DE3703929A1 - Device for pumping two viscous or pasty substances in a predetermined proportion from two reservoirs to one or more nozzles - Google Patents

Abstract

The device has a plunger pump (32) for the first substance, and a second plunger pump (40) for the second substance. The two plunger pumps are synchronised with each other, and pump the substances through a mixer to a nozzle. The plungers (33, 42) can be driven by a thrust spindle (34). <IMAGE>

Description

The invention relates to a device with the The preamble of claim 1 features specified. Such a device is used in particular for conveying of sealants and adhesives, which consist of two components (Binder and hardener) exist only immediately mixed together before processing and then set, reacting chemically with each other.

A device with in the preamble of the claim 1 specified features is part of annexes known for sealing insulating glass panes, which consist of glass panels glued together at the edge are. To seal the insulating glass properly to get discs, it is necessary that the two Components of the sealant and adhesive (usually one based on Thiokol) consistent in one predetermined quantity ratio from their respective pre pumped out of the container (preferably a barrel) mixed and sprayed out of a nozzle. To this end, it is known to store each of the two container for the two components that are are viscous or pasty substances, a pneumatically operated barrel pump and a hydraulic be assign actuated piston pump. The barrel pump delivers the component in question in the cylinder following it orderly piston pump and this promotes the component into a mixer. The pistons of the two piston pumps are mechanical to force synchronous movement coupled with each other; their clear cylinder cross-section  and the type of coupling are said to be the quantitative ratio determine in which the two components by the Piston pumps are pumped out of the storage containers.

The two components are placed in a static mixer promoted in which they are intimately mixed will. The components are then mixed into a buffer; it is a Piston-cylinder unit with a hydraulically operated piston, in the chamber in front of the piston front two mixed substances can be fed. The end The mixture is pressed out of the cylinder hydraulically with constant pressure, the amount of which by nature depends on the sealant and adhesive used and is typically approx. 40 bar. The two of them piston pumps assigned to the pumps promote the two Components of the sealant and adhesive with higher pressure into the clipboard, the piston of which on two ends switch acts; one limit switch is actuated as soon as the piston of the intermediate storage is pre-selected given immersion depth, and as a result of this The two become actuated to the storage containers orderly pumps turned on so that they the two Components of the sealant and adhesive in between Promote storage and its pistons against the un changes the hydraulic force on it push until a specified minimum immersion depth  of the piston in which the other Limit switch is operated, whereupon he the two Pumps associated pumps switches off, and even before the piston of the buffer the added component mixture towards its end stop is pressed. This way it is guaranteed ensures that on the one hand always one in the buffer certain amount of sealant and adhesive available stands that on the other hand also during the on feeding the sealant and glue in between store the pressure under which it is from the clipboard is pushed out again, regardless of the higher one Pressure that the pumps assigned to the storage tanks generate, does not exceed the specified pressure, which by the hydraulically operated piston of the Cache is exercised.

In the line between the buffer and the nozzle lies in the known device as a quantity dosage pump a gear pump, through which the amount of Control sealant and adhesive emerging from the nozzle is cash. This gear pump required one per to be able to effect proportional dosage (e.g. a Quantity dosage according to the width and / or depth the edge joint of an insulating glass pane) a constant Admission pressure, which the intermediate storage in the amount of approx. 40 bar provides.

The sealing and Adhesive, which ranges from mixer to  Nozzle is located. So that he can advance the funding routes direction is not clogged, it is necessary Rinse areas of the device in good time. To this purpose is immediately before the mixer in the Supply of one of the two components - more appropriate in the supply line for the hardener - a valve with two switching positions are provided, which in one Position the pump for this component with the mixer connects, but in the other switch position this Connection breaks and the one coming from the pump Line with one to be returned to the storage container Line connects so that the component (the hardener) can flow back to the reservoir. The last ge named position is the position in which rinsed will: only the main component (the binder) promoted the sealant and adhesive until the mixture of the two components that make up the mixer to Nozzle-extending part of the device completely is displaced, so that there no longer sets can be done. When the device is finished is put back into operation after a break the valve is returned to its original position; the device is only ready to work again, if the main component of the sealant and adhesive displaced from the area from the mixer to the nozzle and was replaced by the mixture.

The known device has the disadvantage that it  from a large number of assemblies (barrel pumps, piston pumps, Intermediate store with valves and pressure compensation system, mixer, gear pump, nozzle) and is complex to manufacture and control. Another disadvantage is that the volume of the conveyance routes that are flushed during breaks must be relatively large, so that with each Flushing process and every time the Device relatively large amounts of the two Components are lost. Corresponding losses also occur at regular intervals cleaning of the conveying paths to be carried out with solvent average.

Another disadvantage of the known device lies in that the lead time of the sealing and adhesive from entry into the mixer to exit is relatively long from the nozzle; during this The sealing and adhesive binds throughput time already partially. The lead time is operational breaks to add if you take those breaks determined duration, after which a rinse the device is required. Because business breaks are inevitable even when the workflow is undisturbed (when sealing insulating glass panes already occurs undisturbed succession of insulating glass panes between two successive insulating glass discs necessarily an interruption of the  Promotion of the sealant and adhesive) is one longer throughput times highly undesirable.

The invention has for its object a to simplify the direction of the type mentioned and at the same time to improve that the through running time of the mixture shortened by the device and the volume of the mixture in the device is wrestled.

This object is achieved with a device the features specified in claim 1. Before partial developments of the invention are the subject of subclaims.

In contrast, the device according to the invention requires to the known device between the mixer and the respective nozzle no longer has a metering pump. The Dosing is already sufficiently accurate by the synchronized used according to the invention Plunger pumps, their plungers by means of a thrust spindle can be driven. The spindle driven pumps meter in contrast to those in the known Pumps used not dependent on pressure, but depending on the path, so that the dosing accuracy in essentially from the cross section of the plunger used and depends on the accuracy of the spindle drive;  both can be done by the person skilled in the concrete Easily adjust the dosing task. A separate dosing pump, which in the known device between the mixer and the respective nozzle is required, can therefore be omitted here. Because the invention according to the spindle driven plunger pumps used Dosing independent of pressure can also be done with the State of the art required for pressure equalization in the conveying path between the piston pumps and the dosing pump intermediate storage is not required. That has the Advantage that the volume of the conveyor paths between the Plunger pumps and the nozzle is considerably smaller than in the known device. At the same time it is the throughput time of the mixture of the two substances drastically shortened. The device according to the invention can therefore extend downtimes accordingly cope before rinsing the be with the mixture funding routes is necessary. The invention thus leads with a double advantage: the shortened Pass time of the mixture through the device Rinsing is no longer necessary, and the amount of substance that ver lorenggeht is much lower than the known one Contraption. Instead of after the device has come to a standstill rinse, you can also from the rest of the device disconnect and during downtime, especially during the nightly shutdown, in a deep  Keep refrigerated container so that the mixture cannot harden. This possibility of low cooling is facilitated by the invention because only a relatively small part of the device, namely the part comprising the mixer and the nozzle, remove from the device and in the deep cool container.

So much for a way to rinse off the mixture assigned funding routes is provided, one sees purpose switching just in front of the mixer valve, especially a 3/2-way valve, which in its one position is the one plunger pump connects to the mixer and in its other Position the mixer from this one plunger pump separates them with a container, especially with the reservoir of this plunger pump promoted substance, connects, so that when rinsing the device only the one substance in the mixer and from there to the nozzle that others are redirected (returned).

The construction of the mixer, which the substances in front certain quantity ratio of the plunger pumps are supplied directly, is state of the art and not the subject of the present patent application. At least one nozzle follows the mixer. The  Mixers can also be arranged after several nozzles, as far as they should work synchronously and the capacity the mixer allows that. If you want two nozzles independently can control each other, then it is recommended for each nozzle a separate conveyor with the To provide features of the invention.

The two plunger pumps could each have their own You could have drive and to synchronize them synchronize these two drives electrically. However, an embodiment of the invention is preferred, in which the two plunger pumps mechanically synchronized are based and by means of a common shear spindle are drivable. This sole push spindle could be on engage a lever on which the two plungers at different distances from the fulcrum of the lever are directed. The two plungers are expedient hinged directly on the lever, but you could also between the lever and the respective plunger Provide handlebars.

The ratio of the funding of the two plungers pumping is determined on the one hand by the ratio of the two plunger cross sections and the other through the Ab stands in which the two plungers from the fulcrum of the Lever are articulated on the lever. Preferably the Ab stood the two articulation points of the plunger on the lever changeable, thereby changing the ratio of funding  of the two plunger pumps.

As a rule, the storage containers for the two Substances are barrels. In this case, a be special device to provide the substances the barrels in the cylinders of the first and second To promote plunger pump, from which it then passes the plunger can be dispensed. Suitable for this in particular as pneumatically operated piston pumps trained barrel pumps.

In the delivery path of at least one of these barrel pumps and the associated plunger pump is preferably seen a buffer. Such an intermediate memory has the advantage that it is an interruption free working with the device even during the Time in which a barrel change takes place. To the substance in question from the buffer to be able to transfer into the associated plunger pump the interior of the clipboard is best with with a constant pre-pressure. This before pressure can be very easily with the help of a bellows render, which one arranges in the buffer and from pressurized inside. The piston pulls back of the plunger pump, the bellows can expand and the substance from the buffer into the Press the plunger pump cylinder. In the case of plunger pumps with different delivery rates are recommended it is such a buffer at least the  Plunger pump with the greater delivery rate too arrange because this involves a more frequent barrel change finds. Are the two substances for example around the two components (binder and hardener) a two-component adhesive, in which ten parts of the Are to be mixed with part of the hardener, then at least the one intended for the binder should be A buffer can be assigned to the plunger pump, because there - assuming the same barrel sizes - a barrel change must be carried out ten times as often like the hardener.

An embodiment of the invention is in the Drawings shown schematically and is described below.

Fig. 1 shows, partly in section, partly in elevation and partly in block diagram of the apparatus without mixer and without nozzle,

Fig. 2 shows the section AB of FIG. 1, and

Fig. 3 shows the part missing in Fig. 1 Before the device with mixer and nozzle.

Fig. 1 shows two storage containers 1 and 2 for two different substances, of which it is assumed below that it is, for example, the two components of a two-component sealant and adhesive. The two storage containers 1 and 2 are cylindrical barrels. One barrel 1 contains the main component (binder), the other barrel 2 contains the additional component (hardener). Each drum has a drum pump 3 or 4 , which are basically constructed the same. The barrel pumps have a base plate 5 on which barrel 1 or 2 is located. On both sides of the barrel, two upright hydraulic cylinders 6 and 7 are attached to the base plate 5 , from the upper ends of which lead piston rods 8 and 9 , which are connected at their upper end by a horizontal cross member 10 . On the traverse 10 , a circular plate 13 is suspended on two diagonally arranged vertical rods 11 and 12 , which plunges into the barrel 1 or 2 and lies on the surface of the substance contained in the barrel. The plate 12 is provided in the middle with a passage 14 which opens into the cylinder 15 of a piston pump 16 attached to the plate 13 , the piston 17 of which is actuated by a pneumatic piston-cylinder unit 18 . The input of the cylinder 15 can be shut off by a rotary slide valve 19 .

To fill the cylinder 15 , the piston 17 is withdrawn; it can move from the hydraulic cylinders 6 and 7 pressurized from above plate 13 downward and displace the ent in the barrel 1 or 2 contained substance upward so that they slide valve 19 through the passage 14 and the open rotary valve 19 in the cylinder 15 flows. Before the substance is pressed out of the cylinder 15 , the rotary slide valve 19 is closed.

The barrel pump 3 conveys the main component through a line 20 , in which a check valve 21 is located and which is secured by a pressure switch 22 , into an intermediate store 23 , which is a container in which a bellows 24 is arranged, the interior of which can be hit by compressed air. The compressed air is supplied from a compressed air source 25 through a compressed air line 26 in which a manometer 27 and a pressure regulator 28 are located, whereby a constant, preselectable pressure can be set in the bellows.

The intermediate storage container 23 is closed at the top by a plate 29 , in which a passage 30 is provided, which opens into the cylinder 31 of a plunger pump 32 , which is fixed on the plate 29 . The plunger 33 of the plunger pump 31 is connected at its upper end to the lower end of a push spindle 34 which can be moved up and down in a controlled manner by an electrical stepping motor 35 . The inlet opening of the cylinder 31 is through a rotary valve 36, the outlet opening of the cylinder 31 is shut off by a rotary valve 37th

The cylinder 39 of a further plunger pump 40 is mounted on a horizontal support plate 38 attached to the side of the plate 29 so that it can pivot about a horizontal axis 41 . The plunger 42 of this second plunger pump, like the plunger 33 of the first plunger pump 32 , is guided upward out of the cylinder. Both plungers 33 and 42 are articulated with a lever 43 which is pivotally attached to a handlebar 45 about a horizontal axis of rotation 44 , which in turn is attached to the support plate 38 in a manner pivotable about a horizontal axis 46 . The different swivel axes all run parallel to each other. By means of the lever 43 , both plunger pumps 32 and 40 are actuated synchronously by one and the same push spindle 34 . The pivotable mounting of the second plunger pump 40 and the link 45 enable the necessary conversion of the pivoting movement of the lever 43 into the linear movement of the plungers 33 and 42 in their cylinders 31 and 39 .

The second plunger pump 40 can be shut off at its inlet opening by a rotary slide valve 47 and at its outlet opening by a rotary slide valve 48 .

The second barrel pump 4 promotes the additional component via a line 49 , in which there is a check valve 50 and which is secured by a pressure switch 51 , in the cylinder 39 of the second plunger pump 40 .

A line 52 leads from the outlet opening of the first plunger pump 32 , a line 53 leads from the outlet opening of the second plunger pump 40 to a mixer 54 , which in the exemplary embodiment shown is a two-stage static mixer (see FIG. 3). A nozzle 55 follows the mixer 54 .

A suitable upstream pressure for the bellows 24 is 6 bar. This pressure is maintained regardless of the degree of filling of the intermediate storage container 23 . As long as the delivery rate of the barrel pump 3 is greater than the removal rate of the plunger pump 32 , the bellows 24 remains compressed; in this case, the pressure switch 22 prevents the buffer 23 from overfilling and an undesirable pressure rise therein. If the cylinder 31 of the plunger pump 32 is to be filled at a point in time at which the barrel pump 3 cannot deliver (e.g. during a barrel change), the bellows 24 expands and displaces the necessary amount of the main component from the intermediate store 23 , so that it flows into the cylinder 31 (backflow to the barrel pump 3 is prevented by the check valve 21 ). The volume of the air bladder 24 and the latch 23 is measured advantageously so that the supply of the main component in sufficient latch 23 in order at the intended loading of the device operating as a change of the barrel 1 to carry out.

Simultaneously with the filling of the cylinder 31 of the first plunger pump 32 , the cylinder 39 of the second plunger pump 40 is also filled by the second barrel pump 4 , but here without an intermediate store. An overfilling of the cylinder 39 is prevented by the pressure switch 51 .

The quantity ratio in which the main component and the additional component are conveyed and mixed with one another is determined on the one hand by the cross sections of the two plungers 33 and 42 and on the other hand by the distances between the articulation points 56 and 56 a of the two plungers on the lever 43 from its pivot axis 44 . In order to be able to flush those conveying paths which were occupied by the mixture of the two components after a longer standstill, a flushing tap 57 is provided according to FIG. 3, which in the example shown is a 3/2-way valve, which in its one position (as shown in FIG. 3) connects the second plunger pump 40 to the mixer 54 and in its other position connects this second plunger pump 40 to a collecting container 58 , which can be a drum 2 , and the to mixer 54 leading section of line 53 blocks. When rinsing takes place in this position, only the main component is conveyed into the mixer 54 , but the additional component is returned. When the device is put back into operation, the flushing tap 57 is returned to its starting position, and as soon as the mixture of the two components appears again at the nozzle 55 instead of the main component, the device is ready for operation. The amount of the main component that is lost is small; it is determined by the volume of the mixer 54 and the subsequent conveying path to the nozzle 55 .

Instead of such a flushing device, one could also provide for the arrangement of the mixer 54 and the nozzle 55 to be removable so that it can be kept in a frozen container during downtimes.

If the mixture of the two components can be fed to two nozzles independently of each other, it is best to provide a separate plunger pump for the main component and a separate plunger pump for the additional component for each of the nozzles, with each pair having its own push spindle drive as shown in Fig. 1 is shown, is driven. The barrel pumps 3 and 4 are nevertheless only required once, and the intermediate storage container 23 is only needed once if - as shown in the detailed drawing in FIG. 2 - two plunger pumps 32 are arranged next to one another on the plate 29 of the intermediate storage container 23 , which can be of the same design. On the support plate 38 can be seen accordingly in addition to the plunger pump 40 is a further similar plunger pump for the additional component before, which is coupled to the second plunger pump for the main constituent in the same manner by a lever, as for shown in Fig. 1 plunger 32 and 40 is the case. A leading to the second plunger pump for the additional component feed line 59 is indicated by dashed lines in Fig. 1.

Claims (13)

1.Device for conveying two viscous or pasty substances in a predetermined quantitative ratio from two storage containers to one or more nozzles, with a first piston pump for the first substance and with a second piston pump for the second substance, which is synchronized with the first piston pump, and with a mixer arranged in the delivery paths between the two piston pumps and the nozzle or nozzles, characterized in that the piston pumps ( 32, 40 ) are designed as plunger pumps, the plungers ( 33, 42 ) of which can be driven by means of a thrust spindle ( 34 ). 2. Device according to claim 1, characterized in that the mixer ( 54 ) pumps the plunger ( 32, 40 ) is immediately downstream. 3. Apparatus according to claim 1 or 2, characterized in that the nozzle (s) ( 55 ) is the mixer ( 54 ) immediately downstream or are. 4. Device according to one of the preceding claims, characterized in that the plunger pumps ( 32, 40 ) are mechanically synchronized. 5. The device according to claim 4, characterized in that the plunger pumps ( 32, 40 ) can be driven by means of a common thrust spindle ( 34 ). 6. The device according to claim 5, characterized in that the thrust spindle ( 34 ) engages on a lever ( 43 ) on which the two plungers ( 33, 42 ) are hinged at different distances from the pivot point ( 44 ) of the lever ( 43 ) . 7. The device according to claim 6, characterized in that the distance between the articulation points ( 56, 56 a) of the plunger ( 33, 42 ) on the lever ( 43 ) is variable. 8. Device according to one of the preceding claims for the case that the storage containers are barrels, characterized in that two barrel pumps ( 3, 4 ) are additionally provided, which the first and the second substance on their barrel ( 1, 2 ) in the Feed the cylinders ( 31, 39 ) of the first and second plunger pumps ( 32, 40 ). 9. The device according to claim 8, characterized in that the barrel pumps ( 3, 4 ) are pneumatically actuated piston pumps. 10. Apparatus according to claim 8 or 9, characterized in that an intermediate store ( 23 ) is provided at least in the conveying path between one of the barrel pumps ( 3 ) and the associated plunger pump ( 32 ). 11. The device according to claim 10, characterized in that the interior of the intermediate store ( 23 ) can be acted upon with a constant admission pressure. 12. The apparatus of claim 10 or 11, characterized in that in the buffer ( 23 ) from the inside with compressed air bellows ( 24 ) is provided. 13. The apparatus according to claim 10, characterized in that the plunger pumps ( 32, 40 ) have different delivery capacities and the buffer ( 23 ) of the plunger pump ( 32 ) is associated with the larger delivery rate.