RU69248U1 - DENSITOMETER - Google Patents

Abstract

The inventive utility model relates to devices, namely, automatic monitoring devices for controlling the density of a liquid product, in particular, to devices for controlling the contamination of motor oil of a car engine, which causes an increase in oil density. The technical result of the proposed densitometer is to simplify the design of the well-known, adopted as a prototype of the densitometer. This result is achieved due to the fact that in the known densitometer containing a float with a rod on which the contact is fixed, and a rheostat included in the circuit of a recording device powered by a current source, the rheostat is fixed in the housing, in particular the insulating cover, stationary the rod is closed with a rheostat constantly. Another technical result is the expansion of the arsenal of technical means for controlling the density of a liquid medium. The simplicity of design and use makes it possible to use it, in particular, in the automotive industry as a device for controlling the contamination of engine oil of a running engine. In the drawing presented is a schematic diagram of the proposed device.

Description

The inventive utility model relates to devices, namely to automatic production devices for controlling the density of a liquid product in order to achieve or maintain the required quality of a control product, in particular to float densitometers, and can find application in mechanical engineering, for example, in the automotive industry, for monitoring engine oil pollution ( resulting from an increase in its density) during vehicle operation.

Float densitometers for measuring the density of a controlled medium are widely known, the feature of which is continuous density monitoring without performing manual operations for installation, adjustment and commissioning (IP Glybin, “Automatic Density Meters”, Kiev, “Technics”, 1965 Shchepelsky Yu.L., Pevzner LA “Density as an indicator of contamination of working engine oil”, “Engine-building”, 1984, No. 7, pp. 35-37).

In particular, the known densitometer for sugar syrups contains a float floating in a controlled environment, the movement of which, associated with an increase or decrease in the density of the controlled medium, is transmitted to a recording mechanism, for example, a recorder.

However, this densitometer is complex, applicable only in stationary conditions and is not sensitive enough due to the presence of a recorder.

Closest to the claimed is a well-known densitometer with a freely floating float, developed by the Ukrainian Research Institute of Building Materials (see IP Glybin, “Automatic Density Meters”, Kiev, “Technics”, 1965, pp. 16-17), containing a housing in communication with a container for a controlled fluid, inside of which there is a float with a rod installed with the possibility of its vertical movement in the guides.

An elastic contact is fixed on the rod, which has the possibility of periodic interaction with a rheostat transmitter at various points depending on the depth of immersion of the float. In this case, the rheostat is mounted on an anchor that can be moved horizontally under the influence of an electromagnet powered by an alternating current source, the circuit of which periodically closes the impulse wheel.

With horizontal movement, together with the anchor, the rheostat interacts with the contact of the rod, moved vertically under the influence of the changing density of the controlled medium, at different points. The rheostat and rod contact periodically form a circuit of a secondary device, for example, a voltmeter, powered by a direct current source.

However, this device is complex due to the presence of many kinematic relationships. In the absence of alternating current, this device is not operational. In addition, due to the need to use alternating current in operating conditions, it is not acceptable, for example, in the automotive industry.

The technical result of the proposed utility model is to simplify the design of the known densitometer, as well as expanding the arsenal of technical tools for measuring the changing density of a controlled environment, in particular for constantly monitoring the increase in the density of motor oil of a working car associated with its pollution.

The technical result is achieved due to the fact that in the known float densitometer containing the housing, with the float placed therein with a rod on which the contact is fixed, and a rheostat forming a circuit of a recording device powered by a current source, the rheostat is fixed in the housing and the contact the rod is closed with a rheostat constantly.

This embodiment of the densitometer ensures the simplicity of the design (it does not have complex kinematic pairs), and also allows you to expand the arsenal of technical tools used to measure and control the density of liquids, in particular motor vehicle oil, associated with its pollution.

The attached drawing shows the proposed densitometer.

The densitometer comprises a housing 1, in particular with an insulating cover 2, and having openings 3 and 4 to enable communication with the reservoir for the controlled fluid 5, for example, with the oil sump of a car engine.

A float 6 with a rod 7 is placed in the housing 1. A conductive contact 8 is fixed on the rod 7. The rod 7 is movable in the insulating guide 9 and the cover 2.

Current-carrying contacts 10 11 are fixed in the cover 2 of the housing 1. Contact 10 is connected to a rheostat 12. The contacts 10 and 11 and the rheostat 12 are located so that the contact 8 of the rod 7 is constantly closed with the fixed contact 11 and the rheostat 12. Contacts 10 and 11 together with the movable contact 8 of the rod 7 and the rheostat 12 form a circuit of the device, in particular the voltmeter 13, powered by a current source 14.

The operation of the device is as follows.

In the initial state of the controlled fluid 5, in particular when pouring clean oil into the engine, the float 6 takes its initial position, for example, the lowermost position. Pin 8 of the rod 7 is pressed against pin 11 and the rheostat 12 also in the extreme position.

In this state, the device 13 gives readings corresponding to the normal value of the density of the oil, for example 0.895 kg / cubic dm, or a threshold density value of 0.920 kg / cubic dm.

When the composition of the oil changes due to its contamination with engine wear products, its density increases. The float 6 rises

moving the contact 8 of the rod 7. In this case, the contact 8, in contact with different points of the rheostat 12, includes a different resistance in the circuit of the voltmeter 13. The deviation of the arrow of the voltmeter judges the degree of contamination of the engine oil.

Claims (1)

A densitometer comprising a housing, a float with a rod located in the housing, a rheostat, as well as a contact placed on the rod, which can be connected through a rheostat to the circuit of the recording device, characterized in that the rheostat is fixed in the housing and the rod contact is constantly connected to the rheostat .