JPS6324896B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a bucket-type continuous unloader used for unloading bulk materials such as ore from a ship or the like, and particularly to a bucket-type continuous unloader having a quantitative dispensing control device.

The unloader is equipped with a boom that performs movements such as turning and elevating, and a plurality of buckets attached to a chain etc. from this boom. During cargo handling work, the buckets are guided into the ship's hatch and then The bucket is raised and lowered to excavate and cut out cargo.

In this type of bucket type continuous unloader,
If the amount of cargo to be delivered is irregular, equipment installed behind the unloader such as a conveyor must be enlarged, which increases the cost of the equipment.

However, when unloading bulk materials such as coal and ore that have been transported by ship, etc., the bulk materials are excavated by the bucket of the unloader, which may cause problems such as the amount of thrust of the bucket into the bulk materials and the collapse of the bulk materials. As a result, there is a problem in that the amount of dispensing is inevitably irregular, and conventionally, it has been common to have a buffer device such as a surge hopper for quantifying the amount of dispensing.

An object of the present invention is to provide a bucket-type continuous unloader equipped with a control device capable of quantifying the amount of cargo discharged with a simple configuration without requiring a buffer device such as a surge hopper. It is.

According to the present invention, there is provided a bucket elevator in which a plurality of bucket trucks are connected, a first driving device for moving the bucket elevator in a predetermined direction, and a first driving device for rotating the bucket elevator. The bucket type continuous unloader has a second drive device including a hydraulic motor, and continuously excavates and unloads cargo by rotating the bucket elevator, wherein the second drive device A first detection means for detecting the primary side pressure and obtaining a first detection signal; and a second detection means for detecting the rotational speed of the second drive device and obtaining a second detection signal. and measuring means for measuring the amount of the cargo delivered by the bucket elevator and obtaining a delivery signal; and the first detection signal, the second detection signal, and the delivery signal. , further comprising calculation means for inputting a setting signal for presetting the amount of cargo to be delivered, and for generating a correction signal based on the four signals; In addition to controlling the second drive device,
There is obtained a bucket-type continuous unloader equipped with a fixed quantity dispensing control device characterized in that the first drive device is controlled so that the discharging of the cargo is constant.

The present invention will be described below with reference to embodiments of the drawings.

First, referring to FIGS. 1a and 1b, the bucket type continuous unloader 1 includes a traveling truck 11 and a rotating section
2 and is laid along the quay.
The rotating section 12 is configured to be able to move horizontally and turn on the traveling carriage 11 in the left and right directions in FIG. 1a. Moreover, the boom 13 connected to the rotating part 12 can be raised and lowered in the vertical direction. The drive unit for these traveling, traversing, turning, and up-and-down operations is called a first drive unit. Furthermore, the continuous unloader can rotate the bucket elevator 14 attached to the tip of the boom 13 along an endless track. Bucket elevator 1
The drive unit for rotating 4 is called a second drive unit.

A plurality of buckets 16 are attached to a chain 15 of a bucket elevator 14. The ore 22 stored in the hatch 21 of the ship 20 is excavated by the rotation of the bucket 16 and transported to the outside of the hatch 21, as shown in FIG. 1a. Ore 22 carried out to the outside of this hatch 21
is transported by a belt conveyor or the like (not shown) provided on the boom 13.

In order to keep the above-mentioned carrying out by the bucket, that is, the amount of payout constant, the bucket elevator 14
The amount of thrust into the hatch 21, the speed of the traveling cart 11, the ups and downs of the boom 13, the rotation speed of the bucket 16, etc. must be determined appropriately, and the collapse of the ore and the shaking of the ship must also be taken into consideration.
As explained below, the bucket type continuous unloader according to the present invention is capable of dispensing a fixed amount.

Referring to FIG. 2, there is shown a dispensing path of a bucket-type continuous unloader according to the present invention. In this case, the bucket elevator draws a rectangular delivery path on the orthogonal coordinate system. First, origin A (x ₀ ,
The excavation depth is determined at A( _{x 0 ,} y ₀ ).
The bucket elevator travels from B (x ₁ , y ₀ ) to B (x ₁ , y ₀ ), and when it reaches B (x 1 , y 0 ), the bucket elevator starts a lateral movement and reaches C (x ₁ , y ₁ ). Then C(x ₁ , y ₁ )
From there, it travels toward D (x ₀ , y ₁ ), and from D (x ₀ , y ₁ ), it returns to the origin (x ₀ , y ₀ ) again through a lateral movement, completing one payout cycle.

Next, the fixed amount dispensing control device will be explained with reference to FIG.

A hydraulic motor 31 is disposed within the bucket elevator 14 and rotates the bucket truck 16. The rotational speed of the hydraulic motor 31 is controlled by the discharge amount of the hydraulic pump 38.

On the primary side of the hydraulic motor 31, the hydraulic motor 31
A pressure detector 32 is connected to detect the primary side pressure. Further, a speed detector 33 for detecting the rotation speed of the hydraulic motor 31 is connected to the rotation shaft of the hydraulic motor 31. Further, as mentioned above, the cargo discharged by the bucket elevator 14 is transported to rear equipment (such as a coal storage yard in the case of coal) by a belt conveyor (not shown), but the cargo is actually discharged. In order to measure (measure) the amount of delivered cargo, the belt conveyor is provided with a delivered amount measuring device 39 (conveyor scale). This dispensing amount measuring device 39 is composed of, for example, a load cell, and measures and detects the pressure due to the amount of cargo being conveyed on the belt conveyor, and outputs a dispensing signal (w) according to this pressure. Send.

Furthermore, the output sides of the pressure detector 32, speed detector 33, and dispensing amount measuring device 39 are connected to an arithmetic device 34, and the dispensing amount (Q) set in advance is sent to the arithmetic device 34. A payout amount setting device 35 for input is connected. The output of the arithmetic unit 34 is connected to a hydraulic control device 36 and a travel control device 37, and the output of the hydraulic control device 36 is fed back to a hydraulic pump 38 to control the speed of the hydraulic motor 31. Moreover, the output of the travel control device 37 is
It is connected to the drive device of the unloader in order to control the turning section or traveling section of the unloader. Further, the output of the computing device 34 is directly connected to the hoisting device of the boom 13 to control the hoisting of the boom 13.

Next, with reference to FIGS. 1 to 3, a case will be described in which the bucket type continuous unloader is controlled to dispense a fixed amount.

An arbitrary payout amount (Q) is set from the payout amount setting device 35 and inputted to the calculation device 34. Next, the bucket type continuous unloader is operated, the bucket 16 excavates ore 22, and the bucket elevator 14 discharges ore.

At this time, the pressure on the primary side of the hydraulic motor 31 operating the bucket elevator 14 is detected by the pressure detector 3.
2, a pressure signal (P) corresponding to the primary side pressure is output from the pressure detector 32,
It is input to the arithmetic unit 34. In addition, the hydraulic motor 3
The rotational speed of No. 1 is detected by the speed detector 33, and a speed signal (v) corresponding to the rotational speed is outputted and inputted to the arithmetic unit 34.

On the other hand, at a certain speed of the hydraulic motor 31, the primary pressure of the hydraulic motor 31 and the discharge amount have a linear relationship as shown by the solid line in FIG.
The discharge amount of the bucket elevator is determined by the primary pressure of the bucket elevator.

However, it is generally unavoidable that loose objects adhere to the bucket 16 of the bucket elevator 14, and therefore a difference (error) occurs in the relationship between the primary pressure of the hydraulic motor 31 and the discharge amount of the bucket elevator 14. . Furthermore, changes in the oil temperature of the hydraulic motor 31 cause a difference in pressure loss, and due to this pressure loss as well as differences in excavation resistance depending on the type of bulk material, the primary A difference (error) occurs between the side pressure and the discharge amount of the bucket elevator 14. Therefore, as described above, the payout amount actually measured by the payout amount measuring device 39 is input to the arithmetic unit 34.

In the arithmetic device 34, a payout amount setting device 35
The primary pressure of the hydraulic motor 31 corresponding to the discharge amount (Q) inputted from is calculated, and this calculated primary pressure (hereinafter simply referred to as calculated pressure (P')) is compared with the above pressure signal (P). do. If there is a difference between the calculated pressure (P') and the pressure signal (P), a control signal is sent to the hydraulic control device 36, and the hydraulic control device 36 sends an oil flow correction signal (R) to the hydraulic pump. Adjust the discharge amount of 38. Furthermore, since there is a linear relationship between the primary side pressure and the rotational speed of the hydraulic motor 31, the oil flow correction signal (R) is sent even when the speed signal (v) deviates from a predetermined value.

Further, in response to the oil flow correction signal (R) described above, a control signal is sent from the calculation device 34 to the travel control device 3.
7, and a travel control signal (T) is sent from the travel control device 37 to control the travel device of the bucket type continuous unloader 1. Incidentally, when the bucket type continuous unloader 1 is traversing, the traversing device is controlled.

However, as mentioned above, the set payout amount (Q)
Since an error occurs in the actual payout amount (w), the arithmetic unit 34 uses the payout signal (w) of the payout amount actually measured by the payout amount measuring device 39, as shown by the broken line in FIG. The relationship between the primary side pressure of the hydraulic motor 31 and the payout amount is corrected.

If the above relationship is expressed numerically, it will be as follows. Here, the proportionality constant (k) and the bias amount (q) are given from actual measurement data.

Set discharge amount (Q) = Proportionality constant (k) × Calculated pressure (P') × Rotational speed (v) - Bias amount (q) Calculated discharge amount (Q') = Proportionality constant (k) × Primary side pressure ( P) x rotational speed (v) - bias amount (q) The bias amount (q) is corrected by the measured payout amount (w) and the calculated payout amount (Q'), that is, the corrected bias amount q' = q- (w-Q′).

If controlled as described above, when the bucket type unloader 1 is discharging along an arbitrary route, when the load increases, such as when the amount of bucket thrust into the ore increases or the ore collapses,
Since the primary side pressure of the hydraulic motor 31 increases, this is detected and a correction signal (R) is sent to slow down the rotational speed of the hydraulic motor 31, and furthermore, to slow down the running of the bucket type continuous unloader, etc. A travel control signal (T) is sent to the vehicle. Similarly, when the load decreases, the hydraulic motor 3
Since the primary side pressure of 1 decreases, the hydraulic motor 31
A correction signal (R) is sent out to increase the rotational speed of the bucket type continuous unloader, and a travel control signal (T) is sent out to speed up the travel of the bucket type continuous unloader. In addition, when the actual dispensing amount and the set dispensing amount (Q) are significantly different, the boom 13 can be raised and lowered by the raising and lowering device to eliminate the difference between the set dispensing amount and the actual dispensing amount.

As explained above, in the bucket type continuous unloader according to the present invention, the primary side pressure and rotational speed of the hydraulic motor of the bucket elevator are detected, and the actual discharge amount is measured, and the discharge amount and the primary side of the hydraulic motor are detected. The rotation speed of the hydraulic motor is controlled by correcting the relationship with the side pressure, and furthermore, the traveling device, traversing device, or luffing device of the bucket type unloader is controlled, so that the set payout amount can be adjusted to a predetermined amount. It is possible to quantitatively control the actual payout amount with extremely high accuracy. Further, according to the present invention, it is possible to reduce the error in the amount of discharge caused by the error in the excavation depth of the bucket elevator or the installation error of the running rail, and the configuration of the control device is also simple.

Note that the above-mentioned pressure signal, speed signal, dispensing setting signal, and dispensing measurement signal may be always input to the arithmetic device, or may be input to the arithmetic device at regular intervals. Furthermore, the pressure difference between the primary side pressure and the secondary side pressure of the hydraulic motor may be used as the pressure signal. In addition, when searching while the boom is turning, the turning speed of the boom may be corrected.

[Brief explanation of the drawing]

FIG. 1a is a side view of a bucket-type continuous unloader according to the present invention, FIG. 1b is a top view of a bucket-type continuous unloader according to the present invention, and FIG. 2 is a diagram showing a bucket-type continuous unloader according to the present invention. FIG. 3 is a block diagram showing the fixed amount dispensing control device used in the bucket type continuous unloader according to the present invention, and FIG. 4 is a diagram showing the relationship between the primary pressure of the hydraulic motor and the dispensing amount. be. In the figure, 1... bucket type continuous unloader, 10... track, 11... traveling trolley, 12...
Swivel part, 13...boom, 14...bucket elevator, 15...chain, 16...bucket,
20...Ship, 21...Hatsuchi, 22...Ore,
31... Hydraulic motor, 32... Pressure detector, 33
. . . speed detector, 34 . . . calculation device, 35 .

Claims (1)

[Claims] 1. A bucket elevator that connects a plurality of bucket elevators, a first drive device for moving the bucket elevator in a predetermined direction, and a second bucket elevator that includes a hydraulic motor for rotating the bucket elevator. A bucket type continuous unloader that continuously excavates and unloads cargo by rotating the bucket elevator, the primary side pressure of the hydraulic motor of the second drive device a first detection signal to obtain a first detection signal.
a second detection means for detecting the rotational speed of the second drive device and obtaining a second detection signal; and an amount of the cargo delivered by the bucket elevator. measuring means for measuring and obtaining a dispensing signal, the first detection signal, the second detection signal, the dispensing signal, and a setting signal for presetting the amount of the cargo to be disbursed. and a calculation means for generating a correction signal using the input four signals, and using the correction signal,
A bucket-type continuous unloader equipped with a fixed amount dispensing control device, characterized in that the second drive device is controlled and the first drive device is also controlled so that the unloading of the cargo is constant. .