KR101251459B1 - (lifting system for turbine case - Google Patents

Abstract

PURPOSE: A lifting system for a turbine case is provided to prevent safety accidents and to protect equipment by preventing collision between blades of a turbine and an upper case because the upper case is efficiently lifted. CONSTITUTION: A lifting system for a turbine case comprises a crane(200), lifting grooves(13), initial starting parts(110), fastening sockets(120), and a safety supporting part(130). The crane is fastened to an upper case(10) of a turbine(1), and lifts the upper case. The lifting grooves are formed on flanges(11,21) of the upper case and a lower case(20) to face each other. Each initial starting part has a lifting bar(111) inserted into the lifting groove to initially lift the upper case with a hydraulic device. Each fastening socket is inserted and fixed in a fastening hole(12) of the flange of the upper case. A fastening screw hole is formed upward from the underside of the fastening socket. A locking piece(121) is formed downward from the front end of the flange of the fastening socket. The safety supporting part thread-couples a fastening screw of a guide body(131) to the fastening screw hole of the fastening socket. The length of the guide body is the same as the height of a safety position depending on the lifting of the upper case.

Description

Lifting system for turbine case

The present invention relates to a lifting system for a turbine case, and more particularly, to a lifting case for a turbine case that can safely and accurately remove the upper case of the turbine to protect the blades of the turbine.

In general, thermal power generation refers to the development of a method of converting thermal energy obtained by burning fossil fuels such as coal, oil, and gas into mechanical energy and converting it into electrical energy.

In the thermal power generation method, the water generated by burning fuel is heated to make steam, and then the steam is used to drive a steam turbine connected to the generator, and the generator is driven by an internal combustion engine such as a diesel engine. System and power generation system using a gas turbine as a prime mover.

The turbine installation of such a thermal power plant is a device that generates electricity by rotating a generator by converting thermal energy of the working medium into mechanical energy in a thermodynamic cycle using working steam or gas, and a steam turbine and a gas turbine are mainly used in a power plant.

A steam turbine is an engine that converts the thermal energy of high pressure steam into mechanical energy.The principle of operation is to accelerate and expand the steam flow by blowing and expanding the high temperature and high pressure steam produced in a boiler at a nozzle or a fixed vane, Recoil causes the rotating vanes to rotate and ultimately convert the rotating forces into electrical energy.

The gas turbine uses combustion gas instead of steam. It is a power generation facility that generates electricity by using combustion gas of fuel. For initial start-up, it must be supplied with external power or have a separate self-starting facility. It becomes possible.

Such power generation equipment is usually rotated by the rotational force of the turbine to produce power.

In other words, as the rotary shaft of the power plant is connected to the turbine shaft, as the turbine shaft rotates, the power shaft of the power plant is rotated to produce power.

At this time, the turbine shaft is rotated by the high-pressure steam bar, by adjusting the steam inflow of a constant pressure supplied to the turbine to maintain the rotation of the turbine shaft to the rated rotational speed to produce electricity.

On the other hand, if the rotation of the power plant turbine exceeds the rated rotation speed, and the rotation speed is excessive, vibration may spread and serious damage may occur to the power plant itself. It has been kept within speed.

However, such a conventional power plant turbine has been frequently dismantled in order to maximize efficiency by grasping preventive maintenance, identifying problems caused by output improvement or output degradation, and performing abnormality measurement and inspection of each part. Therefore, when lifting or placing it after checking, the inner periphery of the upper case often hits the blade of the inner turbine, which causes a high risk of safety accident.

In particular, the hoist of the shape and the center of gravity of the upper case is not only deepened, but in fact, the gap between the upper case and the blade is only 2.5 ~ 3.5mm, so there is a problem that easily bumps even a little shaking.

Therefore, the main object of the present invention is to provide a turbine case lifting system for a turbine case that can be safely lifted or recombined without shaking the turbine case of the power generation equipment to prevent a safety accident.

Lifting system for a turbine case of the present invention to achieve the above object is a crane coupled to the upper case of the turbine lifting; A lifting groove formed to face the flange of the upper case and the lower case to which the crane is fastened; An initial starting unit having a lifting bar inserted into the lifting groove to initially lift the upper case by a hydraulic apparatus; A fastening socket inserted into a fastening ball formed on a flange of the upper case to prevent it; And a safety support that couples the guide body to the fastening socket but passes through the fastening ball of the lower case, and forms a guide body downwardly to form a height of the safe position.

Therefore, the lifting system for the turbine case of the present invention inserts a lifting bar into the lifting groove so that the hydraulic system and the crane can be operated simultaneously at the same time so that the upper case can be safely started and lifted. In addition, the guide body of the safety support screwed to the fastening socket is lifted together along the lifting of the upper case while restricting the movement of the front, rear, left and right, thus preventing the occurrence of shaking during the lifting of the upper case. At the same time, it guides the safety position accurately while maintaining the balance. As the guide body of the safety support guides continuously and safely and accurately as described above, the upper case can be efficiently lifted and thus the top of the turbine blade It prevents the collision of the sub-case to protect the device and to suppress the occurrence of safety accidents.

1 is a perspective view showing an installation state of a lifting system for a turbine case according to the present invention.
2 is a perspective view showing an initial lifting state of the lifting system for a turbine case according to the present invention.
3 is a perspective view showing a safe lifting state of the lifting system for a turbine case according to the present invention.
Figure 4 is a perspective view showing a complete lifting state of the lifting system for a turbine case according to the present invention.
5 is a front view showing an installation state of the lifting system for a turbine case according to the present invention.
6 is a front view showing an initial lifting state of the lifting system for a turbine case according to the present invention.
7 is a front view showing a safe lifting state of the lifting system for a turbine case according to the present invention.
8 is an exploded perspective view showing the safety support of the lifting system for a turbine case according to the present invention.
9 is a cross-sectional view showing a deployed state of the safety support of the lifting system for a turbine case according to the present invention.
10 is an exploded view showing an initial lifting state of the lifting system for a turbine case according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 10, the turbine system lifting system 100 of the present invention includes a crane 200 for fastening to the upper case 10 of the turbine (1); Lifting grooves 13 and 23 formed to face the flanges 11 and 21 of the upper case 10 and the lower case 20 to which the crane 200 is fastened; An initial starting part (110) having a lifting bar (111) inserted into the lifting grooves (13, 23) to initially lift the upper case (20) with the hydraulic device (112); A fastening socket 120 inserted into and fastened to a fastening hole 12 formed in the flange 11 of the upper case 10; And a guide body 131 coupled to the fastening socket 120, but coupled by penetrating through the fastening hole 22 of the lower case 20, and forming the guide body 131 downward by a height of a safe position downward. It consists of a support 130.

The lifting grooves 13 and 23 face the lifting grooves 13 and 23 on the surfaces of the upper case 10 that face the flanges 11 and the flanges 21 of the lower case 20, respectively. It is preferable to form a long to facilitate the insertion of the lifting bar (111).

In addition, the lifting grooves 13 and 23 are preferably formed at four points of the upper case 10 in consideration of the center of gravity.

The initial starting unit 110 is provided with a lifting bar 111 to be inserted into the lifting grooves (13, 23), but the lifting bar 111 is formed in a pair of upper and lower lifting bar 111 is the upper case at the beginning of the lifting ( 10) Make sure the initial lifting safely.

The lifting bar 111 is ideally connected to the hydraulic device 112, but installed at the four points to lift at the same time.

The fastening socket 120 removes the bolts and nuts coupled to the flanges 11 of the upper case 10 and the fastening holes 12 and 22 of the flange 21 of the lower case 20 and removes the bolts and nuts. The flange 11 is fastened to the fastening hole 12 and inserted from the upper side to the lower side.

Furthermore, at the upper end of the fastening socket 120, the locking piece 121 is formed to be bent downward from the front end of the flange 11 to maintain the locking state, and thus the fastening hole 12 of the flange 11 of the upper case 10 is formed. At the same time to prevent the rotation of the fastening socket 120 is inserted into the) to be prevented from escaping to the bottom.

In addition, the fastening socket 120 is formed by drilling the fastening screw ball 122 from the bottom to the inner side.

The safety support 130 is screwed to the fastening screw 132 of the guide body 131 to the fastening screw ball 122 of the fastening socket 120, but is coupled through the fastening hole 22 of the lower case 20 do.

In addition, the guide body 131 of the safety support 130 is formed to extend downwards as long as the height of the safety position according to the lifting of the upper case 10, but the hexagonal head 133 is integrally formed at the bottom of the guide body ( 131 and the fastening socket 120 is preferably formed so that it can be quickly and easily performed.

Referring to the operation of the turbine case lifting system according to the present invention.

First, the upper and lower cases 10 and 20 of the turbine 1 are released, the upper case 10 is coupled to the crane 200, and the fastening socket 120 is flanged to the upper case 10. (11) Inserted into the fastening ball 12 to restrain.

At this time, the engaging piece 121 of the fastening socket 120 is caught in the front end of the flange 11 of the upper case 10, thereby preventing the rotation of the fastening socket 120 and escape to the bottom.

Here, the fastening screw 132 formed on the guide body 131 of the safety support part 130 to the fastening screw ball 122 of the fastening socket 120 is screwed to the four or more points of the upper case 10 as described above. Install.

Furthermore, the lifting bar 111 is inserted into the lifting grooves 13 and 23 formed at four points, and the crane 200 is operated to maintain a taut state.

In this state, the hydraulic device 112 and the crane 200 are operated at the same time to lift the upper case 10 slightly so as to initially start.

That is, the inner periphery of the upper case (10, 20) is the initial start safely in a very close state to the blade 30 to lift.

When the initial starting is completed, the upper case 10 is slowly lifted by the crane 200.

Here, the guide body 131 of the safety support part 130 screwed to the fastening socket 120 also rises along the front, rear, and left and right of the upper case 10. Therefore, the upper case 10 of the upper case 10 is restrained. This guides you to the safe position while suppressing shaking during lifting.

Next, when the upper case 10 is out of the safe position, the lifting operation is stopped and the guide body 131 head 133 of the safety support 130 is rotated in reverse to separate the fastening socket 120 and then the crane again. The 200 is driven to complete the lifting of the upper case 10.

Therefore, the guide body 131 of the safety support 130 is continuously safe, accurate and efficient lifting as described above to prevent the impact of the blade 30 of the turbine 10 and the upper case 10 to protect the device The occurrence of a safety accident can be suppressed.

On the other hand, when reassembling the upper case 10 proceeds in the reverse order of the above will be able to safely and accurately reassemble as described above.

1 turbine 10 upper case
11: flange 12: fastening ball
13: lifting groove 20: lower case
21: flange 22: fastening ball
23: lifting groove 30: blade
100: lifting system 110: initial start
111: lifting bar 112: hydraulic device
120: tightening socket 121: engaging piece
122: fastening screw ball 130: safety support
131: guide body 132: tightening screw
133 head 200 crane

Claims (3)

A crane 200 fastened to the upper case 10 of the turbine 1 for lifting;
Lifting grooves 13 and 23 formed to face the flanges 11 and 21 of the upper case 10 and the lower case 20 to which the crane 200 is fastened;
An initial starting part (110) having a lifting bar (111) inserted into the lifting grooves (13, 23) to initially lift the upper case (20) with the hydraulic device (112);
Inserted into the fastening hole 12 of the flange 11 of the upper case 10 to be fixed, but the fastening screw hole 122 from the bottom to the inner side and the locking piece located downward from the front end of the flange 11 on the top ( A fastening socket 120 having a 121; And
Screw the fastening screw 132 of the guide body 131 to the fastening screw ball 122 of the fastening socket 120, but is coupled through the fastening hole 22 of the lower case 20 and guide body 131 Lifting system for a turbine case, characterized in that consisting of the safety support portion 130 to form the length of the safety position according to the lifting of the upper case (10). delete delete

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