KR0123473Y1 - Control system for conveying concrete - Google Patents

Abstract

The present invention relates to an inflow control system between cements for controlling the amount of cement flowed in to store the cement. In general, the cement transported by the freight train is loaded on the bucket elevator by a vacuum suction force in a suspended state by the air slide to flow into the upper portion.

In this process, the amount of cement discharged from the freight train is inevitably ups and downs, and the amount of cement transferred by the bucket elevator is irregular, and the amount of the cement is too high, causing the bucket elevator to become overloaded or low in transport efficiency. There was also a problem.

The present invention installs a bypass pipe at one or more positions on one side of the air slide, connects a control bin to it, and installs a transfer screw on the bottom to control the motor so that the inlet of the bucket elevator is always sufficient and uniform. By allowing the cement to be transported, the transfer efficiency is greatly increased, and it can be operated smoothly without overloading, thereby reducing the incidence of failure and reducing maintenance costs.

Description

Inflow control system between cements

1 is a graph showing the amount of cement supplied to the bucket elevator between the conventional cement by time zone.

2 is an explanatory view showing the overall configuration of the inflow control system between cements according to the present invention.

Figure 3 is a perspective view showing the main part of the control system according to the present invention.

4 is an explanatory view showing an enlarged portion of FIG.

5 is a graph showing the amount of cement supplied to the bucket elevator between the cement according to the present invention over time.

* Explanation of symbols for main parts of the drawings

1: Connecting suit 2: Gate

3: Air slide 4: Bucket elevator

5: bypass tube 6: control bin

7: Screw Conveyor 8: Driving Motor

9: level switch

The present invention relates to an inflow control system between cements for controlling the amount of cement flowed in to store the cement. In general, the cement is transported from the production site to the storage using a freight train, and the cement transported by the freight train is loaded on the bucket elevator in a floating state by the inclined air slide (3) so as to flow into the upper part. .

In this process, the amount of cement discharged from the freight train is so undulating that it gradually increases from zero to maximum as recorded in the first road, and then decreases to zero again. When there is almost no amount of cement loaded on the bucket elevator for conveying the cement, and when the overload is excessive, the motor for driving the bucket elevator is stopped or burned out due to overheating. There is a problem that increases the maintenance cost burden resulting in, and to reduce the maximum amount of transportation to reduce the maximum amount of transport in order to enable smooth operation, there is a problem that the transportation efficiency is low.

Furthermore, if any part of the cement is blocked in the transportation process, there is a problem in that the overall transportation efficiency is further lowered.

In order to solve this problem, the present invention allows the cement to be supplied from the gate 2 of the freight train to the bucket elevator through a plurality of air slides 3 installed at an optimum angle, but at one side of the air slide 3 Bypass pipe (5) is installed in the above position and the control bin (6) is connected to the lower side of the transfer screw to control the motor (8) by controlling a constant amount of cement in the bucket elevator always When the present invention is described in detail by the accompanying drawings as to be supplied as follows.

2, 3, and 4 illustrate an inflow control system between cements according to the present invention.

As can be seen from the present invention, when the freight train reaches the connecting chute 1 position for unloading cement and opens the gate 2 and starts unloading the cement, the cement is suspended by the air slide 3 inclined. Inflow into the inlet of the bucket elevator (4) is the same as the conventional one.

In particular, the present invention provides a bypass pipe 5, a control bin 6, and a screw conveyor 7 between the inlet of the bucket elevator 4 and the air slide 3 in front of the bucket elevator 4. ) Is connected to the negative side of the air slide 3, the discharge pipe of the screw conveyor 7 is connected above the inlet of the bucket elevator 4, and the motor 8 for driving the skew conveyor 7 is leveled. The driving is controlled in accordance with the operation of the switch 9. In this way, the present invention ensures that the freight train stops at the correct position to unload cargo in the workplace, then operates the bag filter, starts the bucket elevator 4, operates the air slide 3, opens the hatch of the freight train and opens the cone. When the connecting chute 1 is raised and the gate 2 is opened and air is supplied to the freight train, cement loaded on the freight train may fall onto the air slide 3.

After this, the sucked cement begins to move in a floating state by the air slide 3, at which time the amount of cement supplied to the inlet of the bucket elevator 4 is initially low so that the intermediate level of the air slide 3 Will not exceed.

Therefore, initially, the sucked cement reaches the inlet of the bucket elevator 4 directly without going through the bypass pipe 5 because the level of cement passing through the air slide 3 is below the middle.

In this state, the bucket elevator (4) is to pull the cement upwards to inject the cement upwards. In the present design, the bucket elevator (4) is installed in two stages to lift the cement and the cement is introduced from above. have.

When operating in this state, the amount of cement supplied through the connecting chute 1 connected to the freight train gradually increases, and thus approaches the maximum as shown in FIG. 1.

The maximum value exceeds the proper transportation capacity of the bucket elevator 4, and in this case, the amount of cement dispersed in the bucket elevator 4 at the time when the flow volume to the bucket elevator 4 is dispersed and the flow rate into the bucket elevator 4 is reduced is increased. (4) allows a substantially uniform amount of cement to flow into the bucket elevator (4), thereby increasing the transfer efficiency of the bucket elevator (4) and at the same time driving the bucket elevator (4) or a motor (8) for driving the same. ) Can prevent overload and long life.

That is, in the present invention, when the level of cement passing through the air slide 3 in the front of the inlet of the bucket elevator 4 exceeds the middle, the air slide 3 starts to become overloaded with the bucket elevator 4. Cement flows into the bypass pipe 5 formed at the intermediate level or more in the above), and thus the cement introduced into the bypass pipe 5 is filled in the control bin 6. In this state, as time passes, the control bin 6 is filled with a substantial amount of cement, and at the same time, the appropriate amount of cement introduced into the bucket elevator 4 is continuously transferred by the bucket elevator 4.

As a result, the amount of cement coming down from the freight train gradually decreases past the maximum value. As a result, the level of cement passing through the air slide 3 also decreases to be below the height connected with the bypass pipe 5 so that the bucket elevator 4 inlet The cement level of the site also decreases.

This level reduction is detected by the sensing section of the level switch 9 and the motor 8 of the screw conveyor 7 which is controlled and operated by the level switch 9 starts to operate so that the control bin 6 Cement is transferred to the inlet of the bucket elevator (4). Therefore, the inlet of the bucket elevator 4 can be maintained at an appropriate level by the cement supplied through the air slide 3 and the cement stored in the control bin 6 introduced through the screw conveyor 7.

Accordingly, the amount of cement conveyed by the bucket elevator 4 is in a state where there is almost no ups and downs, unlike the conventional one, and it is possible to maintain an appropriate amount to maximize the transport rate and at the same time relate to the bucket elevator 4. The parts are not impeded at all and this state is shown in FIG.

In this way, the present invention is that the bucket elevator (4) is enough to transfer a substantially uniform amount of cement, while maintaining a high transport efficiency, while maintaining the proper load on the bucket elevator (4) and its mechanisms for driving smoothly It is a practical design that has a useful effect, such as not only to reduce the occurrence rate of the failure to reduce the maintenance cost by operating, but also to facilitate the inflow of cement to greatly increase the work efficiency.

Claims (1)

When the freight train reaches the connecting chute (1) position for unloading the cement, the gate (2) is opened and the unloading cement begins to unload, and the bucket elevator (4) is driven by the vacuum suction input while the cement is suspended by the air slide (3). In the well-known inlet which flows into the inlet of (), the bypass pipe 5, the control bin 6, and the screw conveyor 7 are installed between the inlet of the bucket elevator 4 and the air slide 3 in front of it. Bypass pipe 5 is connected to the height of the middle or higher of the air slide 3, the discharge pipe of the screw conveyor (7) is connected to the upper inlet of the bucket elevator (4) for driving the electric skew conveyor (7) The inflow control system between cements characterized in that the motor (8) allows the drive to be controlled in accordance with the operation of the level switch (9).