JPS6260329B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to the structure of a magnetic separation device mounted in an unloader used to unload raw materials such as coal and ore from a ship.

Unloaders are used when unloading raw materials such as coal and ore from ships and the like. The raw materials unloaded by the unloader are sent to the yard by a conveyor installed on the ground. At this time, if magnetic contaminants such as iron pieces are present in the raw materials, the conveyor belt of the transport conveyor is often torn or the conveyor mechanism is damaged.

The economic loss associated with a failure of this conveyor is large, and not only does the ship's time on board become longer, but it also has a significant impact on related systems. Therefore, it is required that the magnetic pieces in the raw material be completely separated in an unloader before the conveyor.

This problem can be solved by installing a magnetic separation device on the in-machine conveyor installed in the unloader or at a suitable location in the machine to magnetically attract and separate the magnetic pieces.

By the way, extremely high unloading capabilities are required for economical reasons such as improving the efficiency of unloading operations and shortening the time on board. For this reason, a magnetic separator that removes magnetic contaminants mixed in cargo handling and conveyance is also required to have large processing capacity. This processing capacity is determined by the attraction capacity of the electromagnet, and the requirement for high attraction capacity leads to the electromagnet becoming larger.

On the other hand, existing unloaders do not have enough space to accommodate a magnetic separation device with a huge electromagnet, and there is not enough strength to support it. If we plan something that satisfies these requirements, it will inevitably lead to an increase in the size of the unloader, and this will be difficult to implement considering the changes in peripheral equipment and systems that this increase in size will entail.

The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a magnetic separator that can be easily mounted inside an unloader by reducing the size and weight of a strong magnetic separator.

The present invention comprises a separator having an electromagnet that is cooled by a refrigerant such as insulating oil, a radiator that cools the refrigerant, and a forced circulation device that circulates the refrigerant through the separator and the radiator. This is done in a magnetic separation device of an unloader of the type in which magnetic contaminants in raw materials moving on an in-machine conveyor are sucked and separated by the separator, and the separator is of a suspended type and is suspended close to the upper surface of the in-machine conveyor. At the same time, the radiator and the forced circulation device are installed at different positions in the unloader body apart from the separator, and the radiator is divided into two circuits, and the pump discharge side of the forced circulation device is separated from the separator. and one of the circuits, an opening/closing control valve is provided that detects the temperature of the refrigerant in the circulation system and controls the valve to open when the oil temperature is above a set temperature and close when the oil temperature is below the installation temperature,
Connect these with pipes.

In other words, the electromagnet, which is the main body of the magnetic separation device, is made smaller by forcibly circulating a heat transfer medium such as insulating oil between the electromagnet, which is the heat generating part, and the radiator, which is the heat radiating part, to enhance the cooling effect. With,
Magnetic separation allows the radiator and forced circulation devices (such as oil pumps) that occupy a large space to be installed in a narrow space inside the unloader by separating them from the magnetic separator and installing them in different locations inside the unloader. The aim is to provide the equipment. In other words, by creating a separate structure, the weight and size can be reduced to within the allowable range of the structural strength of the existing unloader, and the powerful magnetic magnet can be installed without making any changes to the unloader. The purpose is to provide a separation device. Furthermore, by installing the heat radiator and forced circulation device at a location away from the magnetic separator,
It is possible to prevent a concentrated load from being applied to the installation position, and it is not necessary to increase the structural strength of the unloader too much. Further, the device does not require a large installation space, and can be installed using two or more small spaces at separate locations.

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

FIG. 1 is a diagram illustrating a schematic structure of an unloader suitable for applying the present invention, and a man trolley type unloader is illustrated.

The unloader consists of a crossbeam 4 extending toward the sea supported by a pedestal that can run on rails 1, 1 laid on land along a quay via rolling wheels 2, 2, and a pedestal 3, 3. The machine includes a body 6 consisting of a pedestal 5 supported at an intermediate height position. A man trolley type crane hoisting device (hereinafter referred to as a hoisting device) 8 that can travel via a trolley 7 is provided on the crossbeam 4 . The pedestal 5 is installed at a height that does not interfere with the travel of the hoist 8, a receiving hopper 9 is arranged near the seaward end of the pedestal, and a delivery hopper is arranged at the landward end of the pedestal. 10 are arranged.

An in-machine conveyor 11 is provided within the frame 5 and runs between the receiving hopper 9 and the sending hopper 10.

The hoisting device 8 is supported by a trolley 7 so as to be able to run along the crossbeam 4, and is capable of reciprocating between a seaside position shown by a solid line in FIG. 1 and a landside position shown by a two-dot chain line. It's summery. A raw material loading/unloading machine such as a grab bucket 12 is connected to the rope end of the hoisting device 8 . Raw materials on ships that have docked are
A certain amount is scooped up by the hoisting device 8, and after traveling on the trolley 7 and moving it onto the receiving hopper 9, it is thrown into the receiving hopper and placed in the feeder 1.
3 through the in-machine conveyor 11 at a predetermined delivery speed.
supplied to

The raw material from the in-machine conveyor 11 is fed through an output hopper 10 to a transfer conveyor 14, as shown in FIGS. 1 and 2, and transported to the yard.

A magnetic separator 1 is installed in the middle of the in-machine conveyor 11.
5 is installed. This magnetic separator is suspended on a pedestal 5 or a machine frame of an internal conveyor 11.

As shown in FIGS. 1 and 2, a radiator 16 and an oil feed pump (forced Circulation device) 17
is installed. Note that reference numeral 18 in FIG. 2 indicates a conveyor belt of the in-machine conveyor 11.

The magnetic separator 15 has an oil-filled electromagnet 19 as shown in FIG. 3, and the excitation coil of the electromagnet is immersed in an oil bath of insulating oil (heat transfer medium).
The cooling effect is enhanced by forced circulation.

For this forced cooling, the magnetic separator (specifically, the oil tank) 15, the radiator 16, and the forced circulation device 17 are connected by a pipe 20.

FIG. 3 is a diagram illustrating details of the magnetic separator 15. In FIG. 3, the magnetic separator 15 has an oil-filled electromagnet 19, and a magnetically acting surface 21 is formed on the lower surface of the electromagnet so as to apply a magnetic field toward the conveyor belt 18.

An endless belt 22 is stretched around the electromagnet 19 and runs along a magnetically active surface 21 in the direction of arrow A, that is, in a direction across the conveyor belt 18 . This endless belt is connected to drive pulley 2
3 and the driven pulley 24. A chute 25 is provided at a position after the endless belt 22 passes the conveyor belt 18 . The magnetic pieces absorbed by the surface of the endless belt 22 while passing through the magnetically active surface 21 are removed from this chute 25.

FIG. 4 is an explanatory diagram illustrating the arrangement of the magnetic separator 15, the radiator 16, and the forced circulation device 17 that constitute the magnetic separator of the present invention.

The magnetic separator 15 has an oil-filled electromagnet 1 as a heat generating part.
9, the insulating oil (heat transfer medium) circulated through this enters the oil feed pump 17 through the pipe line 20, and the insulating oil discharged from the pump flows through two circuits 16.
After being cooled by circulating in the radiator 16 divided into A and 16B, the electromagnet 19 is passed through the conduit 20 again.
introduced into the world.

An on-off control valve 26 is provided in the inlet branch pipe of one of the two circuits 16A and 16B of the radiator 16, and an on-off control valve 26 is provided at an appropriate position in the pipe 20 to control the temperature of the insulating oil (heat transfer medium) of the circulation system. Oil temperature detector 2 that detects
7 is provided. The opening/closing control valve 26 is operated in response to a detection signal from the oil temperature detector 27, and is closed when the oil temperature is lower than a set value.

By dividing the radiator 16 into two circuits and controlling the opening and closing of one circuit according to the temperature of the heat transfer medium, the overall volume of the radiator 16, which occupies a large volume, can be reduced. At the same time, the load on the forced circulation device 17 such as the oil pump can be reduced. That is, since the sum of the surface areas required for heat radiation in the divided heat radiator 16 increases, the overall volume can be made relatively small. And when the oil temperature is low, the reverse phase pump
It is only necessary to send the heat transfer medium to one of the divided heat radiators, which reduces the load.

According to the embodiment described above, in the magnetic separation device for an unloader configured to cool the heat generating part by circulating a heat transfer medium between the electromagnet 19, which is the heat generating part, and the heat radiator 16, the heat radiator 16 and The forced circulation device 17 is installed separately at a separate location away from the magnetic separator 15, and is connected with a pipe line 20 to forcefully circulate a heat transfer medium such as insulating oil, thereby increasing the cooling effect and at the same time The magnetic separator can be made smaller and lighter, and therefore a magnetic separator can be obtained that can be easily mounted on an unloader with a small interior space, such as an existing unloader.

In addition, since the radiator 16 is divided into two circuits, one of which is controlled to open and close based on the oil temperature detection value, the load on the oil feed pump (forced circulation device) 17 can be reduced when the oil temperature is low. At the same time, since the surface area of the heat radiator increases, the overall volume of the heat radiator, which occupies a large volume, can be reduced.

Although insulating oil was used as the heat transfer medium in the above embodiments, water or other fluids may be used to further enhance the cooling effect.

As is clear from the above description, according to the present invention, a powerful and compact magnetic separation device can be easily installed in the unloader machine, and the magnetic contaminants of the unloader can be easily removed from the raw materials. A separation device is obtained. Furthermore, it has unique effects compared to conventional techniques in that concentrated loads can be avoided and a large amount of installation space is not required. In other words, an "unloader" is generally a moving beam structure supported by four pillars.
The total weight must be as light as possible, and therefore a limited number of members with limited strength are used for each strength member, such as a steel frame. Therefore, if the equipment placed on the unloader is a single piece of equipment, a large concentrated load will be generated at one location of the unloader, which is a structural body, and the strength and number of steel frames will increase. The total weight will also increase. However, by separately installing and dividing the heat sink as in the present invention, concentrated loads can be avoided, the strength and number of steel frames etc. can be reduced, and the total weight of the unloader can also be reduced.

Furthermore, the unloader is made up of a limited number of steel frames, etc., and requires a small amount of installation space. By separately installing and separating the heat radiators, the present invention can be installed by securing only a few installation spaces, which is a fraction of the conventional installation space. Furthermore, since the present invention makes it easy to secure installation space by making the separator a "suspended type," the effect regarding the installation space is even greater.

[Brief explanation of the drawing]

FIG. 1 is a front view illustrating the overall configuration of an unloader to which the present invention is applied, FIG.
FIG. 4, a sectional view taken along the line - in the figure, is an explanatory view illustrating a forced circulation system for cooling an electromagnet according to the present invention. 3... Pillar, 4... Cross beam, 5... Frame, 6...
Unloader body, 8...Hoisting device, 9...Accepting hopper, 10...Delivery hopper, 11...In-machine conveyor, 14...Transfer conveyor, 15...Magnetic separator, 16...Radiator, 16A, 16B...
Circuit, 17...Forced circulation device, 18...Conveyor belt, 19...Electromagnet, 20...Pipe line, 26...
...Opening/closing control valve, 27...Oil temperature detector.

Claims (1)

[Claims] 1. A separator having an electromagnet that is cooled by a refrigerant such as insulating oil, a radiator that cools the refrigerant, and a forced circulation device that circulates the refrigerant through the separator and the radiator. , in a magnetic separation device for an unloader in which magnetic contaminants in raw materials that have been landed and are moved on an in-machine conveyor are attracted and separated by the separator, the separator is of a suspended type and is installed suspended close to the upper surface of the in-machine conveyor. In addition, the radiator and the forced circulation device are installed at different positions in the unloader body apart from the separator, and the radiator is divided into two circuits, and the pump discharge side and the forced circulation device are separated from each other. An opening/closing control valve is provided between the circuit and one of the circuits to detect the temperature of the refrigerant in the circulation system and control the valve to open when the oil temperature is above a set temperature and close when the oil temperature is below the installation temperature,
A magnetic separation device for an unloader, characterized in that these are connected by a conduit.