SU609970A1 - Radiometric follow-up level gauge - Google Patents

Description

(54) RADIOMETRIC FOLLOWING LEVEL METER

The invention relates to a technique for measuring levels, in particular, devices for measuring funnel-shaped levels of bulk material.

A known level gauge comprising a radiation source and several radiation detectors associated with a recording device | 1}.

This gauge cannot measure the level of bulk material at two points.

Closest to the proposed technical entity is a level gauge containing a radiation source, two radiation detectors connected via signal recognition circuits with a mechanism controlling their movement (2).

This gauge also does not measure the funnel level of bulk materials in two peripheral zones at the same time.

The purpose of the invention is the simultaneous measurement of a funnel-shaped level of bulk material in two peripheral zones.

The goal is achieved by the fact that the level gauge is additionally equipped with a second node recognition node and a motion control mechanism, one signal recognition node being associated with the upper radiation receiver and the control mechanism

the movement of the radiation source, and the other with the lower radiation receiver and the mechanism for controlling the motion of the receivers.

The drawing shows a schematic diagram of a radiometric servo gauge.

The level gauge contains a source of 1 gamma radiation, receivers 2, 3 of radiation, nodes 4, 5 of signal recognition, mechanisms 6, 7 of motion control, and a recording device 8.

The source of gamma radiation is located so that a part of its radiation is attenuated by the grist material. Receivers, tightly coupled to each other, receive a partially attenuated radiation source. The upper receiver 2 receives a portion of the radiation in proportion to the degree of overlap of the radiation material by the embankment located near the radiation source, and the lower receiver of the radiation 3 receives a portion of the radiation due to {) the degree of overlap of the radiation by the material located near the source, 1 and near the radiation receiver 3. Outputs The receivers are connected respectively to the inputs of the nodes 4, 5 recognition of the cables, the outputs of which are connected respectively to the mechanisms 6, 7 of the movement control of the radiation source and the receivers. Mechanisms b and 7 outputs are connected to a recording device 8.

Radiation source 1 and radiation receivers 2 and 3 are fixed at zero imbalance when the radiation source 1: radiation receiver 3 is covered by half the material.

When the material level changes, for example, near the lower radiation detector 3, an unbalance signal arises at the output of the recognition unit 5, which causes receivers 2 and 3 to move until the unbalance signal is removed.

When the level of material fills changes in the vicinity of the radiation source, an unbalance signal appears at the output of the signal recognition unit 4, which causes the radiation source to move until the unbalance signal disappears.

In this way, continuous monitoring of the level of material embankment along the edges of the process tank is carried out.

The use of inventions in the operating conditions of the blast furnace will reduce the number of anchor points of the level gauge, and there is no need to cool the pipes in which the sources move, to increase the measurement accuracy, and consequently, to more efficiently control the operation of the blast furnace.

Due to the small and constant distance between the radiation source 1 and the radiation receivers, the activity of the source can be reduced.

Claims (2)

1. US Patent No. 3594575, cl. 250-43.5, 1971. 2. For the German Federal Republic Kg 1226320, cl. 42 e 34, 5 1966. hake