UA18634U - Assembly and testing rocket body - Google Patents

Abstract

The utility model relates to the rocket-space branch. An assembly and testing rocket body contains a floor, a wall with a roofing, a railroad track for assembly carts of the stages of rocket and a frame installed on the wall frame with points of attachment of upper stage. For increasing the operating characteristics the frame is fixed on the wall located in parallel to railroad track, and it is equipped with a power ring made of open section, on which are installed the points of attachment of upper stage. The longitudinal axis of frame is oriented perpendicularly to the said wall and is located on the same level with the axis of rocket.

Description

Description of the invention

The useful model refers to the rocket and space industry, and more specifically to ground construction and 2 can be used to ensure work with monoblock rockets in the process of their assembly.

The rocket assembly and test case is known, which contains the floor, walls with a roof and a railway track for the assembly trolleys of the rocket stages | see patent of Ukraine Mo52508A, IPC 864055/00, EO4Н5Б/О2, 2002.

To carry out horizontal assembly of medium-class rockets, stages are placed on assembly trolleys.

The docking of the lower stages (first and second stages) is performed and electrical tests of all 70 stages are carried out using adapter cables. A patent degree is used as the upper degree

of Ukraine Mo13022O), IPC 86405/00, g42815/00, 2005). The upper stage is attached to the assembly trolley with the help of support nodes: the front technological ring and a rigid half-ring mounted on the opposite side of the flange of the rear lath of the stage. The device compartment of the upper step is made in the form of a torus with a cover and is located around the upper end of the step. 19 In the process of electrical tests, malfunctions of the control system are revealed, to eliminate which it is necessary to remove the cover of the instrument compartment and replace the faulty device or remove the entire toroidal instrument compartment and install a new one. To perform these operations, the upper stage must be docked to the second stage and the assembly trolley moved away.

After electrical tests, the upper stage is transported to a refueling station for refueling with fuel components, and the dose of fuel components depends on the type of spacecraft. Then the upper stage is connected to the second stage.

The disadvantage of the well-known assembly and test case is its low operational quality due to the high labor-intensiveness of operations related to docking and undocking of the upper stage in conditions of difficult access to the fastening nodes of the upper stage for replacing faulty devices. 29 The closest to the proposed technical solution is the assembly and test case of the missile selected as a prototype, which is described in Ts(patent of Ukraine Mob4368A, IPC 864055/00, 2003. 4. The specified assembly and test case (MEC) contains a floor, walls with the roof, a railway track for mounting trolleys of rocket stages and a wall-mounted frame (truss) with rocket stage mounting nodes. The longitudinal axis of the frame is vertical and the assembly of a heavy-class "package" rocket is carried out on the frame. With 30 Canting of the rocket stages in a vertical position is carried out with the help of mounting carts and vertical body guides.

The disadvantage of the well-known MVKU is its poor operational qualities due to the high labor intensity of the operation ee, canting of the upper stage to replace faulty devices or the device compartment. Gee)

The basis of the useful model is the task of creating an improved design of the ICBM of the rocket, which would ensure the improvement of its operational qualities by introducing new elements and technical solutions into it, such as: - the frame is fixed on a wall located parallel to the railway track, which allows to reduce the labor intensity of the work with the upper stage, because the frame is located in close proximity to the rocket; " - the frame is equipped with a power ring, on which the fastening nodes of the upper stage are mounted, which Z 70 allows to provide the necessary rigidity, which prevents the rear frame of the upper stage from losing its shape during electrical tests or assembly work. In the future, this contributes to the preservation of the shape and the unhindered process of docking the stages of the rocket; - the power ring is made of an open profile, which allows for free access to the fastening nodes; 45 - the longitudinal axis of the frame is oriented perpendicularly to the specified wall, which allows you to use a mounting trolley of a simple design and rationally use the area of the case. If the longitudinal axis of the frame is not perpendicular to the wall (both in the horizontal and vertical planes), then the area of the body occupied by the frame will be larger, the smaller the angle between the longitudinal frame and the wall; b - the longitudinal axis of the frame is located at the same level as the longitudinal axis of the rocket, which allows

Ge) 20 use one assembly trolley both for connecting to the frame and for connecting the upper stage to the second stage; t" - the section of the floor with a section of the railway track is installed on a vertical shaft, which allows to ensure the turning of the assembly trolley with the upper stage both towards the rocket and towards the frame. In this way, a change in orientation is ensured without the use of a bridge crane, which increases the safety of work; - the vertical shaft is connected to the drive of its rotation, which allows to mechanize the process of rotation of the shaft; c - the longitudinal axis of the vertical shaft passes through the intersection of the longitudinal axes of the rocket and the frame, which makes it possible to simplify the docking process, because high accuracy of the alignment of the longitudinal axis of the upper stage with the corresponding longitudinal axes of the rocket and the frame is ensured; - an additional railway track for the assembly trolley of the upper stage is mounted on the floor, and the longitudinal 60 axis of the additional railway track is located in a vertical plane that passes through the longitudinal axis of the frame, which allows to exclude crane overloading of the upper stage; - the presence of a horizontal shaft installed in the wall, which allows for round-the-clock maintenance of the upper stage with minimal effort; - at one end of the horizontal shaft, a frame with a power ring is fixed coaxially, and the other end of the horizontal shaft is connected to the drive of its rotation, which allows to simplify the construction of the housing due to the minimum number of elements.

The task is solved in such a way that the proposed missile IC, which contains a floor, walls with a roof, a railway track for mounting trolleys of rocket stages and a wall-mounted frame with upper stage fastening nodes, in which the frame is fixed on a wall located parallel to the railway track, and equipped with a power ring, which is made of an open profile and on which the fastening nodes of the upper stage are mounted, while the longitudinal axis of the frame is oriented perpendicular to the specified wall and is located at the same level as the longitudinal axis of the missile. The section of the floor with a section of the railway track is installed on a vertical shaft with the possibility of turning with the help of a drive, while the longitudinal axis of the vertical shaft passes through the intersection of the longitudinal axes of the rocket and the frame, an additional railway track for the assembly trolley of the upper stage is mounted on the floor, and the longitudinal axis of the additional of the railway track is located in a vertical plane that passes through the longitudinal axis of the frame. The body is equipped with a horizontal shaft installed in the wall, at one end of which a frame with a power ring is coaxially fixed, and the other end of the horizontal shaft is connected to the drive for its rotation.

To explain the design of the MVCU and its work, drawings and its detailed description are attached. The drawings show: - in Fig. 1 - a general view of the MVKU (the upper stage is connected to the frame); - in Fig. 2 - view A of Fig. 1 (front view of the upper step); - in Fig. 3 - a general view of the MVKU (the upper stage is connected to the rocket); - in Fig. 4 - view B of Fig. 3 (front view of the rocket); - in Fig. 5 - a general view of the MVKU (with a rotating frame); - in Fig. 6 - section B-B Fig. 5 (cross section of the case with a rotating frame).

The proposed MVK consists of a floor 1, walls 2 with a roof 3, a railway track 4 for assembly trolleys 5 of the first b and second 7 stages of the rocket and assembly trolley 8 of the upper stage 9 of the rocket (Fig. 1-4). The frame 10 with the power ring 11 is fixed on the wall 2, located parallel to the railway track 4. The power ring 11 is made of an open profile (corner or channel) and is equipped with nodes 12 for fastening the upper stage t 9. On the front end 13 of the upper stage 9, the front technological ring 14, a rigid half-ring 15 is installed on the rear frame. Battery batteries 16 and a torus compartment 17 of devices with a cover 18 are also installed on the upper step 9. Section 19 of floor 1 with a section 20 of the railway track is installed on a vertical shaft 21 with a drive 22. Additional railway track 23 is mounted on floor 1.

To ensure round-the-clock maintenance, the frame 10 with the power ring 11 is rigidly attached to the horizontal shaft 24, installed on the wall 2 and connected to the rotation drive 25 (electric motor with (o reducer) (Fig. 5, 6).

The work of the proposed MEC is carried out as follows. co

Stages 6, 7, 9 rockets are delivered from the manufacturing plant to the MVK and reloaded onto assembly carts 5, 8 "- respectively. The first 6 and the second 7 degrees connect. The upper stage 9 is connected to the power ring 11 of the frame 10 with the help of bolt-type fasteners 12, electrical and pneumatic communications are connected to the upper stage 9 and electrical and pneumatic tests are carried out (Fig. 1, 2).

If necessary, pre-prepared batteries 16 are installed. For this purpose, the assembly trolley 8 is removed, with the help of the drive 25, the upper stage is successively rotated around the longitudinal axis pt") from the horizontal shaft 24 in such a way that the seat for the corresponding battery 16 is

And from above. With the help of a bridge crane, a battery 16 with a weight of 20 kg is installed. service personnel are located on service facilities (overhead crane and service facilities on

Fig. 5, 6 are not shown).

When malfunctions are detected in the device compartment 17, either cover 18 is removed, the faulty device is replaced and cover 18 is installed, or the entire device compartment 17 is replaced. The assembly trolley 8 is brought up.

After that, the upper step 9 is undocked from the frame 10 and along the additional railway track 23, the upper step 9 on the assembly trolley 8 is moved to the section 19 of floor 1 (in Fig. 2, 4 placement of the assembly trolley

Ge" 8 on section 19 of floor 1 is depicted by a dotted line). With the help of the drive 22, the section 19 of the floor 1 5r is turned by 902 to the alignment of the section 29 of the railway track with the railway track 4. The assembly trolley 8 o is moved to the railway track 4. The upper stage U is reloaded into a car, taken to a gas station,

Then fuel components and compressed gases are filled, returned to the housing and reloaded onto the assembly trolley 8.

Next, the upper stage 9U is connected to the second stage 7 of the rocket with the help of fastening nodes 12 (Fig. 3, 4) and electrical tests are carried out.

Next, the assembly trolley 8 is moved away from the upper stage 9, the front technological ring 14 and the rigid half-ring 15 are removed, the spacecraft is docked to the front end 13 of the upper stage 9, and the upper stage 9 and the spacecraft are covered with a fairing. The rocket is ready for transportation to the launcher.

In the case of cancellation of the launch, the rocket is disassembled in the reverse sequence. Thus, the proposed MVK, which has a simple and reliable design, allows you to rationally use the space of the hull and simplify the maintenance of the rocket.

Claims (2)

The formula of the invention 65 1. The assembly and test case of the rocket, containing the floor, walls with a roof, a railway track for the assembly trolleys of the rocket stages and a wall-mounted frame with the fastening nodes of the upper stage, which is distinguished by the fact that the frame is fixed on a wall located parallel to the railway track, and is equipped with a power ring, which is made of an open profile and on which the fastening nodes of the upper stage are mounted, while the longitudinal axis of the frame is oriented perpendicular to the specified wall and is located on the same level with the longitudinal the axis of the rocket. 2. The assembly and test case of the rocket according to claim 1, which is distinguished by the fact that in it the floor section with a section of the railway track is installed on a vertical shaft with the possibility of turning with the help of a drive, while the longitudinal axis of the vertical shaft passes through the intersection of the longitudinal axes of the rocket and the frame, an additional railway track for the assembly trolley of the upper stage is mounted on the floor, and the longitudinal axis 7/0 of the additional railway track is located in a vertical plane that passes through the longitudinal axis of the frame. C. The rocket assembly and test case according to claim 17, which is characterized by the fact that it is equipped with a horizontal shaft installed in the wall, at one end of which a frame with a power ring is coaxially fixed, and the other end of the horizontal shaft is connected to the drive for its rotation. that 2 « (ze) (Se) (ee) yo - and? - (ee) (o) (95) c» 60 b5