DE949156C - Viscosity meter for streaming media - Google Patents

Description

Viscosity meters for flowing media There are viscosity meters for flowing media known, which consist of a conical tube anise, in each of which a swimmer independent of tenacity and one influenced by tenacity Floats are arranged one above the other. The flow rate is then controlled by a volume regulator kept constant so that the tenacity-independent swimmer maintains his position, so shows the swimmer influenced by the toughness through his respective altitude toughness on a scale. Those with electrical or pneumatic assistants actuated regulators can be controlled by the lower float.

One already has one in a conical one for measuring the toughness Measuring tube located against toughness sensitive swimmers angel turns, whereby the pressure difference on the measuring tube by means of a viscosity-insensitive through Auxiliary power (auxiliary pump) operated controller was kept constant.

These devices are also required by auxiliary workers operated motor controller expensive and regulate only by shuttling back and forth around the Solipoint.

The present invention relates to tenometers that also work with one independent of the toughness and one influenced by the toughness Swimmers work, but with one of the two swimmers according to the invention a throttle device is connected and by virtue of the lively Force of the flow without the use of an auxiliary force regulates the flow, so that the other swimmers showing the toughness directly.

When the swimmer, insensitive to tenacity, the throttle operated, the flow rate is kept constant by him, and that of the Swimmers affected by tenacity show the degree of tenacity on a scale. If, on the other hand, the swimmer, which is influenced by the toughness, operates the control throttle, so the regulated amount is different depending on the toughness present in each case, and the display of these various quantities by the insensitive to toughness Swimmer is then a measure of toughness. In the former case, the device exists from one in the lower cylindrical and in the upper part konisehen measuring tube, in which the lower cylindrical part is the resilient float, which is connected to a throttle located below it so that when it is lifted the throttle operated. Since he works in the cylindrical pipe part, he speaks in all of them its altitude only to the amount corresponding to its weight and rises until the target quantity is set by the throttle that moves with it. Since the swimmer only lets through one and the same amount at any altitude, it acts as an exact regulator without oscillation only by virtue of the living force of Flow without the use of auxiliary staff. The upper part of the measuring tube is conical and contains a swimmer that is highly responsive to toughness.

In the second case the arrangement is the same, but then & er on the toughness dependent float below and connected to the throttle while the swimmer, which is independent of the tenacity, which is influenced by the fluctuations in the tenacity changing flow rates as a measure of the viscosity. The conical pipe part is advantageously transparent to make the position of the upper float visible do.

The displays of the upper swimmers can also be used in a known manner transferred to writing and counting devices by magnetic or inductive coupling as well as for remote transmission.

In Fig. I an embodiment of a device is shown, in which the float, which is insensitive to toughness, is coupled to the throttle. In the cylindrical tube part a there is a thin, sharp-edged one Plate existing swimmer b, which is known by its shape of the toughness is not affected.

It is equipped with a throttle valve located in the lower pipe part c d connected in such a way that when it is lifted by the current, the flap is more or less less closes until the constant flow rate corresponding to its weight is reached Above the cylindrical tube part closes a transparent conical Tube e in which a swimmer J, who is strongly influenced by the toughness, is located. The SclvimmerJ f shows on a scale the toughness present in each case.

If the floats b and f are exchanged, the float shows b in the upper conical tube the change in flow and thus the respective viscosity at.

Fig. 2 shows a device in which the affected by the toughness Float f is designed as a hollow float so that it has buoyancy, and the current is from the bottom down. The back up through a bend directed flow then flows through the conical tube e with the one located therein swimmers insensitive to toughness b, who on the basis of the variable flow rates indicates the size of the toughness on the scale. This latter arrangement has the advantage a significantly shorter overall length of the device.

Claims (3)

P A T E N T A N S P R Ü C H E: I. Viscosity meter for flowing Media in which one is sensitive to viscosity and one is in a measuring tube The toughness of unresponsive swimmers are arranged one above the other and the toughness-independent swimmers The float is kept at a constant flow rate by a regulator, thereby characterized in that the viscous float is in a cylindrical Pipe part works and is thus connected to a throttle valve located below is that he, lifted by the current, placed the throttle upon him according to his weight incoming, always the same flow rate sets while the pipe extension is conical and carries a float influenced by the toughness, which is adjusts to different levels depending on the size of the toughness. 2. Zähieitsmessler according to claim I, characterized in that the float influenced by the toughness is connected to the throttle and, the jew, according to urgent viscosity, different flow rates set by the swimmer, which works in the conical tube part and is insensitive to toughness are displayed and are a measure of the toughness. 3. Toughness meter according to claim 2, characterized in that the float, which is influenced by its toughness, is designed as a hollow body with buoyancy is and works in a downward current. Publications considered: Journal »Chtemile-Ing.-Tech. nik ", 1952, p. 665; German patent specification No. 870 193.