DE1800142A1 - Pulsation-free dosing piston pump with two or more pump rooms connected in parallel for incompressible media, especially liquids - Google Patents

Description

Pulsation-free dosing piston pump with two or more in parallel connected pump rooms for incompressible media, especially liquids.

When solving some technical tasks, especially in chemical engineering, if you need a dosage of liquids under pressure with a dosage per Unit of time that is constant within extremely narrow limits, even so, that the fluctuations as far as possible below the uncertainty of the usual Measurement method. In order to achieve high pressures, it is most important to Piston pumps to be used, but even with a lot of cylindrical pumps and use of pressure-equalizing devices such as air tanks, weight-loaded or spring-loaded Pressure accumulators and the like allow periodic fluctuations in performance Do not always avoid (pulsations) to a sufficient extent. You also have to Use of e.g. B. Wind kettles often tender for a long time to the azymptotic To achieve equilibrium in the system. The invention relates to a pulsation-free metering piston pump with two or more pump chambers connected in parallel, thereby avoiding these evils. The pump can also be used as a work machine to achieve constant working speed with the help of an incompressible medium, the under constant pressure can be used.

The pump according to the invention is characterized in that their pistons are controlled in such a way that there is at least one piston at a time more than one is in the driving phase, and in such a way that the sum the piston, which is simultaneously in the driving phase, has a constant value, which is also equal to the speed of one piston at a time1 that is at one would like to be in the driving phase alone at a given point in time.

This achieves the intended purpose.

For a more detailed explanation, one could consider a tandem pump, in which two identical pump housings are attached so that one and the same Comb disk is in engagement with the two pistons at the same time, namely in 180 ° chamfered points.

ifr denotes the radius vector on the comb slide, and; the Argument, the speed for each pump piston is ##, and the dosing speed be p @ portional hereby.

dr The value of the differential quotient is in d # in this case in a Quadrant, which we can call Quadrant I, constant equal to a positive one Size a.

The curve is therefore an Archimedean spiral in this quadrant. In the next following quadrant II has the said differential quotient in his first point where the argument dr # / 2 is the value a, but the differential quotient d # decreases evenly so that it has the value O dr for the argument #. The value of the differential quotient for the argument d # O + # is according to the invention as a function of the a-values in quadrant IV, in such a way.

that is. This means that the sum of the values of the differential quotients in two corresponding points, ie in points on the same radius vector, should be constantly equal to a in quadrants II and IV. In quadrant IV, the value of the differential quotient will therefore be equal to 0 for argument 3 # / 2, but will grow evenly so that it is equal to a for argument 2 #. Finally, as far as Quadrant III is concerned, this represents a suction stroke. The value of the above-mentioned dr differential quotient begins and ends d # at 0 and has a negative value s in the points corresponding to arguments between # and 3 Xt / 2, which varies in a uniform manner.

In principle, that of the differential quotient can be in each of the points in quadrants II and tV vary freely if they only use the above have mutual dependency. In practice, of course, nazi would like this to be the most even possible variation, see e.g. so that dr is the differential quotient proportional to # - # / 2 in d # quadrant II falls and proportionally with # Q - 3 # / 2 in quadrant IV increases. In quadrant III, the curve can advantageously be used as an ellipse with the power be made equal to or greater than 2.

In summary it is seen that there are ii quadrants I only one piston there who delivers liquid while the opposite piston with its valves connected to the liquid reservoir and liquid from it sucks. The total fluid output is thus when the comb disc is moved at a constant speed, constantly proportional to a. If against it the two pistons in engagement with points in and second and fourth quadrants of the Both pumping chambers emit fluid, and thus the entire fluid If the amount of liquid remains equal to a, the curve gradients must follow one another be adjusted as stated above.

It goes without saying that the principles outlined above apply Piston pumps in which the cylinders are not mounted in tandem, use analogous be able to find where the cylinders are attached, e.g. parallel or in a star shape, and where e.g. each piston is moved by its comb disc. The control of the stamp movement can take place in other ways than with comb disks without affecting the «efficacy so this is changed.

According to one embodiment of the invention, the Piston controlled so that the piston speed for each piston in its drive phase gradually in the direction towards and gradually in the direction from the dead centers of the piston movement increases, or decreases. With such a gradual increase or decrease, the Fluid velocity through the valves of the pump chamber in question at the point in time of valve closing and valve opening must be equal to 0. Cutting off the flow of liquid can therefore be carried out particularly precisely without reducing the amount of liquid dispensed in any Way is influenced and without affecting the valve movement Causes shocks or pulsations. If the valves are spring-loaded or weight-loaded they fall gradually into bearings on their seats, and when they are forcibly controlled the valve movement can be slow in step with the decreasing fluid velocity through the relevant valve gap.

According to one embodiment of the invention, incidentally with the above chosen as an illustrative example, the pistons are from one or driven several rotating, serving as driving organs comb disks.

and have an edge curve shape that gives each piston a speed granted that satisfies the claims listed above. This makes a simple one and accurate construction achieved. It is noted that the edge curve shape in this Embodiment in practice can not be as stated above. The above namely only applies in cases of a point of each of the piston rods of the listed Curve follows, but there is the angle between the curve tangent and the radius vector for this curve fluctuates periodically, this could only be the case if the Piston rods are in engagement with the comb disks by means of a sharp cutting edge could. In practice there should be engagement between the cam disk and the piston rod produced using a rounded surface or a roller, whose line of contact with the comb disk is not necessarily the cylinder axis cuts. It must therefore be compensated for in a manner known per se e.g. by milling out the comb disc with a cylindrical Milling machine whose axis of rotation follows the theoretical curve and whose diameter is the same as that of the sliding surface or the roller. What here and in the claims on the shape of such comb disks has to be given with this reservation taken verden. This also includes reservations about the shape of the curve which follow from the corrections of the same, and which are then necessary if for adjusting the piston movement see e.g. angle.

arms or other organs of transmission are used, if these the changes in the radius vector in the pulley disc are not linear to the piston movement convict. Such corrections caused by the geometry of the transmission Waveforms, however, are readily made beforehand with any desired accuracy predictable.

For example, as mentioned above, the piston.

pump can be designed as a tandem pump, with use from just one comb disc. The pump can, however, also be used with several Comb disks formed verden, z. B. a ram disc per pump chamber, what at Sequential arrangement of the pump cylinders is particularly practical. At this Embodiment according to the invention, the pump has n pump chambers, where n is an integer designated equal to or greater than 2. and the suction stroke for each piston comprises one Rotation of the xamm disc or comb discs of p. 360, where p is an integer is less than or equal to n n / 2, the comb disks being the same and the points of engagement with the piston rods or the same moving transmission organs at an angle phase shifted from ### are. This achieves a simple one and robust construction, executed with the accuracy required for the purpose Due to the narrow conditions that are required according to the invention for the control the piston movement are set, one will generally be advised to the reduction of the dosing amount by means of a regulation of the rotation speed to undertake. If this is due to insufficient or coarse regulation options the drifting machine is not possible or cannot be carried out with sufficient accuracy, one can use a piston pump according to the invention, in which the engagement organs the piston rods are in engagement with an axially displaceable conical surface, whose guide curve is designed as stated above. An axial shift of the The conical surface in relation to the pump cylinder then becomes a corresponding change the stroke length.

The invention is to be explained in more detail below, specifically with Referring to the drawing, the embodiments for the pump are also included Details are shown in FIG. 1, schematically in vertical projection, of a tandem pump According to the invention, seen from the side, FIG. 2 shows on a double scale a corresponding comb disc in plan projection, but in the theoretical one Basic shape, i.e. without corrections in the curve shape with regard to the in Fig. 1 applied, built in the piston rods for engagement with the Curved path the comb disk have been made, Fig. 3 a four-cylinder in-line pump seen schematically from the side and FIG. 4 the for all cylinders have a common formation of a corresponding comb disc with the drawing Orientation lines corresponding to the four pistons.

In Fig. 1, 1 and 2 single-acting piston pumps are set up in tandem and driven by one and the same comb disc. those on one of a not shown Motor pulled shaft 4 is fastened. The shaft 4 is mounted in a bearing block. The pump cylinders 1 and 2 have valve housings 6 and 7 and inlet lines 8 and 9 including outlet lines 10 and 11. Through lines 10 and 11 one is not Common pressure line shown supplied. The piston rods 12 and 13 of the pumps are of a compression spring 14 and 15 through the mediation of the rollers 16 and 17 against the cam track of the comb disk 3 is pressed.

In Fig. 2 is a corresponding comb disc in its theoretical Basic shape shown. The quadrants are marked with the Roman numerals I-IV. In the quarter and eighth points there is a tangent and a normal on the radius vector and the value of tangent to the angle between them is calculated and listed on the drawing. This tangent is a measure for dr Man Man sees that the mentioned value in quadrant 1 is equal to 3 and constant. This is in accordance with that if the pump 1 is in engagement with the pulley is in quadrant I, the pump 2 is engaged with a point in quadrant III be. In the latter quadrant, however, the radius vector increases from the largest to to the smallest value from, vas means that pump 2 has open inlet valve while the outlet valve is closed. There is thus no other liquid contribution to the common collecting line for the outlet lines 10 and 11 delivered as the The piston delivered by the pump 1 engages the comb disk in the quadrant I stands.

dr must therefore be constant.

d # The situation is different if a point is inside.

half of quadrant II in engagement with the piston rod of the pump 1 is coming. In this case, the piston rod of the pump is namely with the comb disc stand at a point on the curved path within quadrant IV, where radius vector is growing, which is why liquid is discharged through the outlet valve 10 for the common line will. In this case dr must gradually increase with dr within quadrant II decrease from within quadrant IV.

d # This has to be done so that the sum is constant, dr and that values for the arguments # / 2 and 0 are equal to d # 0.3 and for the values # and 0 equals 0. The remaining curves within these two quadrants can vary, but should preferably vary evenly.

Fig. 3 shows schematically a series pump, the four pistons with four identical comb disks 18-21 on a shaft driven by a motor 22 4 are engaged.

The comb disks 18-21 are out of phase with the angle # / 2. the The shape of the comb disks is sloped on Fig. 4, and the orientation of the comb disks at each of the four piston positions is by matching Numbering of radius vectors I, II, III, and IV on Fig. 4 and the cylinders on Fig. 3 indicated. In the case of cylinder I, the radius vector shown is in the quadrant 1 directed vertically upward in FIG. 4, and its point of intersection with the curved path is the point of engagement of the piston rod of cylinder 1.As indicated by arrows, three of the pistons are the same.

early with outward movement and thus in connection with the Outlet pipe. The curve shape must be within the quadrant labeled 1 dr therefore in the 90 ° within both quadrants II and IV displaced points consider.

In Figs. 3 and 4, the suction extends the same as in Fig. 1 and 2 only over one quadrant. There is, however, no obstacle in Fig. 3 that it can span two quadrants if desired. and sol.

If necessary, when calculating the curve shape for the quadrant types I and IV are only taken into account in the second of these d #. Correspondingly For example, pumps with two or three or more than four pistons in a row can be used will.

It will be seen, however, that when n cylinders are used and more than 360 ° of suction strokes is determined, the cam disks cannot be equal.

Claims (3)

P a t e n t a n s p r ü c h e. 1. Pulsation-free dosing piston pump for incompressible media, which pump has two or more pump chambers connected in parallel, whose Pistons from one or more of the same drive shaft or drive shafts with idler pulleys or other control means carried at the same speed of rotation be driven, d u r c h e k e n n n z e i c h n e t that the mentioned Move control means according to a basic curve for the piston movements or that their movement is derived in a known manner from such a basic curve, the on the total number of pistons in the propulsion phase at any point in time depends, and zvar such that the sum of the curve slopes at those points the curve, which at any given point in time the position of the in driving phase Piston is determined, and only this, is constant, and that at least always a piston is in the driving phase. 2. Piston pump according to claim 1, d a d u r c h g e k e n nz e i c h n a t that the basic profile of the curve has such a shape that its slope for each piston in its driving phase gradually in the opposite direction and gradually in the direction from the dead centers of the punch movement decreases, or increases. 3. piston pump according to claim 1 or 2, in Velcher the piston of ram disks be driven, that is, that the pump n pump chambers has, where n denotes an integer equal to or greater than 2, and that the Suction stroke one turn for each piston p. 360 of the comb disc or the comb disks from n, whereby the comb disks, if there are several, are the same, and the points of engagement with the piston rods are calculated back on the basic profile are out of phase with an angle of 360 n.