KR840000475B1 - Loop converyor type flow weighter - Google Patents

Abstract

A loop conveyor, which is nearly round when viewed in a plane, has a ring-shaped or loop path to carry powdered material. A material-discharge port lies opposite to a material-receiving port, a semicircle away from it, so that the material may be carried in the ring-shaped path. The loop conveyor is supported by a balance mechanism at two points on the line of the loop diameter which passes the material receiving and discharge ports.

Description

Annular Conveyor Flow Meter

The figure shows one embodiment of the annular conveyor type flow meter according to the present invention,

1 is a plan view with a part of the cover plate removed.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a cross-sectional view taken along the line B-B of FIG.

4 is a plan view showing the removal of a part of another configuration example of the transfer rotation.

5 is a cross-sectional view taken along the line C-C of FIG.

The present invention relates to a flow rate meter for measuring the flow rate and weight of the powder in the process of continuously conveying and supplying the powder, in particular using a ring conveyor having an annular conveying path for conveying the powder The present invention relates to an annular conveyor type flow meter for measuring the flow rate and weight thereof.

Except for the special powders described later, in general, the powders are not flowable, so it is very difficult to measure the weight or flow rate of the powders in a continuous conveying process. This is because it is difficult to transport the powder quantitatively in a quantitative manner, and the powder exhibits completely different properties depending on the kind of raw materials and environmental conditions.

The conventional continuous flow meter of the powder is a conveyor belt system for measuring the weight of the powder placed on the belt in the process of conveying the powder by a conveyor belt running linearly, alternatively Has a screw method for measuring the weight in the process of conveying by the screw.

In these methods, however, the powder adhered to the belt, screw, and other parts and grew, and the packing weight error became large, so that accurate values could not be obtained.

As a special powder, there is pulverized coal, for example. This pulverized coal is used in the roots as a large-scale combustor, but it is normally fluid and severely flushed. In such powders, the conventional belt conveyor method and the screw method described above are completely incapacitated, and the supplied powders flow out at once at a faster speed than the belt speed, or flow out all at once in the screw groove, making measurement impossible. .

An object of the present invention is to provide a flow meter that can accurately measure the weight and flow rate of the powder in the process of continuously transporting the powder.

Another object of the present invention is to provide a flow meter capable of measuring quantitatively and at the same time accurately measuring the weight and flow rate even in powders with a high flushing phenomenon such as pulverized coal.

It is a further object of the present invention to provide a good flow meter for the sealing of partition blades to form a compartment for conveying powder, in particular pulverized coal.

The annular conveyor flow meter of the present invention includes an annular conveyor having an annular conveying path for conveying material, a support for supporting the annular conveyor in a straight line in section 2 on its diameter line, and a right angle with the perpendicular oblique line. It consists of an electrical load detector, such as a rotcell, which supported the annular conveyor at the position where it is made, The annular conveyor is formed so that the import port of the material to be conveyed is located on the same diameter line as the support of the two sections. Each of the outlets is arranged so as to be located on the opposite side of the semi-circumferentially pushed out of the import port, and a conveying rotating body for continuously conveying the material supplied from the import port to the outlet as a material conveying means.

The weight of the powder to be continuously conveyed in the annular conveying path semicircumferentially is measured by measuring it electrically until it becomes a load on the electrical load detector, and the weight of the powder in relation to the rotational speed of the conveying rotor is measured. Measurable.

In detail, the annular conveyor is comprised from the bottom plate which has a cylindrical force on the outer periphery, the cover plate which can cover this, and the conveyance rotating body rotated horizontally in the space formed by the bottom plate and the cover. The transfer rotating body has a circumferential circumferential wall constituting a concentric circle with the cylindrical wall, and the circumferential wall and the cylindrical wall form an annular transfer path.

In the rotating body for conveying powder, the bottom plate of the material receiving plate is installed on the bottom surface of the main wall of the shaft in a stepped manner, and the material supplied from the import port is placed on the bottom plate and transported in a semicircle to discharge from the discharge port.

In the conveying rotating body for powders with high flushing phenomenon, such as pulverized coal, partition blades of equal intervals are provided by radiation from the circumferential wall of the shaft, and the partition compartments are formed by the partition blades. The partition wing is made to seal the contact part with the said cylindrical wall, the bottom plate, and a cover plate reliably. Thus, the material supplied from the inlet is stored in the compartment and is reliably conveyed to the outlet without causing flushing.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

(1) in the drawing is an annular conveyor, circular in plan view, supported by a support part 2 consisting of a horizontal shaft 3 and a bearing 4, which are installed axially from the outer end of the diameter line thereof, and are supported on a scale type. have. The annular conveyor 1 is a horizontal direction in the space formed between the bottom plate 5 in which the cylindrical wall 6 was formed in the outer periphery, the cover plate 7 to cover this, and the bottom plate 5 and the cover plate 7. It consists of the conveyance rotating body 8 driven by rotation.

The side portion 9 of the rotating body 8 has an outer circumferential wall 9a concentric with the cylindrical wall 6, and annular conveyance for material transfer between the outer circumferential wall 9a and the cylindrical wall 6. The furnace 1a is formed.

The optimum rotating body for conveying powders with a high flushing phenomenon such as pulverized coal is shown in FIGS. 1 to 3. The rotating body 8 shown here has the partition blades 10 equidistantly spaced radially from the said outer peripheral wall 9a, and the partition chamber 14 is formed by each partition blade 10. As shown in FIG. In the partition wing 10, the wing plate 11 and the press plate 12 fixed to the outer circumferential wall 9a clamp the felt sheet 13, and the felt sheet 13 is winged. Exit from the outer edge of the plate (11). In this way, the partitioning wing 10 is sealed by the contact part with the said cylindrical wall 6, the bottom plate 5, and the cover plate 7, and it does not spill even if it is a highly fluid powder.

The long-term experiment was repeated about the sealing material of the said partition wing | blade with various materials including hardening agents, such as stainless steel.

Although it cannot be determined with the naked eye, the pulverized coal particles have sharp edges. Therefore, pulverized coal acts as a good abrasive and wears the sealing material or the wall surface, and many of the tested sealants have failed. Was found to be optimal.

The material import port 15 of the annular conveyor 1 is positioned at the cover plate 7 at the same diameter line position as the horizontal axes 3 and 3, and the material discharge port 16 is 180 degrees from the import port 15. In the position where the phase was pushed out, it is provided in the bottom plate 5, respectively, and the flexible connection part is connected to the import pipe 17 and the discharge pipe 18, respectively. The import pipe 17 is connected to the outlet of the automatic quantitative feeder for powders invented separately, and the powders are quantitatively supplied through the import pipes 17.

The annular conveyor 1 configured as described above is supported by an electrical load detector, for example a load cell 19, at a position perpendicular to the diameter line of the horizontal axis 3, 3. The load cell 19 may be either a tension type or a pressure type depending on the support position thereof, and is proportional to the total weight of the material lying in the semi-circular transfer path from the inlet port 15 to the outlet port 16. One value is to be detected electrically. In the figure, 20 is a driving motor, which rotates the rotating body 8 through the transmission means such as the belt 21, the reduction gear 22, these are the lower part of the annular conveyor 1, the above It is attached so as to be approximately symmetrical about the axis of the horizontal axis (3,3). All of these are package weights, and an external moment does not act on a load cell. In the examples of FIGS. 4 and 5 to be described later, a reduction motor is used as the driving motor, and the rotating body 8 is directly decelerated and rotated by the motor shaft. In the figure, TG denotes a taco generator, and 23 denotes a multiplier.

If there is an unbalance of weight in the above-mentioned annular conveyor, a balancer is added to maintain mechanical balance, and the load cell is slightly loaded. The signal due to this load is set to zero. In this way, the weight of the material can be measured easily and accurately, and the flow rate can be measured by the product of the weight measured by the load cell and the rotation speed of the rotor 8, that is, the flow rate = weight x rotation speed. There is a number.

In the case of ordinary powder, the structure of the rotating body 8 can be made into the simple structure as shown in FIG. 4 and FIG.

4 and 5, the rotor 8 has no partition wings, and a bottom plate 24 corresponding to the annular feed path 1a extends at the lower end of the outer circumferential wall 9a. . The discharge port 16 is provided on the cylindrical wall 6 side, and the discharge gate 25 extends obliquely at the end of the discharge port 16, and the tip thereof is in contact with the outer circumferential wall 9a. Therefore, the material supplied from the import port 15 is placed and transported evenly on the bottom plate 24, and is discharged to the discharge port 16 while being guided by the discharge gate 25. Other configurations are substantially the same as those shown in FIGS. 1 to 3, but a deceleration motor 26 is used as the drive motor.

In addition, in FIG. 1 through FIG. 5, the drawing 27 shows the sealing material between the rotating body 8, the bottom plate 5, and the cover plate 7. As shown in FIG.

According to the annular conveyor flow meter of the present invention, the powder material supplied from the import port is semicircularly conveyed in the annular conveying path and discharged from the discharge port. At this time, since the annular conveyor is supported at two points on the straight line and is a scale mechanism, the weight of the material lying on the semi-circumferential portion of the conveying path is accurately detected electrically by the load cell.

When the material to be conveyed is a powder which has a high fluidity such as pulverized coal and a significant cause of flushing phenomenon, it is stored in the compartment of the rotating body formed in the rotating body and is conveyed accurately so that there is no fear of spilling out.

In addition, even if the material is attached to the partition blades or other rotating bodies, the annular conveyor is supported at two points on the diameter line, and equilibrium is equally balanced between the right and left sides of the point, so that no packaging weight error occurs.

In addition, since the inlet and outlet of the material are arranged on the diameter line passing through two points, they are not affected by the pressure of the material dropping.

Claims (1)

An annular conveyor (1) having an annular conveying path (1a) for conveying material, and a support (2) for supporting the annular conveyor on a scale at two points on its diameter line, and at a position perpendicular to the diameter line In a flow measuring device comprising an electrical load detector 19 such as a rod cell supporting a toroidal conveyor, the toroidal conveyor is provided such that the inlet port 15 of the material to be conveyed is located on the same diameter line as the two points of support. The outlets 16 of the material are arranged so as to be located on the opposite side away from the inlet by half a circumference, and provided with a rotating body 8 for continuously conveying the material supplied from the inlet to the outlet as a means of conveying the material, Annular conveyor type oil, characterized in that configured to electrically detect the weight of the material placed in the semi-circumferential portion of the annular transfer path with an electrical load detector Meter.

Images