JPS60183028A - Weighing and compounding apparatus - Google Patents

Abstract

PURPOSE:To facilitate the charging of a stock material, by mounting a drive apparatus for revolving stock material storage tanks around the center position of the ring-shaped arrangement thereof and fixedly providing hopper weighing machines. CONSTITUTION:Particulate stock materials are charged into stock material storage tanks 4 from charging ports 22 and each charging amount is stored in a control apparatus on the basis of the signal from a level control platform scale 23. Thereafter, when the kinds and amounts of the stock materials to be compounded are inputted to the control apparatus, a drive apparatus 6 is operated by the control apparatus and the stock materials in the stock material storage tanks 14 are charged in the hopper parts 18 of hopper weighing machines 17. The charged amount is weighed by the weighing part 19 of each hopper weighing machine 17 and the signal thereof is inputted to the control apparatus and, at the point of time when the charged amount reaches an indicated one, the control apparatus stops the operation of a quantitative supply apparatus 16.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a measuring and blending device for storing a wide variety of raw materials separately in storage tanks and taking out desired amounts of some desired raw materials.・It is something to do.

Conventionally, as the above-mentioned weighing and blending device, the first raw material storage tank cI℃ is divided into a plurality of hoppers, a ho river weighing machine (2) is provided for each block, and these hopper weighing machines are installed. Raw materials discharged from heavy machinery 6) are transferred to a belt conveyor (
There was one that was transported to a predetermined position by (to). However, in such conventional equipment, a ho soba weighing machine (
2) was large in size, and there was also the problem that the amount of raw material finally obtained was inaccurate due to scattering and adhesion on Peltco's Y-veyor.

On the other hand, as shown in Figure 2, there was a system in which a large number of raw material storage tanks (B) were installed in a straight line, and a ho-river weighing machine (B) was mounted on a reciprocating cart (B). , In such conventional equipment, the Ho-River weighing machine (
), there was a problem with low measurement accuracy.

In addition, each of the above-mentioned conventional devices requires a long installation space because the raw material storage tank 6I) (to) is arranged in a straight line.
There was also the problem that it was troublesome to add raw materials to the raw material storage tanks (b) and (b).

The present invention solves the above-mentioned conventional drawbacks, and provides a measuring and blending device that has high measuring accuracy, can be installed in a compact space, and can easily charge raw materials, etc. to a raw material storage tank. The purpose is to

In order to achieve the above object, the measuring and blending device of the present invention includes a plurality of raw material storage tanks arranged in an annular manner, a drive device for rotating these raw material storage tanks around the center position of the annular arrangement, and each of the above-mentioned raw material storage tanks. A quantitative feeding device installed in a raw material storage tank and discharging the raw material inside the tank to the outside, and a hopper weighing device fixedly installed at a predetermined location to receive and weigh the raw material discharged from the quantitative feeding device. It is a configuration with.

According to this configuration, the weighing machine is permanently installed, and there is no need to convey the raw material after weighing using a belt, etc., so that the weighing accuracy is high. Furthermore, since the raw material storage tanks are arranged in a ring, the installation space can be reduced, and since these raw material storage tanks are rotated, raw materials can be input at one location, making the raw material input work easy.

An embodiment of the F1 invention will be described below based on the drawings.

3 and 4 are a plan view and a front view of a metering and blending device in one embodiment of the present invention. In this embodiment, two raw material measuring and blending devices are arranged, and since both have the same configuration, the right measuring and blending device is not shown in FIG.

In Figures 3 and 4, (1) is the machine frame, (2) is the frame, (3) is an annular rail installed on the frame (2), and (4) is a plurality of annularly arranged rails. These are raw material storage tanks, and a wheel (5) is attached to the bottom surface of each raw material storage tank (4) so as to be rotatable around a horizontal axis.
5) is placed on the rail (3). (6) is a drive device that rotates the raw material storage tank (4) along the rail (3). ) connected to the reducer (8)
, a gear (9) externally fixed to the output shaft 1 of this reducer (8), a rotating body α force to which a gear αO meshing with this gear (9) is externally fixed, and this rotating body α9 and a link mechanism α that connects each of the raw material storage tanks (4).

The rotating body α0 includes a wheel α rotatable around a horizontal axis.
9 are installed at appropriate intervals in the circumferential direction, and the rotating body (
] J) The weight of " is the said frame (2) through the wheel 03
is supported by Further, the center of rotation of this rotating body aη coincides with the center of the rail (3), and the center of rotation of the rotating body aη coincides with the center of the rail (3).
) is the rotational force of the reduction gear 1a (8) and the gear (9) (If
), the rotary body 0υ, and the lifting mechanism @ to the raw material storage tanks (4), thereby causing the raw material storage tanks (4) to travel on the rails (3). Each of the raw material storage tanks (4
) At the lower end of the screw feeder a
A quantitative feeding device (11) consisting of υ is installed, and this quantitative feeding device @OQ discharges the raw material from the raw material storage tank (4). This is a ho-river weighing machine consisting of a floating valve (not shown) installed at the lower end of the ho-riba part (end).This hopper scale weight a'i'r is It weighs the raw material supplied by the quantitative feeding device (1119), and is fixed at a predetermined position, and has a bellows body (to) connected to the discharge port of the quantitative feeding device θG at its upper end. The lower end is fitted inside the Ho River e◇.

The lower end of the soba 0υ is connected to, for example, a mixer (not shown). (2) is the raw material storage tank (4)
This is an input port for inputting raw materials into the tank, and is installed at a predetermined position. A level control platform scale (2) is installed below the input port (A) to measure the weight of the raw material storage tank (4) to determine the amount of raw material stored therein. That is, the part of the rail (3) located above the platform scale for controlling the small level of +tiJ is independent, and the raw material storage tank (4) located in this part and the weight of the raw materials inside thereof are independent of each other. c). The amount of raw material known from the weighing result of this level control platform scale (c), together with the amount of raw material that can be stored in the raw material storage tank (4),
Since the information is displayed on a display (not shown) installed at a predetermined location, it is possible to prevent raw materials from exceeding the capacity limit when being charged. In addition, the f-ta (7) of the drive device (6), the f-ta (7) of the quantitative supply device a0, and the f-ta
River weighing machine α power on/off valve, Ho Soba weighing machine αη
Weighing part α9. The level management scale and the display are connected to a control device (not shown), and various signals are exchanged with the control device. Also, which of the raw material storage tanks (4) is located at the raw material input position or the raw material discharge position is determined by each raw material storage tank (4).
A unique code bar etc. is set aside, and this code bar is read by a reading device, and the direction of rotation of the raw material storage tank (4) by the drive device (6) and its rotation angle are calculated cumulatively. Various methods can be adopted, such as a method for storing the information in a stored manner.

I will briefly explain the operation. First, raw material consisting of powder and granules is charged into the raw material storage tank (4) through the input port (a). This input amount is stored in the control device by a signal from the level management platform scale (c). The above operations are sequentially performed for each raw material storage tank (4) while rotating the raw material storage tank (4) by the drive device (6). Thereafter, when the desired types of raw materials to be blended and their amounts are input to the control device, the drive device (6) is operated by the control device, and the raw material storage t! +4) reaches the discharge position ■. Then, the quantitative supply device θ0 is operated, and the raw material in the raw material storage tank Q41 is charged into a part (to) of the hopper of the Ho-River weighing machine Uη. This input amount is measured by the weighing unit 0 sound of the Ho-River weighing aO''I), and the signal is input to the control device, and when the specified input amount is reached, the control device This input amount and the amount obtained by subtracting the input amount from the amount stored in the raw material storage tank (4), that is, the current storage amount, are stored in the control device.This operation After the process has been carried out in sequence for the number of designated raw material types, the on-off valve of the hopper weighing gun is opened, and all the designated raw materials are supplied to the mixer etc. via the ho-soba-■υ. From then on, the same operation is repeated every time the type and amount of raw materials to be blended are specified, and the minimum storage limit is the amount obtained by subtracting the KL to be supplied from the amount of raw materials stored in the raw material storage tank (4). If it becomes smaller than , the control device issues an alarm and the supply is not performed.In this case, the raw material is put into the raw material storage tank (4).

In this way, the hopper weighing machine qη is permanently installed, and there is no need to transport the weighed raw material using a conveyor or the like, so the weighing accuracy is high. In addition, since the raw material storage tanks (4) are arranged in a ring, the installation space can be reduced, and since these raw material storage tanks (4) can be rotated around the center position of the ring, the raw material can be collected in one place. It is possible to perform discharging and loading, only one weighing machine is required, and the work of loading raw materials can be easily performed. In addition, as in this embodiment, the rotating body <11) and the raw material storage tank (4)
If these are connected via a link mechanism, there is no need to support the weight of the raw material storage tank (4) by the drive device (6), so the driving force can be reduced, and the weight of each raw material storage tank (4) can be reduced individually. Since it can be weighed, the storage layer of carbonaceous material can be calculated from the result. Further, as in this embodiment, if the amount of raw material input is set to 1 and a table scale (A) for controlling the bell is provided, there is no fear of overcharging, and the raw material input work can be performed accurately and quickly. In addition, the storage amount of each raw material (soda (4)) can be determined using two weighing machines: a bell control platform scale (c) and a popper weighing machine.

As explained above, according to the present invention, high precision measurement can be performed, the installation space can be reduced, and the loading operation can be easily performed, so that the present invention has extremely high industrial utility value.

[Brief explanation of drawings]

1 and 2 are block diagrams of a conventional measuring and blending apparatus, FIG. 3 is a plan view of the measuring and blending apparatus according to an embodiment of the present invention, and FIG. 4 is a front view thereof. (4)...Raw material storage tank, (6)...Drive device, (10
...Quantitative supply device, aη...Hopazuki＼-Weighing machine agent Yoshihiro Moriki

Claims (1)

[Claims] 1. A plurality of raw material storage tanks arranged in an annular manner, a drive device that rotates these raw material storage tanks around the center position of the annular arrangement, and a drive device installed in each of the raw material storage tanks to remove the raw materials inside the tank to the outside. 1. A weighing and blending device comprising: a quantitative feed device for discharging raw materials to a container; and a weighing machine fixedly installed at a predetermined location to receive and weigh the raw materials discharged from the quantitative feed device.