RU2326365C1 - Device for sampling particulates and particulate sample formation - Google Patents

Abstract

FIELD: instruments.

SUBSTANCE: device consists of an attachment panel, a vertical pneumatic pusher, and a transmitter. Additionally, the following components are introduced into the device: the second vertical pneumatic pusher with a sample ejector secured on its stem, a rotary reversing actuator, on the shaft of which a lever with a cuvette attached to its end is installed, a sample cuvette reception tank, and a discharge bin. Both bins are installed on the attachment panel, in its cut-through windows joined with a cut-through horizontal slot. The drop bottom of the cuvette is supported by a guide designed as a semi-ring. One end of the guide, through the window, is secured to the inclined bottom of the sample cuvette reception bin, the second end of the guide has a chamfer and is located at a distance equal to the cuvette bottom diameter from the sample discharge bin window plane. The middle part of the semi-ring is supported by a support bar.

EFFECT: decrease in integral measurement error in vertically dropping flows of granular medium.

2 dwg

Description

The present invention relates to the field of measuring equipment, namely for the preparation of samples for quality control of granular media. It can be used in chemical, mining, construction and other industries.

A device for measuring the moisture content of bulk materials by and.with. 557301, IPC G01N 27/22. The sampler of this device consists of a sampling wheel, a guide roller and a conveyor belt with nozzles for sampling bulk material. This device has significant disadvantages. Firstly, it lacks a sample former, which leads to an increase in measurement error. Secondly, this sampler has a low representativeness of sampling, as the sampling organ crosses the flow of granular medium in only one direction. This leads to an additional measurement error.

A device is known "Automatic humidity control system for potassium chloride. VNIIG and LGI named after G.V. Plekhanov, 1976". The sampling and sample-forming unit in it consists of a fastening shield, a horizontal pneumatic pusher with a slider attached to it, in which a cuvette is made for samples of granular medium, a vertical pneumatic pusher with a primary transducer, a rotary-reversing mechanism and a folding bottom of the cuvette. This device also has significant disadvantages. Firstly, when working with wet and abrasive media, prone to sticking, the lever system of the hinged bottom fails as a result of jamming of the slide. Secondly, this device also has a low representativeness of testing.

The closest technical solution to the claimed is a "Device for the selection and formation of samples of dispersed materials" according to.with. 706736, IPC G01N 1/20. It consists of a mounting shield, two horizontal pneumatic pushers, to the rods of which are attached carriages with holes for loading and unloading a sample of bulk material, a vertical pneumatic pusher. A primary transducer is fixed on the rod of the vertical pneumatic pusher, the casing of which is a pusher of the spent sample. However, this device also has a significant drawback, which lies in the low representativeness of the testing of granular media, because crosses the flow in one direction. This leads, in the final result, to an increase in the measurement error of the integral value of the controlled parameter in the flows of granular media.

The technical result of the invention is to eliminate this drawback.

The technical result is achieved by the fact that in the device for sampling and forming samples of dispersed materials, consisting of a mounting shield and a vertical pneumatic pusher with a primary transducer fixed to its rod, according to the invention, a second vertical pneumatic pusher with a sample ejector mounted on its rod and an actuator rotary reverse action, on the shaft of which a lever is fixed with a cuvette attached to its end, a cell for receiving a cell with a sample and an unloading hopper, see the fastenings on the shield in its through windows, which are connected through a horizontal slit, with the folding bottom of the cuvette resting on a guide made in the form of a half ring, one end of which is fixed through the window to the inclined bottom of the hopper for receiving the cuvette with a sample, its second end is made with a bevel and is located from the plane of the window of the sample unloading hopper at a distance equal to the diameter of the bottom of the cell, and the middle part of the half-ring rests on the supporting bar.

The advantage of the invention is the high representativeness of testing, because the cell crosses the flow of granular medium in two mutually perpendicular directions. This ultimately leads to a decrease in the measurement error of the integral value of the controlled parameter in the flows of granular media.

Figure 1 shows a device for sampling and forming samples of dispersed materials from the outside of the flow of a controlled environment. Figure 2 presents a device for sampling and forming samples of dispersed materials from the flow of a controlled environment.

A device for sampling and forming samples of dispersed materials consists of a fastening shield 1, a first vertical pneumatic pusher 2 with a primary transducer 3 fixed on its rod, a second vertical pneumatic pusher 4 with a sample ejector 5 placed on its rod, and a rotary-reverse mechanism 6 attached to it the shaft with a lever 7, at the end of which a cuvette 8 with a hinged bottom 9, a guide 10 made in the form of a half ring supporting the strap 11, a receiving hopper 12 of the cuvette 8 with a breakdown and an unloading hopper 13, s mounted on the shield fasteners in through windows, which are connected through horizontal slit 14.

A device for sampling and forming samples of dispersed materials works as follows.

In the initial state, an empty cell 8 with the bottom 9 thrown down is in the discharge hopper 13, and the rod of the pneumatic pusher 4 with the ejector 5 is in the lower position. Then the rod of the pneumatic pusher 4 with the ejector 5 is moved to the upper position. Then the mechanism of the rotary-reverse action 6 moves the lever 7 with the cell 8 to the side of the receiving hopper 12. The folding bottom 9, moving along the bevel of the guide 10, is pressed from the bottom to the cell 8. Next, the cell 8, moving along the trajectory of the semicircle, is filled with a controlled dispersed medium and enters into the receiving hopper 12 through a horizontal horizontal slit 14. Since the guide 10 enters into the receiving hopper 12 at one end, the bottom 9 of the cell 8 will be closed. Then the rod of the first vertical pneumatic pusher 2 with the primary transducer 3 is moved down. As a result of this, the sample of the controlled material is compacted to the specified density value and the controlled parameter is measured. After that, the primary transducer 3 is moved by the first vertical pneumatic pusher 2 to the upper position. At the final stage of the cuvette 8 with the bottom 9, using the lever 7 and the rotary-reverse mechanism 6 along the guide 10, it moves along the horizontal through slit 14 back to the discharge hopper 13. The sample ejector 5 is mixed with the rod of the second vertical pneumatic pusher 4 to the lower position. The bottom 9 of the cell 8 opens and the spent sample along the inclined bottom of the discharge hopper 13 is returned to the stream.

Using a device for sampling and forming samples of dispersed materials in vertically falling streams will allow monitoring of granular medium in process streams with a lower integral error. This is achieved due to the fact that the sampling element (cuvette) crosses the incident flow of the controlled medium in two mutually perpendicular directions.

Claims (1)

A device for sampling and forming samples of dispersed materials, consisting of a mounting shield, a vertical pneumatic pusher with a primary transducer fixed to its rod, characterized in that a second vertical pneumatic pusher with a sample ejector mounted on its rod, an actuator of rotary-reverse action, is additionally introduced into it on the shaft of which a lever is fixed with a cuvette attached to its end, a cell for receiving the cuvette with a sample and an unloading hopper mounted on the fastening panel in its squaw the windows that are connected through a horizontal slit, the hinged bottom of the cuvette rests on a guide made in the form of a half ring, one end of which is fixed through the window to the inclined bottom of the hopper for receiving the cuvette with a sample, its second end is made with a bevel and is located from the plane of the bunker window unloading the sample at a distance equal to the diameter of the bottom of the cell, and the middle part of the half-ring rests on the supporting bar.

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