SU1626287A1 - Telescopic mast and lock of a section thereof - Google Patents

Abstract

The invention relates to antenna technology. The aim of the invention is to increase the reliability of operation by eliminating the movement of more than one section at a time. The telescopic mast contains the outer section 2 installed on the base 1, the intermediate sections 3-5 and the inner section 6. The translational drive is located inside

Description

The invention relates to antenna technology and building structures, namely to structures of deployable supports.

The purpose of the invention is to increase the reliability of operation by eliminating the movement of more than one section at a time and to increase the reliability of fixing the extreme positions.

FIG. 1 shows the telescopic mast, general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 - the lower part of the telescopic mast, a longitudinal section; in fig. 4 shows a section BB in FIG. 3; in fig. 5 shows section B-8 in FIG. 3; in fig. 6 is a sectional view in FIG. 3; in fig. 7 - section dD in figure 1; in fig. 8 - lock sections telescopic mast in the initial position, a longitudinal section; in fig. 9 - the same, after locking the section.

The telescopic mast contains a base 1 on which the outer section 2 is fixed, inside which intermediate 3-5 and inner 6 sections are placed. In the lower (Fig. 1) parts of sections 3-6 there are bottom plates with central openings, inside of which grooves are made, which are located in the same diametrical cross section and are formed by protrusions 7. The grooves of different sections 3-6 are offset from one another by an angle a, equal to the angular step

stepper turning mechanism. To prevent mutual reversal, sections 2-6 are interconnected by key connections 8. For fixing the extreme positions of sections 2-6, there are

locks 9 of the folded state, installed in the lower parts of sections 2-5, and locks 10 of the unfolded state, installed in the upper parts of the same sections 2-5. Inside the inner section 6, on the axis of the telescopic mast, a translational drive is arranged, for example, in the form of a hydraulic cylinder with a fixed rod 12. To protect against spontaneous turning, the hydraulic cylinder 11 interacts with the guides 13. fixed on the base 1. The head 14 is fixed on the hydraulic cylinder 11 with the possibility rotation around its axis and is provided with a lock 15 of its angular position on the hydraulic cylinder 11. The fixing step of the head 14 is equal to the angle a.

On the head 14, there is a hook 16, which is a protrusion, in the opening of which two wedges 17 are placed, between which a compression spring 18 is located. The width of the protrusion is made equal to the width of the groove formed by the protrusions 7, and the distance between the wedge 17 and the T-shaped tide of the hook 16 is equal to the height of the protrusions 7. On the head 14 there is a protrusion 19 interacting with a spring-loaded lock rod 9. At the bottom ) the end face of the head 14 is pressed in by pins 20 interacting with openings made on the end face of the disk 21 of the stepping rotary mechanism facing the head 14, located on the same circle with a step equal to the angle a.

The stepping rotary mechanism includes a disk 21 connected by a torsion spring 22 to the base 1 and provided with two fingers 23, two convex cams 24 which are fixed on the base 1 and on the tops of which holes for fingers 23 are made, two solenoids 25 and 26 which are mounted on the base 1 and the rods of which are provided with bevels directed oppositely and interacting with the fingers 23.

In order to ensure an automatic cycle of operation of the telescopic mast, the latter is equipped with two limit switches 27 fixed in the upper part of the guides 13 and located on the same circle with a step equal to the angle (I and interacting with the head 14 when the latter takes the extreme upper position in positions I and IV (Fig. 2), as well as a limit switch 28 fixed on the base 1 and interacting with the finger 23. The working fluid is supplied to the cavity 29 and 30 of the hydraulic cylinder 11 via a rod 12. Each lock 9 is folded allowed to stand is designed as a spring-loaded rod 31 interacting with the notches made in the bottoms of the sections 3-6.

The lock 10 of the unfolded state of the telescopic mast sections comprises a pin 32 mounted for movement, for example, in section 2 of the telescopic mast perpendicular to its axis. A sleeve 33 is mounted on the pin 32 for movement along it and in the telescopic mast section 2, which is connected to the first end of the pin 32 by means of a tension spring 34, and a telescopic mast section 2 by means of a compression spring 35. The tension spring 34 counteracts the compression spring 35. The first end of the pin 32 is provided with a spring-loaded retainer 36, which interacts with sections 2 and 3 of the telescopic mast. In

0 the sleeve 33 has a groove in which a rusk 37 is placed, mounted with the possibility of moving together with the telescopic mast section 3. Rusk 37 is equipped with a roller 38, interacting with the second

5 end pin 32, which is made with a bevel. The latch 36 can interact with section 2 of the telescopic mast through its pin 39, and with section 3 of the telescopic mast - through

0 pusher 40.

Telescopic mast works as follows.

When the mode of raising the telescopic mast is switched on, the working fluid through

5, the fixed rod 12 enters the cavity 30. The hydraulic cylinder 11 rises together with the head 14, which, with its hooks 16, enters the grooves formed by the projections 7 of the inner section 6. With further movement of the head 14, the capture of the inner section 6 simultaneously causes wedges 17 and retraction spring rod 31 of the lock 9 of the folded state. At the same time, voltage is applied.

5 per solenoid 25. whose stock rises. Further movement of the head 14 leads to the rise of the inner section 6 to the level at which it is locked by the lock 10 of the unfolded state installed on the intermediate section 5. The stopping of the inner section 6 leads to an increase in pressure in the pipeline, which causes the control valve to switch (not shown) and to the supply of working fluid in

the cavity 29 through the fixed rod 12. The hydraulic cylinder 11 starts to fall, and the hook 16, overcoming the resistance of the compression spring 18, leaves the groove of the inner section 6. At the end of the stroke of the hydraulic cylinder 11, the head 14 is fixed by means of pins 20 on the disc 21. together with the head 14 and the disk 21, the fingers 23 of the disk 21 interact with the bevel of the rod of the solenoid 25, and

5 then with a convex cam 24, which leads to compression of the torsion spring 22 and rotation of the disk 21 together with the head 14 at an angle a, for example, clockwise (FIG. 2).

In this position, the head occupies position II, which is fixed by retainer 15, and the hook 16 is located under the groove formed by the projections 7 of the intermediate section 5. In the lower position of the hydrocylin 5 of the core 11, the finger 23 rests on the lower part of the cam 24. The hydraulic cylinder 11 stops, the pressure in the pipeline increases , which leads to the switching of the control valve and to the supply of the working fluid to the cavity 30, and the lifting cycle is repeated with the difference that at the end of each cycle, the head 14 successively moves to the next in order field number The following sections of intermediate sections 4 and 3 are lifted up following the order of numbers. After the head 14 is detached from the head 14, the disk 21 returns to its original position under the action of the torsion spring 22. When the last intermediate section 3 is locked in the upper position, the head 14, with its protrusion 41, interacts with the limit switch 27 (interaction is possible only in position IV of the head 14), which turns off the solenoid 25, the rod of which is lowered. Therefore, at the end of the downward stroke of the head 14, the finger 23 of the disk 21 falls into the holes of the cams 24, which prevents the rotation of the holoke 14. Simultaneously with the fixation in the hole, the fingers 23 interact with the limit switch 28, which turns off the power of the hydraulic pump. The telescopic mast deployment is complete.

When the telescopic mast descent mode is activated, the working fluid enters the cavity 30 of the hydraulic cylinder 11, which leads to the lifting of the head 14 and its adhesion through the zzcepa 16 to the intermediate section 3. Simultaneously with the lifting of the head 14, the solenoid 26 is turned on, the stem of which rises. Lifting the head 14 after engaging with the intermediate section 3 triggers the lock 10 of the unfolded state, and the intermediate section 3 gets the possibility of unhindered lowering, which occurs after the lifting of the head 14 due to switching of the control valve and supplying the working fluid to the cavity 29. After reaching the intermediate section 3 of the lower position is locked by the lock 9 of the collapsed state.

Upon further downward movement of the head 14, it disengages from the intermediate section 3 and fixes it on the disk 21 by means of pins 20. Upon further lowering of the hydraulic cylinder 11 together with the head 14 and the disk 21, the fingers 23 of the disk 21 interact with the bevel of the solenoid rod 26, and then with convex cam 24, which leads to compression of the spring 22. twist and to turn the disk 21 joint head 14 at an angle a counterclockwise (figure 2). In this position, the head 14 occupies position III, which is fixed by a lock 15, and the hook 16 is located

under the groove formed by the protrusions 7 of the intermediate section 4. In the lower position of the hydraulic cylinder, the finger 23 rests on the lower part of the tank 24. The hydraulic cylinder 11 stops, the pressure in the pipeline increases, the control valve switches, the working fluid begins to flow into the cavity 30 and the hydraulic cylinder 11 is joint head 14 rises, starting on a new cycle, each of which leads to sequential rotation of head 14 by angle a, moving it to position II and I and lowering the corresponding sections - intermediate 5 and internal 6, Disc 21

5, after the head 14 is detached from it, when the latter is lifted, it returns to its original position under the action of the torsion spring 22.

When doing the last cycle in

0 the process of moving upwards after engagement with the inner section 6, which is necessary for the operation of the lock 10 of the unfolded state, the head 14 with its protrusion 41 interacts with another limit switch

5 27 (interaction is possible only in position I of head 14), disengaging the solenoid 26, the stem of which is lowered. Therefore, at the end of the downward stroke of the head 14, the fingers 23 of the disk 21 fall into the holes of the cams 24,

0 which eliminates the rotation of the head 14 and causes the end switch 28 to turn off the power of the hydraulic pump. The folding of the telescopic mast is completed and it is ready for a new deployment.

Lock sections telescopic mast works as follows. In the initial state, the force of the spring 35 is greater than the force of the tension spring 34 and the sleeve 33 tends to move to the right (as shown in FIG. 8), which is prevented by section 3 of the telescopic mast. After lifting the telescopic mast section 3, the sleeve 33 moves to the right and enters a window made 5 in the body of the telescopic mast section 3. After the lift drive (not shown) of the telescopic mast section 3 is disconnected, the latter is lowered, moving cracker 37. The roller 38 of which acts on the bevel of the rod 12 and moves it to the left (in Fig. 8). The left position of the rod 12 is fixed by a spring-loaded latch 36. In this case, the force of the tension spring 34 becomes greater than the force of the compression spring 35. Section

5 3 telescopic mast locked.

To unlock section 3 of the telescopic mast, it must be lifted with a lifting drive so that rusk 37 allows sleeve 33 to leave the window of section 3 of the telescopic mast, after which the latter can be lowered. At the end of the lowering stroke, section 3 of the telescopic mast acts by means of the pusher 40 on the spring-loaded clamp 36 and inserts the pin 39 of the latter. Under the action of the tension spring 34, the pin returns to the right position, i.e. the lock of the telescopic mast sections has returned to its original state.

Claims (4)

Claim 1. Telescopic mast, comprising an outer section fixed on the base, intermediate and inner sections, in the lower parts of which the bottoms with central openings are made, the sections are interconnected by key connections, equipped with locks of the unfolded state installed in the upper parts sections, except for the internal, and locks of the folded state, located in the lower parts of the sections, except for the internal, and a drive of translational movement, located on the axis of the sections and interacting with A head with their bottoms, characterized in that, in order to increase the reliability of operation by eliminating the movement of more than one section at the same time, a stepping pivot mechanism, made in the form of a disk connected by a torsion spring with a base and equipped with two fingers, is combined mounted on the base and on the tops of which holes are made under the fingers, two solenoids, which are installed on the base and the rods of which are provided with bevels oppositely directed and interacting with fingers, there are holes around the disk face, located around the circumference, and corresponding pins are installed at the head end, the head is installed with the possibility of rotation around the drive axis, provided with a lock of its angular position, a hook interacting with the bottom, and a protrusion interacting 5 with locks of the folded state, slots are made in the bottoms, which, like the locks of the folded state, are shifted by angle in accordance with the angular positions of the head. 0 2. A mast according to claim 1, characterized in that the hook is made of two wedges, between which a compression spring is placed. 3. Mast according to claim 1, characterized in 5 in that the drive of translational movement is made in the form of a hydraulic cylinder with a fixed rod. 4. The lock section of the telescopic mast containing pin, spring-loaded 0 with a compression spring and mounted for movement perpendicular to the axis of the first section of the telescopic mast, the first end of the compression spring is supported on the first section of the telescopic mast, about the fact that, in order to increase the reliability of fixing the extreme positions, the sleeve is movable on the pin, spring tension is introduced, counteracting 0 the compression spring, both springs with the second ends are fixed on the hub, the first end of the tension spring is fixed on the first end of the pin, provided with a spring-loaded retainer, interacting with 5 of the first and second, located closer to the center, sections of the telescopic mast, a groove is made in the sleeve, in which a cracker is placed that is mounted so that it can move together with the second 0 section telescopic mast, cracker is provided with a roller that interacts with the second end of the pin, which is made with a bevel. 9Ltt7Ul4 BB 26 FIG. four 6 18/7 7 Bb 5 LL t SHZHShYAYA 32 /.///// 2 34 35 33 3d 31 FIG. eight XV4X4XVCWVW "V