KR20230061953A - Continuous ship unloader - Google Patents

Abstract

The invention for a continuous unloading device is disclosed. The disclosed continuous unloading device includes: a frame part mounted on a boom part, a plurality of sprocket parts rotatably mounted on the frame part, a chain part wound around the plurality of sprocket parts and moving in an endless track manner, and mounted on the chain part, It is characterized in that it includes a bucket unit for excavating fuel and supplying fuel to the boom unit, mounted on the frame unit, in contact with the bucket unit, and operating when there is no contact with the bucket unit to detect separation of the bucket unit. .

Description

Continuous unloading device {CONTINUOUS SHIP UNLOADER}

The present invention relates to a continuous unloading device, and more particularly, to a continuous unloading device that prevents damage due to detachment of a bucket.

In general, iron ore and coal used as raw fuel for blast furnace operation in a steel plant are transported by ship, unloaded at a pier, and then transported to an open storage yard of a factory through transportation facilities such as a belt conveyor. Fuel materials such as coal or iron ore loaded on a ship are transferred to the outside of the ship using buckets continuously attached to elevator posts of continuous unloaders.

The background art for the present invention is disclosed in Republic of Korea Patent Registration No. 10-1968820 (title of the invention: continuous unloading device, registration date: 2019.04.08.).

According to one embodiment of the present invention, it is to provide a continuous loading and unloading device that prevents damage due to detachment of the bucket.

The continuous unloading device of the present invention includes: a frame part mounted on a boom part; a plurality of sprocket parts rotatably mounted on the frame part; a chain part wound around the plurality of sprockets and moving in an endless track; a bucket unit mounted on the chain unit, excavating fuel and supplying fuel to the boom unit; and a bucket departure detection unit mounted on the frame unit, in contact with the bucket unit, and operated when there is no contact with the bucket unit to detect separation of the bucket unit.

In addition, it is characterized in that it further comprises; receiving a detection signal from the bucket separation detection unit, and stopping the operation of the sprocket based on the detection signal.

In addition, the bucket departure detection unit, the installation unit mounted on the frame unit; a bucket contact portion rotatably installed on the installation portion, in contact with the bucket portion, and rotated when the bucket portion is not in contact; a detection unit mounted on the installation unit and transmitting a detection signal to the control unit; and a sensing operation unit connected to the bucket contact unit and rotating together with the bucket contact unit to operate the sensing unit.

In addition, the installation unit may include a first installation frame installed in a vertical direction to the frame unit and rotatably coupled to the bucket contact unit; And a second installation frame installed in the frame part in a vertical direction spaced apart from the first installation frame and rotatably coupled to the bucket contact part.

In addition, the bucket contact portion is rotatably coupled through the first installation frame and the second installation frame, and the rotation frame portion to which the sensing operation unit is coupled; a contact portion connected to the rotating frame portion and brought into contact with the bucket portion; and a weight unit connected to the rotation frame unit, having a set weight, and applying a load to the rotation frame unit when the contact unit and the bucket unit do not contact each other to rotate the rotation frame unit.

In addition, the contact unit may include a pair of contact frames coupled to the rotation frame unit to be spaced apart; and a contact roller part rotatably coupled between the pair of contact frames and rotated in contact with the bucket part.

In addition, the weight portion, a pair of weight frames each extending to one side at both ends of the rotating frame portion; and a pair of weight weights each coupled to the weight frame and having a set weight.

The continuous loading and unloading device according to the present invention quickly detects the separation of the bucket through the bucket separation detection unit that operates when there is no contact with the bucket and detects the separation of the bucket and controls the movement of the chain connected to the bucket. There is an effect of preventing damage to the continuous unloading machine due to

1 is a diagram schematically showing a continuous unloading device according to an embodiment of the present invention.
2 is an enlarged view of a main part of a continuous unloading device according to an embodiment of the present invention.
3 is an enlarged view of a portion of a bucket departure detection unit of a continuous loading and unloading device according to an embodiment of the present invention.
4 is a view showing a state in which the bucket separation detection unit of the continuous unloading apparatus according to an embodiment of the present invention detects separation of the bucket unit.
5 to 7 are diagrams showing a state in which the bucket departure detection unit of the continuous unloading device according to an embodiment of the present invention is in contact with the bucket unit.
8 and 9 are diagrams showing a state in which the bucket separation detection unit of the continuous loading and unloading apparatus according to an embodiment of the present invention does not contact the bucket unit and detects the separation of the bucket unit.

Hereinafter, a continuous unloading device according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

1 is a schematic view of a continuous unloading device according to an embodiment of the present invention, FIG. 2 is an enlarged view of a main part of the continuous unloading device according to an embodiment of the present invention, and FIG. It is an enlarged view of the bucket separation detection unit of the continuous unloading device according to the embodiment, and FIG. 4 is a view showing a state in which the bucket separation detection unit of the continuous unloading device according to an embodiment of the present invention detects separation of the bucket unit. 5 to 7 are views showing a state in which the bucket departure detection unit of the continuous unloading device according to an embodiment of the present invention is in contact with the bucket unit, and FIGS. 8 and 9 are continuous according to an embodiment of the present invention. It is a drawing showing a state in which the bucket separation detection unit of the type loading and unloading device does not contact the bucket unit and detects the separation of the bucket unit.

1 to 9, the continuous unloading device 1 according to an embodiment of the present invention includes a frame part 100, a plurality of sprocket parts 200, a chain part 300, and a bucket part 400. , It includes a bucket departure detection unit 500 and a control unit 600. The frame part 100 is mounted on the boom part 10 .

The boom unit 10 is mounted on the traveling unit 20 and carries the fuel material 50. At this time, the driving unit 20 is moved along the pier 30. For example, the driving unit 20 may be moved in a forward and backward direction to approach or move away from the ship 40 anchored at the pier 30 .

The raw material 50 is moved through the boom unit 10 to an above ground belt conveyor (not shown) provided below the driving unit 20 and is moved to an open storage yard.

The frame unit 100 includes a first frame 110 and a second frame 120 . The first frame 110 is coupled to the lower portion of the boom unit 10 and can be adjusted in length in the vertical direction. The second frame 120 is coupled to the lower end of the first frame 110 and can be adjusted in length in the left and right directions.

The plurality of sprocket parts 200 are rotatably mounted on the frame part 100 . The plurality of sprocket parts 200 are rotatably installed on at least one of the first frame 110 and the second frame 120, and the chain part 300 described later is interlocked and coupled. That is, the chain part 300 is moved by driving the sprocket part 200 .

The chain part 300 is wound around the plurality of sprocket parts 200 and moves in an endless orbit. The chain part 300 engages with the sprocket part 200, and a plurality of bucket parts 400 are mounted spaced apart from each other along the chain part 300.

The bucket unit 400 is mounted on the chain unit 300, excavates fuel material 50, and supplies it to the boom unit 10. The bucket part 400 is mounted on the chain part 300 engaged with the outside of the sprocket part 200, and transports the raw material 50 by turning the outside of the frame part 100 together with the chain part 300.

The bucket departure detection unit 500 is mounted on the frame unit 100, comes into contact with the bucket unit 400, and operates when there is no contact with the bucket unit 400 to detect separation of the bucket unit 400.

The bucket separation detection unit 500 operates when the bucket unit 400 is separated from the chain unit 300 and the interval between the bucket units 400 is an abnormal interval (L), the bucket separation detection unit 500 is operated and the bucket unit ( 400) detects departure.

The control unit 600 receives a detection signal from the bucket departure detection unit 500 and stops the operation of the sprocket unit 200 based on the detection signal.

Specifically, the control unit 600 receives a detection signal from the bucket separation detection unit 500, and stops the operation of the sprocket unit 200 based on this, thereby stopping the movement of the chain unit 300 in an endless track manner. At this time, the control unit 600 generates an alarm signal so that the operator can recognize the departure of the bucket unit 400. As a result, it is possible to prevent the continuous unloading device 1 from being damaged due to separation of the bucket part 400 .

The bucket departure detection unit 500 includes an installation unit 510, a bucket contact unit 520, a detection unit 530, and a detection operation unit 540. The installation part 510 is mounted on the frame part 100 . The installation unit 510 includes a first installation frame 511 and a second installation frame 512 . The first installation frame 511 is installed in the frame part 100 in a vertical direction, and the bucket contact part 520 described later is rotatably coupled.

The second installation frame 512 is installed in the frame unit 100 in a vertical direction spaced apart from the first installation frame 511, and the bucket contact portion 520 described later is rotatably coupled.

The bucket contact portion 520 is rotatably installed on the installation portion 510, contacts the bucket portion 400, and rotates when the bucket portion 400 does not contact. The bucket contact portion 520 includes a rotating frame portion 521, a contact portion 522, and a weight portion 523. The rotating frame unit 521 is rotatably coupled through the first installation frame 511 and the second installation frame 512 in a columnar shape, and the sensing operation unit 540 described below is coupled thereto.

The contact portion 522 is connected to the rotating frame portion 521 and contacts the bucket portion 400 . The contact portion 522 includes a pair of contact frames 522a and a contact roller portion 522b. A pair of contact frames 522a are coupled to the rotation frame unit 521 to be spaced apart.

The contact roller portion 522b is rotatably coupled between the pair of contact frames 522a and is rotated upon contact with the bucket portion 400 . The contact roller 522b is rotated upon contact with the bucket 400 to minimize friction with the bucket 400 .

The weight portion 523 is connected to the rotating frame portion 521, has a set weight, and applies a load to the rotating frame portion 521 when the contact portion 522 and the bucket portion 400 do not contact each other, so that the rotating frame portion 521 ) is rotated.

The weight unit 523 includes a pair of weight frames 523a and weight weights 523b. A pair of weight frames 523a are formed extending to one side at both ends of the rotating frame unit 521, respectively. The weights 523b are each coupled to a pair of weight frames 523a and have a set weight.

The detection unit 530 is mounted on the installation unit 510 and transmits a detection signal to the control unit 600 . The sensing unit 530 protrudes from the installation unit 510 to one side and can contact the sensing operation unit 540 .

The detection operation unit 540 is connected to the bucket contact unit 520 and is rotated together with the bucket contact unit 520 to operate the detection unit 530 . The sensing operation unit 540 is connected to the rotation frame unit 521 of the bucket contact unit 520 in a bar shape, and rotates together with the rotation frame unit 521 when the rotation frame unit 521 rotates, thereby detecting the detection unit 530. come into contact with

Hereinafter, the operation and effect of the continuous unloading device according to an embodiment of the present invention will be reviewed with reference to FIGS. 5 to 9 .

When the bucket unit 400 is separated from the chain unit 300 and the interval between the bucket units 400 becomes an abnormal interval, the bucket separation detection unit 500 does not come into contact with the bucket unit 400 and is operated so that the bucket unit ( 400) is detected. In normal times, the bucket separation detection unit 500 is in contact with the bucket unit 400 .

Specifically, the bucket contact unit 520 of the bucket separation detection unit 500 is rotated on the installation unit 510 of the bucket separation detection unit 500 to come into contact with the detection unit 530 of the bucket separation detection unit 500 .

At this time, the rotation frame portion 521 of the bucket contact portion 520 is rotated by the set weight of the weight portion 523 of the bucket contact portion 520, and the bucket contact portion connected to the rotation frame portion 521 of the bucket contact portion 520 ( The contact part 522 of 520 is in contact with the detection part 530 of the bucket separation detection part 500 .

When the bucket separation detection unit 500 detects separation of the bucket unit 400, it transmits a detection signal to the control unit 600. That is, when the contact part 522 of the bucket contact part 520 is in contact with the detection part 530 of the bucket departure detection part 500, the detection part 530 transmits a detection signal to the control unit 600.

The control unit 600 stops the operation of the sprocket unit 200 based on the detection signal received from the bucket separation detection unit 500 . As a result, the movement of the chain unit 300 in an endless orbit is stopped.

As a result, it is possible to prevent the continuous unloading device 1 from being damaged due to separation of the bucket part 400 . At this time, the control unit 600 generates an alarm signal so that the operator can recognize the departure of the bucket unit 400.

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand

Therefore, the true technical protection scope of the present invention should be determined by the claims below.

1: continuous unloading device 10: boom part
20: driving part 30: pier
40: ship 50: raw fuel
100: frame part 110: first frame
120: second frame 200: sprocket part
300: chain part 400: bucket part
500: bucket departure detection unit 510: installation unit
511: first installation frame 512: second installation frame
520: Bucket contact part 521: Rotation frame part
522: contact part 522a: contact frame
522b: contact roller part 523: weight part
523a: weight frame 523b: weight weight
530: sensing unit 540: sensing operation unit
600: control unit

Claims (7)

A frame part mounted on the boom part;
a plurality of sprocket parts rotatably mounted on the frame part;
a chain part wound around the plurality of sprockets and moving in an endless track;
a bucket unit mounted on the chain unit, excavating fuel and supplying fuel to the boom unit; and
and a bucket departure detection unit mounted on the frame unit, in contact with the bucket unit, and operated when there is no contact with the bucket unit to detect separation of the bucket unit.
According to claim 1,
The continuous loading and unloading device further comprises a control unit that receives a detection signal from the bucket departure detection unit and stops the operation of the sprocket unit based on the detection signal.
According to claim 2,
The bucket departure detection unit,
an installation unit mounted on the frame unit;
a bucket contact portion rotatably installed on the installation portion, in contact with the bucket portion, and rotated when the bucket portion is not in contact;
a detection unit mounted on the installation unit and transmitting a detection signal to the control unit; and
and a sensing operation unit connected to the bucket contact unit and rotated together with the bucket contact unit to operate the sensing unit.
According to claim 3,
The installation part,
a first installation frame installed in the vertical direction to the frame part and rotatably coupled to the bucket contact part; and
The continuous unloading device comprising a second installation frame installed in the frame part in a vertical direction spaced apart from the first installation frame and rotatably coupled to the bucket contact part.
According to claim 4,
The bucket contact part,
a rotating frame portion rotatably coupled through the first installation frame and the second installation frame and to which the sensing operation unit is coupled;
a contact portion connected to the rotating frame portion and brought into contact with the bucket portion; and
A weight unit that is connected to the rotation frame unit, has a set weight, and applies a load to the rotation frame unit to rotate the rotation frame unit when the contact unit and the bucket unit do not contact each other. .
According to claim 5,
the contact part,
a pair of contact frames spaced apart from each other; and
and a contact roller part rotatably coupled between the pair of contact frames and rotated in contact with the bucket part.
According to claim 5,
The weight part,
A pair of weight frames extending to one side at both ends of the rotating frame unit; and
A continuous loading and unloading device comprising a pair of weights each coupled to the weight frame and having a set weight.

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