The plug-on module 7 (FIGS. 1 and 2) is plugged onto the bottle dosing device 1 (FIG. 3) in the manner shown in FIGS. 4 to 8. It is secured in this position by the projections 23 of the plug-on module 7 which engage in the grooves 24 of the bottle dosing device 1 (FIG. 5). When the plug-on module 7 is plugged onto the bottle dosing device 1, the setting slide 5 is in the basic position shown in FIG. 3. The setting slide 5 is therefore on the same side as the ejection cannula 3. It is also in its lowest position, and is therefore set to the maximum volume. After plugging on the plug-on module 7, the outer sleeve 4 is rotated by its rotary knob 6 by 180 degrees. Then the adjusting slide 5 engages between the projections 15 of the driver 9 without play; the connection between the driver 9 and the setting slide 5 (and thus - via the outer sleeve 4 - the piston) is established.

Via the gear formed by the handwheels 20, the second bevel gear 17, the first bevel gear 16, the threaded spindle 11 and the threaded nut 12, the driver 9 and with it the adjusting slide 5 and the piston of the bottle dosing device can be moved axially. By means of the rotary encoder 21 connected to the threaded spindle 11, the stroke movement of the piston can be measured and evaluated exactly. This is preferably done by electronics connected to the rotary encoder 21 and the scanner 22. The amount of liquid dispensed and measured can preferably be displayed digitally.

Thanks to the plug-on module designed as an attachment (accessory), a bottle dosing device can be quickly and easily converted into a burette. Another advantage associated with this is that the bottle dosing device, which can also be referred to as a bottle dispenser, is autoclavable (sterilizable). For this purpose, only the plug-on module 7 has to be removed from the bottle dosing device 1 again. This is done in that the axial safety catch 26 is moved away from the projection on the valve block against the force of the compression spring 25 by an attack on the grip strip 27; the plug-on module 7 can then be removed from the bottle dosing device 1 by releasing the latching between the projections 23 and the grooves 24.

Claims (7)

1. Bottle dispenser (1) for dispensing liquid from a container with a cylinder and a longitudinally sliding piston contained therein, and with an attachment module (7) with a housing (8) connected to and detachable from the bottle dispenser (1), and with a drive element (9) for moving the piston, which drive element (9) is longitudinally guided in said housing (8),
   characterised in that
   the housing (8) of the attachment module (7) features latching elements, preferably protrusions (23) for detachable latching with corresponding latching elements, preferably grooves (24), in the bottle dispenser (1).
2. Bottle dispenser according to Claim 1, characterised by a measuring device for measuring the displacement of the drive element.
3. Bottle dispenser according to Claim 1 or Claim 2, characterised in that a threaded spindle (11) is pivot-mounted in the housing (8), on which threaded spindle (11) is fitted a threaded nut (12) connected to the drive element (9).
4. Bottle dispenser according to Claim 3, characterised in that the threaded spindle (11) features a first bevel gear (16) with which a second bevel gear (17) meshes, the rotary axis (18) of which second bevel gear (17) is preferably at right angles to the rotary axis (19) of the first bevel gear (16).
5. Bottle dispenser according to Claim 4, characterised in that the second bevel gear (17) is connected to a hand wheel (20) and/or to a motor.
6. Bottle dispenser according to one of Claims 3 to 5, characterised in that the threaded spindle (11) features a rotary transducer (21) which can be scanned by a pickup (22) connected to the housing (8).
7. Bottle dispenser according to one of the preceding claims, characterised in that the piston is connected to a sleeve (4) which envelops the cylinder.

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