KR20140004821A - Separating system for a outer shell of generator rotator and method thereof - Google Patents

Abstract

The present invention relates to a system and a method for separating an outer cylinder of a generator rotor, which has an opening part at the lower part of a body of an outer cylinder vehicle of a rotor and uses a dual rail system comprising a vehicle moving rail for moving the outer cylinder vehicle of a rotor and a cylindrical jig vehicle and an assistant vehicle moving rail for moving an assistant vehicle for utilizing the assistant vehicle passing through the opening part, thereby preventing a deflection of the cylindrical jig and a shaft, shortening the time for separating the outer cylinder of the rotor by enabling smooth movement of the outer cylinder of the rotor, maximizing the space usage of a worker, and guaranteeing the safety of the worker.

Description

Separating system for a outer shell of generator rotator and method

The present invention relates to an outer cylinder separating system and a separating method of a generator rotor, and more particularly, an auxiliary bogie that can pass through a bogie moving rail and an opening, which is dually installed with an opening formed in a lower portion of the rotor outer cylinder bogie. The present invention relates to a generator rotor outer cylinder separation system and a separation method capable of preventing sagging of the cylindrical jig and shortening the rotor outer cylinder separation operation time.

In general, a generator usually consists of a stator, a rotor, a bearing, an exciter, and the like. The rotor means a part of the generator that rotates, and the stationary part is called a stator. Typically the rotor consists of the inner cylinder of the rotor and the outer cylinder of the rotor. Separating the inner and outer cylinders of the rotor from the generator is frequently performed for regular internal inspection or maintenance of the generator or for repairs due to accidental failure. In the case of a small generator, the rotor, which is one of its components, is also small, and there is no great difficulty in separating the outer and inner cylinders of the rotor. However, in the case of a large generator, the rotor, which is one of its components, is also large, and the weight of the outer cylinder or the inner cylinder of the rotor is usually several tons to several tens of tons, so there are many difficulties in separating them. Moreover, in the case of superconducting generators that are being developed a lot today, it is necessary to separate the rotor inner and outer cylinders.

Figure 1 shows a system for separating the outer cylinder of the conventional superconducting generator rotor, Figure 2 shows a state in which the rotor outer cylinder is separated in the rotor outer cylinder separation system of FIG. 1 and 2, the system for separating the outer cylinder of the conventional superconducting generator rotor is a rotor 100, a rotor fixing support 130, a bogie moving rail 200, a shaft 150, a cylindrical The jig 160, the cylindrical jig support belt 161, the rotor inner cylinder support belt 131, the rotor outer cylinder bogie 140, the cylindrical jig bogie 170, and the deflection amount correcting means 105. The rotor 100 of the superconducting generator constitutes a part of the generator. The rotor 100 is composed of a rotor inner cylinder 120 and a rotor outer cylinder 110 surrounding the rotor inner cylinder 120. The rotor 100 of the outer cylinder separation system of the conventional superconducting generator rotor is fixed support to the rotor fixed support 130, this rotor fixed support 130 was not movable. Accordingly, as the work space is limited, the rotor installation work and the rotor outer cylinder separation work are inconvenient, and the work time increases. The balance moving rail 200 is installed on the ground in parallel along the longitudinal direction of the rotor 100. The shaft 150 is inserted into the groove of the rotor 100 fixed to the rotor fixing support 130. The cylindrical jig 160 has a hollow therein to accommodate the shaft 150 therein, and supports the rotor outer cylinder 110 together with the shaft 150 when the rotor outer cylinder 110 is separated. Play a role. A cylindrical jig support belt 161 is coupled to one end of the cylindrical jig 160 to support the cylindrical jig 160. The rotor barrel bogie 140 is installed on the bogie moving rail 200 to be movable along the bogie moving rail 200. The rotor outer cylinder bogie 140 serves to support the rotor outer cylinder 110 and move the rotor outer cylinder 110 when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120. The cylindrical jig bogie 170 is installed on the bogie moving rail 200 to be movable along the bogie moving rail 200. The cylindrical jig bogie 170 supports the cylindrical jig 160 when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120, and serves to move the cylindrical jig 160.

The outer cylinder separating system of the generator rotor according to the prior art is the shaft 150 and the cylindrical jig 160 by the self load of the rotor outer cylinder 110 when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120. ) Will cause sag. When the cylindrical jig 160 and the shaft 150 sag, scratches and deformations are generated on the surface of the rotor outer cylinder 110 to reduce the production efficiency and power generation efficiency of the generator, and cause safety problems. There is a problem. Accordingly, in the conventional rotor outer cylinder separation system, the deflection amount of the cylindrical jig 160 by stacking the deflection amount correction means 105 on the upper portion of the cylindrical jig bogie 170 to correct the deflection amount of the cylindrical jig 160 and the shaft 150. Was corrected. In general, wood jig was used as the deflection correction means 105. However, as all operations of the conventional deflection correction work are performed by hand, there is a difficulty in correcting the deflection amount of the shaft and the cylindrical jig. In addition, there is a problem in that excessive working time is required because the moving distance that the rotor outer cylinder can move at one time is limited in order to minimize breakage of the rotor outer cylinder due to sag. In the conventional rotor casing separation system, it took an average of 4 hours or more to separate the rotor casing.

In addition, in the case of a conventional rotor outer cylinder separation system, the rotor inner cylinder 120 in which separation is in progress according to the movement of the rotor outer cylinder is supported by the rotor inner cylinder support belt 121. However, the cylindrical jig support belt 161 or the rotor inner cylinder support belt 121 may be shaken during the movement of the rotor outer cylinder, and the cylindrical jig or rotor inner belt may be loosened or broken by such shaking. there was. If the support belt is broken, it may threaten the safety of the worker working in the space, which may lead to human accidents, and the shaking may cause the deformation of the cylindrical jig or shaft more rapidly, which may seriously damage the rotor cylinder. There was a problem.

Moreover, the rotor outer cylinder separation system according to the prior art has a narrow working space according to the limited moving distance of the rotor outer cylinder, causing inconvenience to the operator, reducing the efficiency of the work, and increasing the cost of repairing and replacing the rotor. There was a problem letting.

The present invention is to solve the above problems, the present invention forms an opening in the lower portion of the body portion of the rotor barrel bogie, in order to utilize the auxiliary bogie that can move through the opening, the rotor barrel bogie Bogie moving rails that can move the cylindrical jig bogie and auxiliary bogie moving rails that can move the secondary bogie through the double rail system to prevent sagging of the cylindrical jig and shaft, and smooth the movement of the rotor barrel It is an object of the present invention to provide a generator rotor outer cylinder separation system and a separation method capable of shortening the separation work time, maximizing the operator's space utilization, and ensuring worker safety.

In order to achieve the object of the present invention, the outer cylinder separating system of the generator rotor according to the present invention is installed on a part of the generator, and the rotor inner cylinder 110 surrounding the rotor inner cylinder 120 and the rotor inner cylinder 120. Rotor 100 composed of; A rotor fixing support (130) for fixing and supporting the rotor (100); A pair of trolley moving rails 200 having a groove 201 therein and installed in the ground along the longitudinal direction of the rotor 100 in parallel with each other; A shaft 150 inserted into a groove of the rotor 100; A cylindrical jig 160 having a hollow to accommodate the shaft 150 therein and supporting the rotor outer cylinder 110; A cylindrical jig support belt 161 coupled to one end of the cylindrical jig 160 to support the cylindrical jig 160; When the rotor outer cylinder 110 is separated from the rotor inner cylinder 120, the balance moving rail 200 supports the rotor outer cylinder 110 and is movable along the balance moving rail 200. Rotor outer cylinder 140 installed on the; And the bogie moving rail 200 to support the cylindrical jig 160 and to move along the bogie moving rail 200 when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120. In the outer cylinder separation system of the generator rotor having a cylindrical jig bogie (170) installed on the support, to support the rotor fixing support 100, the bogie to move along the bogie moving rail (200) A rotor fixing support trolley 131 installed on the moving rail 200; A pair of grooves 211 provided therein and installed in the ground between the pair of trolley moving rails 200 along the longitudinal direction of the rotor 100 in parallel with the trolley moving rails 200. Auxiliary bogie moving rail 210; A first auxiliary bogie (180) installed on the auxiliary bogie moving rail (210) to be movable along the auxiliary bogie moving rail (210) and supporting the rotor inner cylinder (120); And a second auxiliary bogie 190 installed on the auxiliary bogie moving rail 210 to be movable along the auxiliary bogie moving rail 210 and for supporting the rotor inner cylinder 120. The rotor outer cylinder bogie 140 is movable through the rotor outer cylinder bogie 140 along the subsidiary bogie moving rail 210 by the first subsidiary bogie 180 or the second subsidiary bogie 190. It is characterized in that the opening provided in the lower portion of the body portion 141.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the rotor barrel bogie 140, the rotor outer cylinder, so that the height can be adjusted according to the size of the rotor outer cylinder (110). A hydraulic cylinder 142 installed on an upper portion of the body 141 of the bogie; A gripper 143 installed on an upper portion of the hydraulic cylinder 142 and for holding the rotor outer cylinder 110; And a wheel 144 installed at a lower portion of the body portion 141 of the rotor outer cylinder bogie and seated in the groove 201 of the bogie moving rail.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the gripper 143 of the rotor barrel bogie 140 is formed of an elastic member in contact with the rotor outer cylinder 110 The support 145 may be further provided.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the cylindrical jig bogie 170, the cylindrical jig bogie (to allow height adjustment according to the size of the cylindrical jig 160) Hydraulic cylinder is installed on the upper portion of the body portion 170; A gripper installed at an upper portion of the hydraulic cylinder and for holding the cylindrical jig 160; The wheel is installed in the lower portion of the body of the cylindrical jig bogie 170, the wheel can be seated in the groove 201 of the bogie moving rail;

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the gripper of the cylindrical jig bogie 170 further includes a support portion formed of an elastic member in contact with the cylindrical jig 160. can do.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the first auxiliary bogie 180, the first auxiliary so that the height can be adjusted according to the size of the rotor inner cylinder (120). A hydraulic cylinder installed on an upper portion of the body of the trolley 180; a gripper installed on an upper portion of the hydraulic cylinder and for holding the rotor inner cylinder 120; The wheel may be installed below the body of the first subsidiary bogie 180 and may be seated in the groove 211 of the subsidiary bogie moving rail.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the second auxiliary bogie 190, the second auxiliary so that the height can be adjusted according to the size of the rotor inner cylinder (120) A hydraulic cylinder installed at an upper portion of the body of the trolley 190; a gripper installed at an upper portion of the hydraulic cylinder and for holding the rotor inner cylinder 120; And a wheel installed at a lower portion of the body of the second subsidiary bogie 190 and seated in the groove 211 of the sub bogie moving rail.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the gripper of the first auxiliary bogie 180 and the gripper of the second auxiliary bogie 180 are in contact with the rotor inner cylinder 120. It may further include a support formed of an elastic member.

In addition, in another preferred embodiment of the outer cylinder separation system of the generator rotor according to the present invention, the rotor fixed support bogie 131 prevents the movement of the rotor fixed support bogie 131 on the bogie moving rail 200. Fixing means that can be further provided.

In order to achieve another object of the present invention, the outer cylinder separating method of the generator rotor according to the present invention, after the rotor 100 is fixed to the rotor fixing support 130, is installed on the bogie moving rail 200 Fixing the electronic fixed support trolley (131) so as not to move in the trolley moving rail (200) (S1); Supporting the rotor outer cylinder 110 of the rotor 100 by moving the rotor outer cylinder bogie 140 movably installed on the trolley moving rail 200 (S2); Inserting the shaft (150) through the groove formed in the rotor (S3); Inserting the shaft 150 into a cylindrical jig 160 having one end supported by a cylindrical jig support belt 161 (S4); Supporting the cylindrical jig 160 by moving the cylindrical jig trolley 170 movably installed on the trolley moving rail 200 (S5); Moving the rotor outer cylinder bogie 140 and the cylindrical jig bogie 170 to separate the rotor outer cylinder 110 from the rotor inner cylinder 120 (S6); Supporting the rotor inner cylinder (120) with a first auxiliary bogie (180) movably installed on an auxiliary bogie moving rail (210) (S7); After moving the second auxiliary bogie 190 movably installed on the auxiliary bogie moving rail 210 to pass through the rotor outer cylinder bogie 140 being moved on the bogie moving rail 200, the second second bogie 190 is moved. Additionally supporting the rotor inner cylinder (120) with an auxiliary bogie (S8); And separating the shaft 150 from the cylindrical jig 160 after the rotor inner cylinder 120 and the rotor outer cylinder 110 are completely separated (S9).

The present invention has the effect of accurately correcting the amount of deflection of the cylindrical jig and shaft at the time of separating the outer rotor of the generator rotor to minimize the damage occurring on the outer surface of the rotor.

In addition, the present invention can quickly correct the amount of deflection of the cylindrical jig and shaft by the hydraulic cylinder or the like at the time of separating the outer cylinder of the generator rotor, it is possible to significantly reduce the rotor outer cylinder separation work time, thereby improving product productivity efficiency There is an effect to improve.

Furthermore, the present invention supports the rotor outer cylinder, the rotor inner cylinder, the cylindrical jig, the rotor fixing support by the rotor outer cylinder bogie, auxiliary bogie, cylindrical jig bogie, and rotor fixed support bogie, thereby ensuring the safety of the worker and working. It is effective to maximize space efficiency.

1 shows a system for separating the outer cylinder of a conventional superconducting generator rotor.
FIG. 2 shows a state in which the rotor outer cylinder is being separated in the rotor outer cylinder separating system of FIG. 1.
Figure 3 shows the outer cylinder separation system of the generator rotor according to the present invention.
4A to 4C show a perspective view, a front view, and a side view of the rotor outer cylinder bogie according to the present invention.
5A and 5B show a perspective view of an auxiliary bogie according to the present invention and a state in which the auxiliary bogie passes the rotor outer cylinder bogie.
6A to 6C show a perspective view, a plan view, and a side view of a bogie moving rail and an auxiliary bogie moving rail according to the present invention.
7 to 8 show a state in which the separation of the rotor outer cylinder is in progress in the outer cylinder separation system of the generator rotor according to the present invention.
Figure 9 shows a state in which the rotor outer cylinder is completely separated in the outer cylinder separation system of the generator rotor according to the present invention.
10 shows a procedure of the generator rotor outer cylinder separation method according to the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to components of each drawing, the same components are designated by the same reference numerals.

3 shows an outer cylinder separation system 10 of a generator rotor according to the present invention. 4A to 4C show a perspective view, a front view, and a side view of the rotor outer cylinder bogie 140 according to the present invention. 5A and 5B show a perspective view of the subsidiary bogies 180 and 190 and the state in which the subsidiary bogies 180 and 190 pass through the rotor outer cylinder bogie 140. 6A to 6C show a perspective view, a plan view, and a side view of the bogie moving rail 200 and the auxiliary bogie moving rail 210 according to the present invention. 7 to 8 show a state that the separation of the rotor outer cylinder is in progress in the outer cylinder separation system 10 of the generator rotor according to the present invention. 9 shows a state in which the rotor outer cylinder is completely separated from the outer cylinder separation system 10 of the generator rotor according to the present invention.

The outer cylinder separation system 10 of the generator rotor according to the preferred embodiment of the present invention, the rotor 100, the rotor fixing support 130, the bogie moving rail 200, the shaft 150, cylindrical jig 160 , Cylindrical jig support belt 161, rotor outer cylinder bogie 140, cylindrical jig bogie 170, rotor fixed support bogie 131, auxiliary bogie moving rail 210, the first auxiliary bogie 180, and The second subsidiary bogie 190 is formed.

3 and 7 to 9, the rotor 100 is composed of a rotor inner cylinder 120 and a rotor outer cylinder 110 surrounding the rotor inner cylinder 120, installed in a part of the generator do. Although not necessarily limited thereto, the generator in the outer cylinder separation system 10 of the generator rotor according to a preferred embodiment of the present invention is made of a superconducting generator. The rotor fixing support 130 fixes and supports the rotor 100.

The outer cylinder separating system 10 of the generator rotor according to the present invention further includes a rotor fixed support bogie 131 installed on the bogie moving rail 200 to be movable along the bogie moving rail. The rotor fixing support trolley 131 is fixed to the rotor fixing support 130, and can move along the trolley moving rail 200, the operation occurs in the state that the rotor fixing support 130 is fixed Solving the problem of limited space, there is an effect that can maximize the utilization of the workspace. The rotor fixing support trolley 131 according to another preferred embodiment of the present invention further includes a fixing means capable of preventing the movement of the rotor fixing support trolley 131 on the trolley moving rail 200. The rotor fixing support bogie 131 is the bogie during the operation of fixing the rotor 100 to the rotor fixing support 130 and the rotor fixing support bogie 131 by the fixing means of the rotor fixing support bogie 131. By preventing the movement along the moving rail 200 to prevent human accidents in advance, it is possible to shorten the working time.

The balance moving rail 200 is installed on the ground in parallel along the longitudinal direction of the rotor 100. As shown in FIGS. 6A-6C, the bogie moving rail 200 accommodates wheels provided in the rotor fixed support bogie 131, the rotor barrel bogie 140, and the cylindrical jig bogie 170. A groove 201 is provided therein to be movable through the wheel. Although not necessarily limited thereto, the balance moving rail 200 provided in the separation system of the generator rotor according to the preferred embodiment of the present invention may have a counterclockwise "C" shape when viewed from the side, as shown in FIG. 6C. It is formed in a shape rotated 90 degrees in the reverberation.

As shown in FIGS. 6A to 6C, the auxiliary bogie moving rail 210 accommodates the wheels provided in the first auxiliary bogie 180 and the second auxiliary bogie 190 and moves therein so as to be movable through these wheels. The groove 211 is provided. The auxiliary bogie moving rail 210 is installed on the ground between the pair of bogie moving rails 200 along the longitudinal direction of the rotor 100 in parallel with the bogie moving rail 200. The first auxiliary bogie 180 or the second auxiliary bogie 190 is the rotor outer cylinder 140 by a double rail system formed of the bogie moving rail 200 and the auxiliary bogie moving rail 210. By freely moving through it, it is possible to reduce the separation work time of the rotor outer cylinder, and maximize the utilization of the operator's work space.

The shaft 150 is inserted into the groove of the rotor 100 fixed to the rotor fixing support 130 and the rotor fixing support trolley 131.

The cylindrical jig 160 has a hollow therein to accommodate the shaft 150 therein, and supports the rotor outer cylinder 110 together with the shaft 150 when the rotor outer cylinder 110 is separated. Play a role. In the preferred embodiment of the present invention, the cylindrical jig 160 and the shaft 150 are formed in a cylindrical shape, but are not necessarily limited thereto, and the shapes of the shaft and the cylindrical jig may be changed as necessary.

The cylindrical jig support belt 161 is coupled to one end of the cylindrical jig 160 to support the cylindrical jig 160.

The rotor outer cylinder bogie 140 is installed on the bogie moving rail 200 to be movable along the bogie moving rail 200. The rotor outer cylinder bogie 140 serves to support the rotor outer cylinder 110 and move the rotor outer cylinder 110 when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120.

The cylindrical jig bogie 170 is installed on the bogie moving rail 200 to be movable along the bogie moving rail 200. The cylindrical jig bogie 170 supports the cylindrical jig 160 when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120, and serves to move the cylindrical jig 160.

When the first sub-bogie 180 is installed on the sub-bogie moving rail 210 so as to be movable along the sub-bogie moving rail 210, and when the rotor outer cylinder 110 is separated from the rotor inner cylinder 120. , And serves to support the rotor inner cylinder (120).

The secondary bogie 190 is installed on the secondary bogie moving rail 210 so that the secondary bogie 190 is movable along the secondary bogie moving rail 210, and the rotor outer cylinder 110 is substantially separated from the rotor inner cylinder 120. When, the rotor serves to support the inner cylinder (120). 3 and 7, according to a preferred embodiment of the present invention, according to the space constraints such as the size of the rotor barrel bogie 140 and the rotor fixed support bogie 131 The second auxiliary bogie 190 is a cylindrical jig bogie 170 before the rotor outer cylinder 110 is significantly separated from the rotor inner cylinder 120 before the rotor outer cylinder 110 is separated from the rotor inner cylinder 120. And the rotor outer cylinder bogie 130, are located on the auxiliary bogie rail 210.

As shown in Figures 4a to 4c, the rotor outer cylinder bogie 140 according to a preferred embodiment of the present invention is the first secondary bogie 180 or the second secondary bogie 190 is the secondary bogie moving rail 210 An opening is provided in the lower portion of the body portion 141 to move through the rotor outer cylinder bogie 140 along.

As shown in FIGS. 8 and 9, the rotor outer cylinder 110 is substantially separated from the rotor inner cylinder 120 or the rotor outer cylinder 110 is completely separated from the rotor inner cylinder 120. Passing through the opening portion formed in the body portion 141 of the outer cylinder bogie 140, and moves along the auxiliary bogie moving rail 210 to support the rotor inner cylinder 120. As the second auxiliary bogie 190 additionally supports the rotor inner cylinder 120, the deflection deformation of the shaft 150 and the cylindrical jig 160 can be minimized, thereby reducing the work time and the rotor. It is possible to prevent the damage generated in the outer cylinder (110).

As shown in Figures 4a to 4c and 5a to 5c, according to a preferred embodiment of the present invention, the rotor barrel bogie 140 is the body portion 141, the hydraulic cylinder 142, the gripper 143 , The wheel 144 is made. Body portion 141 forming the overall appearance of the rotor barrel bogie 140, the first secondary bogie 180 or the second secondary bogie 190 is the rotor bogie bogie 140 along the secondary bogie rail 210 An opening is provided in the lower portion so as to move through it. The hydraulic cylinder 142 is installed on the upper portion of the body portion 141, the height can be adjusted according to the size of the rotor outer cylinder 110 by the hydraulic pressure. As the height can be easily adjusted by hydraulic pressure, the working time is shortened by simultaneously correcting the deflection deformation of the cylindrical jig 160 and the shaft 150 generated according to the moving distance of the rotor outer cylinder 110, and the rotor outer cylinder. Damage to the 110 can be prevented. A gripper 143 is installed on the upper portion of the hydraulic cylinder 142 to grip the rotor outer cylinder 110. The wheel 144 is installed below the body portion 141 of the rotor outer cylinder bogie, and seated in the groove 201 of the bogie moving rail, so that the rotor outer cylinder bogie 140 moves quickly along the bogie moving rail 200. Make it possible.

According to another preferred embodiment of the present invention, the gripper 143 of the rotor outer cylinder bogie 140 further includes a support portion 145 formed of an elastic member in contact with the rotor outer cylinder 110. Accordingly, damage or scratches that may occur due to friction when the rotor outer cylinder 140 moves in the contact portion between the rotor outer cylinder 140 and the gripper 143 may be minimized. Although not necessarily limited thereto, the support 145 is formed of an elastic body such as rubber.

According to a preferred embodiment of the present invention, the cylindrical jig bogie 170, the first auxiliary bogie 180, the second auxiliary bogie 190 are all provided with a body portion forming an overall appearance, and is installed on the upper portion of the body portion According to the size and deformation of the cylindrical jig 160 or the rotor inner cylinder 120 is provided with a hydraulic cylinder capable of height adjustment by the hydraulic pressure. In addition, a gripper for gripping the cylindrical jig 160 or the rotor inner cylinder 120 is installed above the hydraulic cylinder. The cylindrical jig bogie 170 has wheels seated in the groove 201 of the bogie moving rail at the bottom of the body portion, and the first auxiliary bogie 180 and the second auxiliary bogie 190 move the auxiliary bogie at the bottom of the body portion. The wheel is provided in the groove 211 of the rail.

Further, according to another preferred embodiment of the present invention, the cylindrical jig bogie 170, the first auxiliary bogie 180, and the second auxiliary bogie 190 are cylindrical jigs 170 or times on top of each gripper. A support part formed of an elastic member is provided at a portion in contact with the electron inner cylinder 120, thereby preventing damage to the cylindrical jig or the rotor inner cylinder.

Although not necessarily limited thereto, the cylindrical jig bogie 170, the first auxiliary bogie 180, and the second auxiliary bogie 190 are structurally different from the rotor outer cylinder bogie 140 only in that they do not have a lower opening of the body portion. There is a difference, and the remaining components are made identical. If necessary, the cylindrical jig bogie 170, the first auxiliary bogie 180, and the second auxiliary bogie 190 may also include a lower opening of the body portion.

10 shows a procedure of the generator rotor outer cylinder separation method according to the present invention. As shown in Figure 10, the method for separating the rotor outer cylinder using the rotor outer cylinder separation system 10 according to the present invention is to secure the rotor (S1), the rotor outer cylinder to support the rotor outer cylinder Step (S2), inserting the shaft into the rotor (S3), inserting the shaft into the cylindrical jig (S4), separating the rotor outer cylinder and the rotor inner cylinder (S5), the first auxiliary bogie The step (S7) of supporting the rotor inner cylinder, the step (S8) of supporting the rotor inner cylinder with the second auxiliary bogie and the step of separating the shaft and the cylindrical jig (S9).

First, the rotor 100 is fixed to the rotor fixing support 130. Then, the rotor fixing support trolley 131 provided on the trolley | bogie moving rail 200 is fixed so that it may not move on the trolley | bogie moving rail 200. FIG. After fixing the rotor, the rotor outer cylinder bogie 140 movably installed on the bogie moving rail 200 is moved to support the rotor outer cylinder 110 of the rotor 100. Thereafter, the shaft is inserted through the groove formed in the rotor 100. After the shaft is inserted, the shaft 150 is inserted into the cylindrical jig 160 having one end supported by the cylindrical jig support belt 161. After the shaft is inserted into the cylindrical jig, the cylindrical jig bogie 170 movably installed on the trolley moving rail 200 is moved to support the cylindrical jig 160. Thereafter, the rotor outer cylinder bogie 140 and the cylindrical jig bogie 170 are moved at the same time to separate the rotor outer cylinder 110 from the rotor inner cylinder 120. When the rotor outer cylinder 110 is partially separated from the rotor inner cylinder 120, the rotor inner cylinder 120 is supported by the first auxiliary bogie 180 movably installed on the auxiliary bogie moving rail 210. After the rotor outer cylinder 110 is substantially separated from the rotor inner cylinder 120, the second auxiliary bogie 190 movably installed on the auxiliary bogie moving rail 210 is being moved on the bogie moving rail 200. By moving through the opening formed in the body portion of the rotor outer cylinder bogie 140, the rotor inner cylinder 120 is further supported by the second auxiliary bogie 190. After the rotor inner cylinder 120 and the rotor outer cylinder 110 are completely separated, the outer cylinder separation operation of the generator rotor is completed by separating the shaft 150 and the cylindrical jig 160.

The present invention is not limited to the modifications shown in the drawings and the embodiments described above, but may be extended to other embodiments falling within the scope of the appended claims.

10: separation system, 100: rotor,
105: deflection correction means, 110: rotor outer cylinder,
120: rotor inner cylinder, 121: rotor inner cylinder support belt,
130: rotor fixing support, 131: rotor fixing support bogie,
140: rotor outer cylinder bogie, 141: rotor outer cylinder bogie,
142: hydraulic cylinder, 143: gripper,
143: wheels, 144: support,
150: shaft,
160: cylindrical jig, 161: cylindrical jig support belt,
170: cylindrical jig bogie, 180: first auxiliary bogie,
190: the second auxiliary bogie,
200: bogie moving rail, 201: groove,
210: secondary bogie moving rail, 211: groove.

Claims (11)

A rotor (100) installed in a part of the generator and configured of a rotor inner cylinder (120) and a rotor outer cylinder (110) surrounding the rotor inner cylinder (120);
A rotor fixing support (130) for fixing and supporting the rotor (100);
A pair of trolley moving rails 200 having a groove 201 therein and installed in the ground along the longitudinal direction of the rotor 100 in parallel with each other;
A shaft 150 inserted into a groove of the rotor 100;
A cylindrical jig 160 having a hollow to accommodate the shaft 150 therein and supporting the rotor outer cylinder 110;
A cylindrical jig support belt 161 coupled to one end of the cylindrical jig 160 to support the cylindrical jig 160;
When the rotor outer cylinder 110 is separated from the rotor inner cylinder 120, the balance moving rail 200 supports the rotor outer cylinder 110 and is movable along the balance moving rail 200. Rotor outer cylinder 140 installed on the; And
When the rotor outer cylinder 110 is separated from the rotor inner cylinder 120, the cylindrical jig 160 supports and moves on the balance moving rail 200 to be movable along the balance moving rail 200. In the cylindrical cylinder separation system of the generator rotor having a; jig bogie 170 is installed in,
A rotor fixing support trolley 131 supporting the rotor fixing support 100 and installed on the trolley moving rail 200 to be movable along the trolley moving rail 200;
A pair of grooves 211 provided therein and installed in the ground between the pair of trolley moving rails 200 along the longitudinal direction of the rotor 100 in parallel with the trolley moving rails 200. Auxiliary bogie moving rail 210;
A first auxiliary bogie (180) installed on the auxiliary bogie moving rail (210) to be movable along the auxiliary bogie moving rail (210) and supporting the rotor inner cylinder (120); And
And a second auxiliary bogie 190 installed on the auxiliary bogie moving rail 210 so as to be movable along the auxiliary bogie moving rail 210 and for supporting the rotor inner cylinder 120.
The rotor outer cylinder bogie 140 is movable through the rotor outer cylinder bogie 140 along the subsidiary bogie moving rail 210 by the first subsidiary bogie 180 or the second subsidiary bogie 190. The outer cylinder separating system of the generator rotor, characterized in that provided with an opening in the lower portion of the body portion (141).
The method of claim 1,
The rotor outer cylinder bogie 140,
A hydraulic cylinder 142 installed on an upper portion of the body portion 141 of the rotor outer cylinder bogie so that height can be adjusted according to the size of the rotor outer cylinder 110;
A gripper 143 installed on an upper portion of the hydraulic cylinder 142 and for holding the rotor outer cylinder 110;
The outer cylinder separating system of the generator rotor, characterized in that consisting of; a wheel (144) is installed in the lower portion of the rotor outer cylinder bogie (141), and seated in the groove (201) of the bogie moving rail.
3. The method of claim 2,
The gripper 143 of the rotor barrel bogie 140 further includes a support part 145 formed of an elastic member in contact with the rotor barrel 110. system.
3. The method of claim 2,
The cylindrical jig bogie 170,
A hydraulic cylinder installed on an upper portion of the body of the cylindrical jig bogie 170 to enable height adjustment according to the size of the cylindrical jig 160;
A gripper installed at an upper portion of the hydraulic cylinder and for holding the cylindrical jig 160;
The outer cylinder separation system of the generator rotor, characterized in that consisting of; wheels are installed in the lower body portion of the cylindrical jig bogie 170, the wheels seated in the groove 201 of the bogie moving rail.
5. The method of claim 4,
The gripper of the cylindrical jig bogie 170 further comprises a support part formed of an elastic member at a portion in contact with the cylindrical jig 160, the outer cylinder separation system of the generator rotor.
3. The method of claim 2,
The first auxiliary cart 180,
A hydraulic cylinder installed on an upper portion of the body of the first auxiliary bogie 180 to enable height adjustment according to the size of the rotor inner cylinder 120;
A gripper installed at an upper portion of the hydraulic cylinder and configured to grip the rotor inner cylinder 120;
The outer cylinder separating system of the generator rotor, characterized in that consisting of; the wheel is installed on the lower portion of the body portion of the first subsidiary bogie (180), and seated in the groove (211) of the sub bogie moving rail. The method according to claim 6,
The gripper of the first auxiliary cart 180 further includes a support part formed of an elastic member at a portion in contact with the rotor inner cylinder 120, the outer cylinder separating system of the generator rotor.
3. The method of claim 2,
The second auxiliary cart 190,
A hydraulic cylinder installed on an upper portion of the body of the second auxiliary bogie 190 to enable height adjustment according to the size of the rotor inner cylinder 120;
A gripper installed at an upper portion of the hydraulic cylinder and configured to grip the rotor inner cylinder 120;
The outer cylinder separating system of the generator rotor, characterized in that consisting of; the wheel is installed on the lower portion of the body portion of the second subsidiary bogie (190), and seated in the groove (211) of the sub bogie moving rail.
9. The method of claim 8,
The gripper of the second auxiliary bogie 190 further includes a support part formed of an elastic member at a portion in contact with the rotor inner cylinder 120, the outer cylinder separation system of the generator rotor.
3. The method of claim 2,
The rotor fixed support trolley 131 further comprises a fixing means for preventing the movement of the rotor fixed support trolley 131 on the trolley moving rail 200, characterized in that the outer cylinder of the generator rotor Separation system.
After the rotor 100 is fixed to the rotor fixing support 130, the rotor fixing support trolley 131 installed on the trolley moving rail 200 is fixed so as not to move in the trolley moving rail 200 ( S1);
Supporting the rotor outer cylinder 110 of the rotor 100 by moving the rotor outer cylinder bogie 140 movably installed on the trolley moving rail 200 (S2);
Inserting the shaft (150) through the groove formed in the rotor (S3);
Inserting the shaft 150 into a cylindrical jig 160 having one end supported by a cylindrical jig support belt 161 (S4);
Supporting the cylindrical jig 160 by moving the cylindrical jig trolley 170 movably installed on the trolley moving rail 200 (S5);
Moving the rotor outer cylinder bogie 140 and the cylindrical jig bogie 170 to separate the rotor outer cylinder 110 from the rotor inner cylinder 120 (S6);
Supporting the rotor inner cylinder (120) with a first auxiliary bogie (180) movably installed on an auxiliary bogie moving rail (210) (S7);
After moving the second auxiliary bogie 190 movably installed on the auxiliary bogie moving rail 210 to pass through the rotor outer cylinder bogie 140 being moved on the bogie moving rail 200, the second second bogie 190 is moved. Additionally supporting the rotor inner cylinder (120) with an auxiliary bogie (S8); And
And separating the shaft 150 and the cylindrical jig 160 after the rotor inner cylinder 120 and the rotor outer cylinder 110 are completely separated (S9). How to separate the outer cylinder.

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