EP0013002A1 - Method and device for pumping, in particular dosing, pasty or liquid masses by means of a hose pump - Google Patents

Abstract

In the method, the hose used is more than twice as long as that portion of it which extends in a hose pump and, if required, is displaced in the pump in a predetermined longitudinal direction of the hose. In the hose pump for carrying out the method, at least one hose (6), preferably at least two parallel hoses, are arranged releasably along a wall (8) and pressure rollers (13) are provided which can be rolled along the hose (6) in the delivery direction, squashing the hose. The hose (6), which is at least twice as long as that portion (16) of it which extends in the pump, is passed without a break through the pump (1) and out at the inlet side (20) and the outlet side (18) of the pump (1) and protrudes on at least one side by at least the length of that portion (16) which extends in the pump. <IMAGE>

Description

The invention relates to a method for pumping, in particular dosing, of pasty to liquid compositions by means of a hose pump containing at least one hose, and a hose pump for carrying out the method.

When dispensing liquid to pasty masses with the aid of a hand-held device, storage containers are generally used, in which the liquid to pasty masses are under pressure. The dispensing is then carried out through a valve whose passage cross section is adjustable. With masses that react with the air or air humidity, disturbances can occur due to a premature reaction in the valve. If several components are to be used, e.g. for the production of a two-component = poly Foam, are then also required an exact dosing, which often cannot be carried out with the appropriate dosing accuracy with flowed through valves. It has therefore already been proposed to use pumps, in particular peristaltic pumps, for the precise metering of liquid or pasty masses. In hose pumps of this type, hoses are pressed against a pressure surface with the aid of pressure rollers, the chambers formed between two pressure rollers being moved in the conveying direction and always being newly formed. However, hose pumps of this type usually only have a very short service life, which is why it is necessary to replace the hoses arranged in the pump from time to time in order to avoid bursting of the hoses and thus contamination of the pump with the masses to be metered. In the case of air-sensitive masses, however, the exchange of the hoses can lead to an undesired penetration of air humidity combined with a risk of clogging.

In contrast, the invention is based on the object to provide a method of the type mentioned, in which the risk of bursting of the hose or hoses can be prevented by simple means and in particular with very sensitive liquid or pasty masses, a blockage of the pump or dosing device is avoided.

The invention is characterized in that a hose is used which is more than twice as long as its section running in the pump and in that the hose is displaced in a predetermined hose longitudinal direction in the pump as required.

Because the hose is selected to be longer than the section in the pump, in particular the section exposed to pressure, this section can always be renewed, by moving the hose lengthways. It is not necessary to open the system for this. Therefore there is no danger that moisture or other harmful substances come into contact with the masses to be pumped.

E. It is possible to run the hose continuously while operating the pump. Lich to move through the pump so that the renewal of the hose takes place automatically. In the case of a simply constructed hand-held device, however, it is preferred to hold the hose in the pump, to release it after a certain operating time and to move it at least so much that a new hose section is exposed to the pressure load from the rollers, and then to reattach it. The hose can be moved in the direction from the pump side with a higher pressure level to the pump side with a lower pressure level. In this way, on the side with a higher pressure level, there is continuously hose material that is not yet exposed to the load.

In one embodiment of the invention, it is provided to move the hose in the conveying direction and then in each case to shorten the output-side end of the hose by approximately the length by which the hose has been moved. This export form of the method according to the invention is particularly advantageous when very sensitive reactive masses are pumped or metered. In the case of such substances, a chemical reaction can easily take place in the event of interruptions in operation due to the penetration of atmospheric moisture or atmospheric acid, which can lead to the substances to be pumped becoming solid or even solidifying. By regularly cutting the hose end after an interruption in operation, any changes in the cutting of the mass in the hose are also removed, so that no faults can occur here. If two different components are mixed together before dispensing, in particular the components for the production of polyurethane foams, then with advantageously a new mixing head connected to the shortened hose ends. The mixer is advantageously designed as an inexpensive single-use mixer, so that the very difficult and unpleasant cleaning, particularly in the case of polyurethane foams, is unnecessary.

The length of the hose, which has no interruptions from the storage container to the dispensing position, is generally a multiple, preferably at least 10 times, of the hose section exposed to pressure in the pump. As a rule, the hose length is approx. 1 to 10 m, preferably approx. 3 to 5 m, which also depends, among other things, on how many interruptions in operation, e.g. by a lunch break or overnight, until the respective storage container is completely emptied. With easily pumpable liquids, the hose length can also be significantly longer, e.g. up to 15 m long. Preferably a fabric-reinforced plastic tube is used as the tube, as it is on the market for technical purposes. The fabric insert has the advantage that the chamber volume can be kept constant in the case of several substances to be dosed at the same time, which require increased dosing accuracy.

To carry out the method according to the invention, a hose pump is advantageously used, in which at least one hose, preferably at least two parallel hoses, is arranged along a wall, and pressure rollers are provided, which can be rolled along the hose while squeezing the hose in the conveying direction, and the hose is detachably held in the pump housing, the hose being at least twice as long as its section running in the pump, the hose running without interruption through the pump and being led out on the inlet and outlet sides of the pump and on at least one side by at least the length the one running in the pump Section survives. The hose is preferably held displaceably in its longitudinal direction in the pump housing, in particular can be pulled through the pump. An arrangement of the hose in a full circle is not necessary since a pinch point moving in the conveying direction already generates sufficient pumping, in particular when the hose itself is springy or the mass to be pumped is under pressure in the storage container. In one embodiment of the invention, the hose is therefore arranged in the pump on an essentially circular arc-shaped path, the radian dimension of which is 180 ^° or less.

In order to increase the service life of the hoses in the pump, an insert made of non-stretchable material is particularly advantageously provided between the pressure rollers and the hoses. This intermediate insert, which is preferably fixed only at the end opposite to the conveying direction, absorbs thrust forces exerted by the rollers, which point in the conveying direction, so that only essentially radial compressive forces are exerted on the hoses. A planet-like drive of the rollers is therefore unnecessary.

The pump is preferably equipped with an overpressure device by means of which pressure build-up is avoided in the event of a blockage or kinking of the hose at the end on the delivery side. For this purpose, the wall against which the hose is pressed during the rolling movement is advantageously pressed against a stop on the housing under spring loading. In the event of a pressure build-up at the output end, this housing wall is able to spring away from the pressure rollers, so that the pump can continue to run without the risk of excess pressure. The suspension can be provided on the input end and / or on the output side of the wall. The wall is advantageously curved approximately coaxially to the circular path of the rollers. If the wall is pressed resiliently in the direction of the rollers, however, it can have a smaller curvature, under certain circumstances even be flat. It is then still ensured that at least one moving pinch point is generated on the hose section located in the pump.

Further features of the invention will become apparent from the following description of a preferred embodiment in conjunction with the drawing and the claims.

• Fig. 1 eine schematische Darstellung einer Dosiervorrichtung für die beiden Komponenten zur Herstellung eines Zweikomponenten-Schaumes,
• Fig. 2 einen Querschnitt durch die Dosierpumpe nach Fig. 1 und
• Fig. 3 eine Draufsicht auf die Pumpe nach Fig. 1.

Show in the drawing

• 1 is a schematic representation of a metering device for the two components for producing a two-component foam,
• Fig. 2 shows a cross section through the metering pump according to Fig. 1 and
• 3 shows a top view of the pump according to FIG. 1.

In the embodiment of the invention shown in the drawing, a hose pump 1 is provided with a housing 2, to which a gear 3 is assigned. The gear 3 can be driven with a conventional hand drill. For this purpose, a pipe socket 4 is provided on the housing 2 for connecting the drilling machine. The pump 1 is used for metering and dispensing the two components for the production of polyurethane foam and is designed as an easy-to-use hand-held device.

To form pressure chambers in the pump, two hoses 5 and 6 are provided which pass through the housing 2 without interruption are passed in parallel and run in a circular arc of approximately 180 ° in the housing. The hoses 5 and 6 enter the housing 2 on one side of the pump 1 essentially radially to the pump and on the opposite side essentially in an extension of the entry direction. On both sides, the hoses are held in releasable holders 7, which are arranged on the housing, without narrowing their cross section. The outer wall of the housing 2 on the side on which the tubes 5 and 6 extend in an arcuate manner is formed by a bracket 8, the inside of the tubes 5 and 6 facing the interior of which extends essentially in an arcuate shape and is so wide that it is a contact surface for the Forms hoses in the squeezed state. The bend of the bracket is approximately 140 °. The bracket is pivotally mounted at one end, namely at the output end, about a horizontal pin 9 and at the other end 10 is pressed elastically against a stop 12 of the housing 2 by means of an adjustable spring 11.

The hoses 5 and 6 are commercially available, self-springing fabric hoses, as are customary for technical purposes. They have the same diameter and the same wall thickness. If a dosage ratio deviating from a one-to-one ratio is desired, hoses with different inner diameters but the same wall thicknesses can be used

In the housing 2, four pressure rollers 13 are mounted on a disk 14 which can be driven about a central axis at an angular distance of 90 °, but are not themselves driven. The width of the rollers essentially corresponds to the width of the bracket 8. Between the tubes 5 and 6 and the pressure rollers 13 there is a flexible strip 15 made of tensile, non-stretchable material, for example fabric-reinforced rubber or metal. The distance of the rollers 13 from the bracket 8 corresponds to the thickness of the strip 15 plus double the wall thickness of the hoses, so that the hose sections, which are located between the rollers 13 and the bracket 8, are squeezed out and do not allow a flow through the mass to be pumped. If the discharge of the material to be pumped is prevented, for example by a blockage of the hoses or a kink, the springs 10 spring up due to the pressure of the accumulated material, so that the pump continues to run without additional pressure generation. This prevents damage caused by overpressures.

The tubes 5 and 6 have a length of approximately 5 m in the illustrated embodiment of the invention. The length of the hose sections 16 and 17, which are located in the pump housing 2 and are exposed to the pressure load by the rollers 13 during pumping, is approximately 20 cm. At the outlet side 18 of the pump 1, the hoses 5 and 6 only protrude a short distance, the length of which is of the order of the length of the sections 16 and 17, and open directly into a helical mixer 19 for the polyurethane foam formation. The mixer 19 has a simple structure and is designed as a disposable item. The remaining hose length of the two hoses 5 and 6 is between the inlet side 20 of the housing 2 and two storage containers 21 and 22 for the isocyanate and the polyol component. The hose ends are connected directly to these storage containers. When the metering device is in operation, the liquid components are under a pressure which is sufficient to convey the components through the hoses 5 and 6 into the pump 1. This is supported by the fact that the hoses 5 and 6 spring open themselves, so that the pump 1 still exerts a suction effect.

Between the rollers 13, which cause moving pinch points 23 on the hose sections 16 and 17 from the inlet side 20 to the outlet side 18 while the pump 1 is running, are formed in each case Pump chambers 24 in the tubing. In Fig. 1, a chamber on the input side is just not yet closed, whereas the second chamber on the output side has already opened. The thrust forces exerted by the rollers 13 in the conveying direction are absorbed by the strip 15, which is only on the input side. is attached to the housing and the other end is freely movable on the off side. This avoids a permanent deformation of the hoses in the sense of a flow of the hose material towards the exit side. The resulting increased service life of the hoses in continuous operation is more than one working day, so that at least one interruption in operation is carried out in each case before the risk of a hose breakage may occur. Before starting the pump again, the brackets 7 are loosened and the bracket 8 is pivoted upward, so that the hoses 5 and 6 can be displaced towards the dispensing side by approximately the length of the sections 16 and 17 located in the pump a new hose section of the pressure load was removed. Since the components of the polyurethane foam react very quickly with each other and the isocyanate component is also particularly sensitive to moisture, the pieces of tubing that have become longer each time the hose is moved are cut off at the end of the mixer at the end of the mixer after each long interruption of operation and connected to a new mixer . This enables trouble-free working without unwanted blockage due to hardened components in the hose and mixer. Moisture, which may initially still be in the hoses, is flushed through to the mixer when connecting the hoses 5 and 6 to the mixer when the pump is first started up, so that undesired reactions do not occur here even after a long shutdown can. The hoses remain connected to them until the storage containers are completely emptied. When connecting new storage containers, new hoses are in turn used. This measure is less expensive and also cleaner than cleaning the hoses, which, if not done carefully enough, can quickly lead to constipation.

Claims (15)

1. A method for pumping, in particular dosing, of pasty to liquid masses by means of a hose pump containing at least one hose, characterized in that a hose is used which is more than twice as long as its section running in the pump, and the hose if necessary is displaced in a predetermined longitudinal direction of the hose in the pump. 2. The method according to claim 1, characterized in that the hose after a predetermined, preferably depending on the mechanical strength of the hose operating time is offset by at least the longitudinal section claimed by the pressure load in the pump. 3. The method according to claim 1 or 2, characterized in that the hose, in particular in the case of a material to be pumped, which chemically changes, in particular solidifies, against the conveying direction from the dispensing end of the hose when the pumping process is interrupted, is displaced in the conveying direction in the pump and the output end of the tube is cut off. 4. The method according to claim 1 or 2, characterized in that the displacement of the hose in the direction from the pump side with higher pressure to the pump side with lower pressure is carried out. 5. The method according to any one of the preceding claims, characterized in that a hose is used, the length of which is a multiple, preferably at least 10 times, of the hose section running in the pump. 6. The method according to any one of the preceding claims, characterized in that a commercially available plastic tube with a fabric insert is used as the tube. 7. peristaltic pump for performing the method according to any one of the preceding claims, in which at least one hose, preferably at least two parallel hoses, is arranged along a wall and pressure rollers are provided which can be rolled along the hose while squeezing the hose in the conveying direction, and the Hose is detachably held in the pump housing, characterized in that the hose (5, 6) is at least twice as long as its section (16, 17) running in the pump, without interruption through the pump (1) and on the inlet side (20) and the outlet side (18) of the pump (1) is led out and on at least one side by at least the length of the section (16, 17) extending in the pump survives. 8. Hose pump according to claim 7, characterized in that the hose (5, 6) in its longitudinal direction in the pump housing (2) held displaceably, preferably through the pump housing (2) can be pulled. 9. Peristaltic pump according to claim 7 or 8, characterized in that the hose (5, 6) in the pump (1) is arranged on a preferably substantially circular arc-shaped path, the radians of which are at most 180 °, preferably less than 180 °. 10. Peristaltic pump according to one of claims 7 to 9, characterized in that an intermediate layer (15) made of non-stretchable material is provided between the rollers (13), which preferably only run along in the rolling movement, and the hose (5, 6). 11. Peristaltic pump according to claim 10, characterized in that the intermediate layer (15) is only attached to the housing (2) at the end opposite to the rolling movement. 12. Peristaltic pump according to one of claims 5 to 11, characterized in that the wall (8) of the housing (2), on which the hoses (5, 6) abut when crushed, of the hoses (5, 6) designed to be removable is. 13. Peristaltic pump according to one of claims 7 to 12, characterized in that the wall (8) of the housing (2) on which the hoses (5, 6) rest resiliently against a stop (12) on the housing (2) and / or qegen the hoses (5, 6) is pressed. 14. Hose pump according to one of claims 7 to 13, characterized in that the inlet end of the hose (5, 6) is provided for direct connection to a storage container (21, 22) for the material to be pumped. 15. Peristaltic pump according to one of claims 7 to 14, characterized in that the outlet end of the hose (5, 6) is provided for direct connection to an output device, - preferably a mixing chamber (19).

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