EP0664153B1 - Mixer - Google Patents

Description

The present invention relates to a mixer for double discharge cartridges according to the generic term of Claim 1. Such mixers are previously known, for example from EP-B-0 121 342, and have the task the two components that are discharged from the discharge cartridges are to be mixed intimately in order to prepare them in this way to be able to apply.

If the two storage cylinders of the discharge cartridge are approximate have the same volume and also approximately that have the same discharge openings, mixing no major problems from the start more. However, if the storage cylinders are significantly different Volumes - which is synonymous with different Cross-sections is because the storage cylinders are manufacturing and have the same length for operational reasons - and outlet openings have, for example in a ratio of 10: 1, there is a risk that the component from the larger Storage cylinder at the beginning of the discharge the mixer coil group of the mixer and thus the second Component with lower volume suppressed or overwhelmed becomes. In particular, presses in the entrance area larger partial flow "A" the smaller partial flow "B" to the B-side wall of the mixing tube, where this, due to the Wall friction remains and therefore from the larger A component overwhelmed or suppressed and therefore can only establish itself as a current after some time. While this initial phase leads the partial flow A and it there can be no mixing in the intended proportions, which results in the components not or only partially react with each other and thereby processing to faulty connections, seals, Imprints, etc. is coming.

Since the second component is generally the Hardener (catalyst) acts and a component mixture is not usable with too little hardener, it is for stabilization of the partial streams in the desired proportioning usual to squeeze a certain amount of useless first before started with the actual application of the mixture can be. Aside from the loss of component mass, you can do not harden and discharge these discharged substances Lead to problems in disposal.

In EP-A-0 584 428 (application 24.08.92; date of publication 02.03.94) proposed a solution to this problem by making the first, larger component initially pent up in a chamber will and means are available to this first component into the entrance chamber of the second component manage and carry this. Although this version is a Improvement over the state of the art known at the time brought, this solution requires a greater flow resistance due to several cross-sectional reductions required. This increased flow resistance can Require reinforcement of the cartridge walls and requires higher forces when discharging.

In addition, a discharge device is known from EP-A-0 472 448, in which the outlets of the discharge device or Cartridge housing are arranged so that the larger Component that flows around the smaller one and takes it along. The The device is intended to work with or without a mixer. If If no mixer is used, the two components come already in the cartridge or in the discharge device and hardened mass leads to that after changing the cartridge of the outlet area needs to be cleaned before can continue to work. When using a Mixing takes place there and after replacement the mixer can be cleaned without cleaning the outlet area Cartridge, or the discharge device to be continued.

With the device specified above, however, no precautions are taken for an exact mixing ratio in the mixer.

Based on this, it is the object of the present invention specify a mixer in which the cartridges side by side escaping components in the input section be that the two components are the first mixer element flow in such a way that a good mixing of Is guaranteed from the beginning, and before the first mixing coil group no increased flow resistance is generated. A Mixer that solves this problem is described in claim 1.

Die Fig. 1, 1a und 2 zeigen in perspektivischer Sicht ein erstes Ausführungsbeispiel der Erfindung,

die Fig. 3 und 4 zeigen in perspektivischer Sicht ein zweites Ausführungsbeispiel der Erfindung, wobei Fig. 4 teilweise längs geschnitten ist,

Fig. 5 zeigt einen Schnitt gemäss der Linie V-V in Fig. 4, und

Fig. 6 zeigt einen Schnitt gemäss der Linie VI-VI in Fig. 4.

The invention is explained in more detail below with reference to a drawing of exemplary embodiments:

1, 1a and 2 show a perspective view of a first embodiment of the invention,

3 and 4 show a perspective view of a second embodiment of the invention, wherein FIG. 4 is partially cut longitudinally,

Fig. 5 shows a section along the line VV in Fig. 4, and

FIG. 6 shows a section along the line VI-VI in FIG. 4.

In the case of previously known mixers, the components arrive at random to the first coil of the mixer, the mixer coil group is constructed in such a way that the two components Mix well along the mixer to the discharge end. As mentioned at the beginning, it occurs with previously known Mixers with different volume ratios, respectively. Cross-sectional ratios of the supply cylinders to the Mass with the larger volume the mass with the smaller Volume, especially in the initial phase, i.e. when refilling of the mixing tube, suppressed or overwhelmed, so that no prescribed mixing ratio can arise. After a certain time, i.e. when the mixer is complete has been filled and a certain amount discharged the mixing ratio of the partial flows stabilizes to a predetermined value.

Figures 1 and 1a show the perspective view Input part 2 and the upper part of the mixing coil group 1 with Coils 9, 9a, and Figure 3 shows the entrance of the mixer housing 3. The in the mixer housing 3 matching input part 2 has one Alignment and guide bar 6 on the corresponding Guide groove 7 in the mixer housing 3 fits and also the Partial stream B leads. For aligning the mixer on the cartridge or on the discharge device can either as in Figure 1 the input part shows two alignment parts 4 and 5 have with the output of the cartridge or dispenser interact or the mixer housing can one Have cutout 25, with a corresponding cam interacts on the cartridge or on the discharge device.

The smaller component B comes from the cartridge outlet, or discharge device in channel 11, while the larger Component A the rest of the available volume of the front end. The formation and location of the canal causes component A to start at the first Spiral 9 completely encapsulates component B. From Fig. 1a can also be seen that the roof-shaped web 10, at where the first spiral begins, right in the middle of the channel 11 is arranged for the smaller component B and this split the partial flow A and partial flow B in half. Of the Cover flange 8 corresponds to the inside width of the mixer tube 13 and can optionally have a sealing bead. Below the cover flange, on the entrance the A component is diametrically opposite side an inclined baffle 12 is arranged, the jam of Any air or gas present is prevented and thus good ventilation and avoidance of in bulk trapped air bubbles guaranteed.

Through the exact alignment of both partial flows on the web 10 of the first coil 9, the web also behind the End wall 11a of the channel 11 extends, as well as wrapping component B by component A becomes an exact one Mixing ratio from the first helix and thus one ensures optimal mixing of both components as well a suppression of component B avoided. Furthermore care is taken that the cross sections of the two Partial flows in the area between the cover flange and the Bridge approximately correspond to the mixing ratio.

3-6 shows a second embodiment variant, where the channel for the smaller component B is completely enclosed. Since this is also one Mixer for a double cartridge with side by side Supply cylinders, the exit of B is due to the Cartridge and the entrance to the mixer for the smaller component B not in the middle, but on the side. For one optimal wrapping of component B by component A it is particularly advantageous to have component B in the middle of the mixer pipe.

In Fig. 3 you can see the input part in a perspective view 14 with the subsequent mixing coil group 15. The input part is on the B side with a cover flange 16 completed, an opening 17 for the smaller one Component B has, while the larger component A flows into the input part next to the cover flange 16. At the Connecting the mixer to the cartridge becomes the cartridge outlet 22 sealingly pressed against the cover flange 16.

The wall 18 is arranged perpendicular to the cover flange 16 and serves to center and stabilize the input part in the Mixer housing. This version is also below the Cover flange 16 and on the entry of the A component diametrically opposite side an oblique guide surface 12 arranged to achieve good ventilation.

The channel 19 for the smaller partial stream B is different to channel 11 of the previous version on all sides closed. Channel 19 is, see also FIG. 4, in relation to FIG the longitudinal axis of the mixer is arranged obliquely and opens into the middle of the mixer tube. Following the canal exit is the roof-shaped web 20 of the first Spiral 21, which divides the partial stream B in half, and so on a good prerequisite for proper mixing create. The first mixer element does not have to have a web 10 or 20 and it does not have to be roof-shaped.

The mixer housing 3B is a variant of the mixer housing 2 and is attached to the cartridge housing or can be attached to the discharge device via a bayonet connection and has a guide groove 7B, see Fig. 5, in which the wall 18 lying on the A side fits. The bayonet flange has a recess 26 that the alignment the mixer on the cartridge or on the discharge device serves.

4 is a cutaway view of the mixer housing 3B, in which the outlet 22 with the two Outputs 23 and 24 of the double cartridge or the discharge device is drawn. In the two cuts of the 5 and 6 it can be seen that the channel 19 in the center of the mixer tube 13B is guided.

From the above description it can be seen that the discharge openings the discharge cartridge or the discharge device with the Input openings of the mixer must match it Measures must be taken to ensure that the mixer in the right position on it, especially then if the volume and opening ratio of both storage cylinders is different from 1: 1, as in the present application. Various other measures are in the beginning mentioned EP-A-0 584 428 have been described. The same applies to the use of the present mixer according to the invention at a mixer connection on dosing and proportioning systems.

The mixer according to the invention ensures efficient and optimal mixing process. With this arrangement possible slight phase shifts or Pulsations between components A and B caused through various influences such as B. different Elasticity of the two cartridge cylinders, due to the hereby improved compensation or backmixing effect of the static mixer largely balanced. It is of course, make sure that the cross sections of the partial flows are proportioned in such a way that guarantees is that both sub-streams are the first spiral at the same time to reach.

Claims (8)

1. Mixer for double dispensing cartridges or dispensing appliances having at least two storage cylinders whose volumetric ratio is different from 1:1, comprising a mixer housing (3, 3B) which is attachable to the cartridge resp. the dispensing appliance, and a mixing helix group (1, 15) arranged in the mixer housing (3, 3B), the two laterally adjacent openings of the cartridge resp. the dispensing appliance communicating with the inlet portion (2, 14) of the mixing helix group, characterised in that the inlet portion (2, 14) in front of the mixing helix group (1, 15) is divided into a larger inlet chamber for the first component (A) having a greater dispensing volume and into a smaller inlet chamber (11, 19) for the second component (B) having a smaller dispensing volume, and in that the smaller inlet chamber is arranged and designed in such a manner that the first component (A) envelops the second component (B) at the exit of the inlet chambers and that the first inlet edge (10, 20) of the first helix (9, 21) divides both the flow of the first (A) and the flow of the second component (B) into equal parts.
2. Mixer according to claim 1, characterised in that the smaller inlet chamber is designed as a channel (11, 19) which ends in the centre of the mixing tube (13) in front of the first helix (9, 21).
3. Mixer according to claim 2, characterised in that the channel (11) is open on the side of the first component (A).
4. Mixer according to claim 2, characterised in that the channel (19) is designed as a closed tube.
5. Mixer according to one of claims 1 to 4, characterised in that the cross-sectional areas, resp. the volumes of the inlet chambers (11, 19; 2, 14) and thus of the partial flows (A, B) of the two components are proportioned in such a manner that the two partial flows reach the first helix (9, 21) at the same time.
6. Mixer according to one of claims 1 to 5, characterised in that diametrically opposite the inlet, the inlet chamber (2, 14) comprises means (12) allowing to prevent the retention of air and thus an inclusion of air bubbles in the larger partial flow (A).
7. Mixer according to one of claims 1 to 6, characterised in that the inlet portion (2, 14) and the housing (3, 3B) of the mixer comprise means (6, 7; 18, 7B) allowing an aligned mounting of the inlet portion including the mixing helix group (1, 15) in the mixer housing.
8. Mixer according to one of claims 1 to 7, characterised in that it comprises means (4, 5; 25, 26) which allow an aligned attachment of the mixer to the cartridge resp. the dispensing appliance.

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