DE313708C - - Google Patents

Description

The subject of the invention form viscosity pumps with conveyor grooves that of the Continue suction after the pressure side, as they are, for. IT. for viscosity pumps with screw grooves occurrence. Usually the grooves will be separated by ridges.

Tests on such pumps have shown that their effect is significantly increased can be if the influence of the JSTut

ίο the opposite wall on the pumped liquid is increased as possible. These There are several ways to increase it. Should the unit of the groove cross-section omitted. Amount of promotion as large as possible, the groove may be a Do not exceed a certain depth in relation to their width. Have numerous attempts show that the delivery rate remains very low if the width of the groove is less than

ao is seven times the depth. Only when exceeded this ratio, d. H. that is, one that is more than seven times as wide as it is deep Nut it is possible to determine the actual amount delivered by the pump in relation to the largest possible delivery rate far beyond the. Half to close to what is theoretically possible Boost limit. Almost full utilization is achieved when the ratio of Groove width to depth is greater than 10 to 1.

This surprising result has been confirmed by tests with pumps of this type. Extensive tests have shown that the best utilization takes place when the usable depth is between ¹ Z ₁₀ and 1 mm. Especially large is the performance of ^ram at a groove depth of from _^3/10 and V ₂ · It is indifferent to above and the following considerations, whether it is to form grooves in the stationary part or in the rotating, on the cylinder or in the sleeve

The influence of the opposite of the bottom of the groove Wall on the viscous liquid and thus the efficiency of the pump can also be on another Increase paths, namely by shaping the grooves. The tests have shown that a reduction in the groove depth significantly increases the pressure generated, while the increase in the groove depth increases the delivery rate, namely the increase in pressure by reducing the depth of the groove, it is far greater than the increase in the delivery rate by deepening the groove. By reducing the depth alone (given the width) one could you can only increase the output while reducing the flow rate - while in the arrangement according to the invention with increased power the delivery rate as well can be kept large or enlarged. It is achieved in that the The depth of the groove is chosen to be different across its cross-section. The groove can here z. B. stepped or formed in any other way. Instead of the To arrange grooves in a stepped manner, several grooves of different depths can work together; the combs that belong together Grooves of different depths do not need to have the same small gap as the main ridges. Appropriate

(xth edition, issued on December si tgaoJ

it is, with a cross-section given by the desired delivery rate, the groove in such a way train that their depth on a possible large extension remains small. It is often useful to change the width of the Grooves cross-sections =;, which has only a small depth, to be carried out larger than the one with great depth. It has been shown that * this also improves the effect of the pump

ίο can be that the groove part is smaller in depth is arranged on the side of the groove, which next to the adjacent groove next higher pressure lies.

The drawing explains the sensation as an example on a cylindrical screw viscosity pump.

The housing α (Fig. 1) has a cylindrical smooth bore in its interior, in which a likewise cylindrical body c fits well

ao circulates. In this body, screw threads C _{1 are} cut, which serve as conveying grooves for the hydraulic fluid. The individual courses are separated from one another by ridges c ₂ , which effect the seal between the adjacent grooves C _1.

According to the invention, the width b of each groove in relation to its depth t is selected so that the groove is at least seven times as wide as it is deep. This relationship also applies analogously to grooves with changing depths, in which case the mean depth must then be at least seven times as small as the width of the groove. It can be seen that the wider the groove is selected in relation to its depth, "the influence of the wall Sl _{1 of} the body α closing off the groove towards the outside must increase. This also increases the delivery rate considerably, as has been determined by experiments.

Furthermore, tests have shown that compared to the simple groove shown in FIG. 1 with a substantially rectangular cross-section, a step-shaped groove, or even better, a groove with a triangular cross-section, as illustrated, for example, FIGS. 2 and 3 on a greatly enlarged scale , the effect of the pump increases significantly. It can be seen that in the execution after. 2 a part J _{1 of} the groove width 'has a significantly smaller depth I ₁ than the abutting part J ₂ . The influence of the fixed wall ^ ₁ on the groove part with the reduced groove depth ty brings about such a considerable increase in pressure that the effect of a pump with such a stepped groove according to FIG. ι increases significantly. . For each subsection of the stepped or similarly formed groove, the groove width (B ₁ or J ₂ ) is expediently selected to be more than seven times the groove depth (J ₁ or t ₂ ) .

The groove shape with a triangular cross-section can for example be carried out in the manner of FIG. 4, in which the base of the groove also has a short cylindrical section J ₃ , to which the lateral boundary wall of the groove can optionally be rounded off. The walls of the groove can also have curved cross-section lines, as illustrated, for example, in FIG. 5. It may be useful that. that part of the cross-section of shallow depth is adjacent to the groove which carries the higher pressure. For example, it is assumed in FIG. 6 that the liquid is conveyed from right to left, that is to say that the pressure from groove c ₃ to groove c ₄ and finally c ₅ increases. It can be seen that in each groove the part J ₁ with the higher pressure lies on the side of the groove cross-section which is adjacent to the groove with the higher pressure.

So it is necessary to achieve a large flow rate at high pressure with the pump It is advisable not to give the groove a constant depth over the entire width (Fig. 1), but different depths.

The invention is in no way limited to those described in greater detail above and embodiments shown in the drawing, but also includes any kind of modification the same.

Claims (5)

Patent Claims: 1. Viscosity pump, characterized in that the ratio of the width to the depth of the conveyor grooves is at least 7 to reduce the influence of the groove opposite wall as possible. 2. Viscosity pump according to claim 1, characterized in that the groove has a triangular cross-section. 3 .. viscosity pump according to claim 1 and 2, characterized in that the conveying groove is step-shaped.
. 4. Viscosity pump according to claim 1 to 3, characterized in that; that the Steps of the groove are separated by ridges. 5. Viscosity pump according to claim 1 to 4, characterized in that in the Conveyor groove the width of the cross-section of small depth is greater than that of the large Depth. 1 sheet of drawings.