DE2312647A1 - Measuring pump for synthetic resin components - capable of continuously varying proportions of components over wide limits - Google Patents

Abstract

Measuring pump has feed cylinders each of which is connected to two inlet and two outelt check valves connected to the feed and discharge lines for the measured components, and double action feed pistons whose rods are adjustably coupled together. Viscosity differences in the components can be equalised and the appts. is reliable using the minimum of moving parts.

Description

Dosing pump, especially for dosing several plastic components The present invention relates to a metering pump, in particular for metering several plastic components. The object of the invention is to provide a metering pump to create that is simple and reliable and has a minimum of moving parts having. The ratio of the components to be dosed should be very wide within Boundaries can be changed continuously and the arrangement can be made in such a way that that the organs that convey the components, e.g. pistons, must, but still are adjustable coupled with each other. Due to the inevitable coupling you can among other things, differences in viscosity in the components are compensated.

According to the invention, this object is achieved in such a way that the coaxially arranged side by side delivery pistons as double-acting pistons are designed and their cylinders with two inlet and two outlet check valves are in connection with the inlets and outlets of the components to be dosed are connected, and that the piston rods of the delivery pistons are positive and adjustable coupled together are.

In the drawing, one is an example embodiment of the inventive Dosing pump shown schematically in a longitudinal section.

The metering pump shown has two double-acting delivery pistons 1, 2, which are movable to and fro in cylinders 3 and 4, respectively. The drive of this Delivery pistons 1, 2 are effected by drive pistons seated on their piston rods 5, 6 7, 8, which are reciprocable in cylinders 9, 10 and-by compressed air or Oil pressure can be actuated in a manner yet to be described. As from the drawing can be seen, are also on the side facing away from the piston rods 5, 6 the piston 1, 2 piston rods 11, 12, which have the function of control rods, The piston rods 5, 6 and 11, 12 are in the walls 13 of the pump housing 14, as well guided in the walls 16 of the control housing 15. The piston rods 5, 6 are thereby forcibly coupled together that one provided with a longitudinal slot 17 Latch 18 overlaps two pins 19, 20 that are firmly seated on the rods 5, 6. the Bracket 18, for its part, can be pivoted about a bolt 21 which penetrates its slot 17 and is fixedly arranged on an adjusting lever 22. In a central threaded longitudinal bore 23 of the lever 22 enters a threaded spindle 24, which is fixed to the setting wheel 25 connected is. The latter can be rotated by hand or by a servomotor, however Axially immovable in the housing part 26. By turning the handwheel you can the bolt 21 can be adjusted in the height direction. It is in the drawing in the middle between the two piston rods 5, 6, so that the transmission ratio 1: 1. Erl can, however, also be adjusted so that it reaches the height of the upper piston rod 5 or that of the lower piston rod 6 can be so that the ratio of the piston travel within very wide limits adjustable is. Aligned with the ends of the piston rods 5, 6 and 11, 12 are on the housings 14, 15 known pneumatic or electric limit switches 27, 26 and 29, 30 brought up.

In the cylinder 9, 10 channels 31, 32 and 33, 34 lead for a hydraulic or pneumatic pressure medium, e.g.

Compressed air. In the cylinders 3, 4 channels 35, 36 and

37, 38 for the components A and B to be conveyed. Component A arrives via a line 39 into the pump. This line is divided into two branches 39 'and 39all, which lead to spring-loaded check valves 40,41. These latter are connected to channels 35, 36. Also connected to the lastsren are oppositely acting check valves 42, 43, which are in an outlet line 44 for component A. The arrangement of the lines and the check valves, which cooperate with the piston 2 is the same. The entry line 45 for the Component 8 leads via branch lines 45 'and 45 "to the spring-loaded check valves 46, 47 which open into the channels 37, 38. These latter are about opposite acting check valve 48, 49 with the outlet line 50 for the component 8 in connection.

The metering pump described works as follows: The drawing shows the pump is in an end position at rest. During commissioning, a print medium is used (Air or Qel] through the channels 31 and 34 on the drive piston 7, 6 to act brought. Dieselbsn, and thus the piston rods 5, 6 thereby move in relation to one another opposite direction from the shown in the opposite end position. Since the delivery pistons 1, 2 are inevitably moved along with them, they suck through the channels 39 and 45 and via the inlet valves 40, 46 medium of the components A. or B.

These components reach the top via channels 35 and 48, respectively Cylinder 3 or 4, at the same time one of the incoming lot corresponding amount of components A and 8 through the pistons 1, 2 via the channels 36, 37 and the outlet valves 43, 48 conveyed into the outlet lines 44 and 50, respectively. If the piston rods 5, 11 and 6, 12 reach the end position of this movement, then the limit switches 27, 30 are actuated.

The same effect via an impulse valve (not shown) that the pressure medium instead of via the channels 31, 34 via the channels 32 and 34 into the cylinders 9, 10 is introduced. As a result, the pistons 7, 8 return to the starting position shown back, at the same time the components A and B via the inlet valves 41 and 47 are sucked in or ejected via the outlet valves 42, 49.

The dosing ratio can be adjusted by adjusting the setting wheel 25 change within wide boundaries. It is also possible to use the cylinder cross-sections 3, 4 instead of dimensioning the same size as in the example shown, different sizes.

The design of the device described brings about compared to known Devices a significant simplification. By eliminating complex valve drives the construction becomes cheaper and less prone to failure. Another advantage lies in the fact that special precautions for the exact synchronization of the switching torques, which were previously required for controlled valves are no longer required. As a result there is also a risk of pulsations due to poor switching regulation avoided from the outset.

The dosing pump described can be used for all liquid two-component substances, Synthetic resins, adhesives, etc. can be used. If more than two components are to be dosed, so it is possible to arrange several of the devices described in series.

When dosing plastic components, there is often one component in terms of quantity, much less than the other component. The corresponding delivery piston and the associated Cylinders are then given a significantly lower rate Quartz section as the cylinder and piston of the other component. The lesser ones for the piston Cross-sectional driving force required can then be so small that no special Drive piston is necessary, but the drive from the other piston via the bracket 18 can be achieved. A regulation of the transmission ratio by the setting wheel is also possible within certain limits. With this arrangement, the Drive piston for the delivery piston conveying the smaller component in terms of quantity.

The described and illustrated embodiment shows spring-loaded Check valves. However, the latter can also be provided without spring loading be. Finally, it is also possible to use the check valves instead of springs to be loaded by pneumatically or hydraulically controlled pistons.

The delivery pistons can, instead of being pneumatic or hydraulic Medium can also be driven by one or more electric motors. Then is it is possible to move the delivery pistons through the pressure of the material to be delivered. In this case, means for locking individual valves must then be provided. In this embodiment, if component A passes through valve 40, for example on, the outlet valve 43 must be open and the valves 41, 42 must be locked. When the delivery piston has reached its other end position (on the right in the drawing), thus, valve 40 is locked in the closed position. Valve 43 is also locked, while the valves 41, 42 are open.

Claims (7)

Patent claims: Dosing pump, especially for dosing several plastic components with a plurality of delivery cylinders and pistons for the individual components, characterized in that the coaxially arranged side by side delivery pistons (1, 2) are designed as double-acting pistons and their cylinders (3, 4) with two inlet and two outlet check valves (40-43, 46-49) are connected, those with the supply and discharge lines 39, 45 and 44, 50) of the component to be dosed (A, 8) are connected, and that the piston rods (5, 6) of the delivery piston (1, 2) are inevitably and adjustable coupled to one another. 2. Dosing pump according to claim 1, characterized in that the Delivery piston (1, 2) at least partially connected to a drive piston (7, 8) are. 3, metering pump according to claim 2, characterized in that the mutually associated delivery and drive pistons (1, 7 or 2, 8) on a continuous Kelbenstange (5, 11 or 6, 12) are arranged. 4. Dosing pump according to claims 2 and 3, characterized in that that in the extension of the piston rod (5, 11 or 6, 12) known limit switches (27-30) are arranged. 5. Dosing pump according to claim 1, characterized in that for inevitable and adjustable coupling of the piston rods (5, 6) one by one adjustable bearing pin (21) pivotable bracket (18) is provided, the bearing points (19, 20) overlaps the piston rod (5, 6). 6. Dosing pump according to claim 1, characterized in that the spring-loaded Check valves are provided. 7. Dosing pump according to claim 1, characterized in that unloaded Check valves are provided. L e r s e i t e