RU219530U1 - Telescopic boom - Google Patents

Abstract

The utility model relates to lifting and transport mechanisms, in particular to telescopic booms mounted on railway cranes. The essence of the technical solution lies in the fact that in the crane boom, which consists of three telescopic sections of profiles included in each other, separated by corresponding sliding supports, the profile of each section is made of two counter-directed ovoid-shaped half-boxes welded along the section, the profile of the upper half-box is formed by a horizontal by a section located between two vertical sections, said vertical sections are connected to the ends of the horizontal section by inclined sections. The inclined sections of the upper semi-box are located symmetrically at an angle of 145-155° with respect to the horizontal section. In this case, the resulting hexagonal semi-box is close to an ovoid shape with apex angles of 150°. The profile of the lower semi-box is made similar to the upper semi-box. Polyamide sliding supports are installed along the length of the boom. The technical result of the proposed model is to reduce the weight of the boom structure, increase the stability of the side walls and increase the strength of the boom. The ovoid shape of the boom allows for a more rational perception of the payload than the box-shaped boom. The boom is made of bent half-boxes welded along the neutral line, which made it possible to reduce its weight by 30% compared to box-type booms of the same load capacity, and to increase the stability of the walls. The crane boom is three-section telescopic. Boom sections are welded box structures with a dodecagonal cross section. A telescopic boom is known from the prior art (patent No. 190009, application No. 2019108312 dated March 22, 2019, patent holder Chelyabinsk Mechanical Plant (RU)). The boom with the proposed shape of the section profile has higher strength properties due to the fact that the load is redistributed and the stability of the walls increases.

Description

The utility model relates to lifting and transport mechanisms, in particular to telescopic booms mounted on railway cranes. The essence of the technical solution lies in the fact that in the crane boom, which consists of three telescopic sections of profiles included in each other, separated by corresponding sliding supports, the profile of each section is made of two counter-directed ovoid-shaped half-boxes welded along the section, the profile of the upper half-box is formed by a horizontal by a section located between two vertical sections, said vertical sections are connected to the ends of the horizontal section by inclined sections. The inclined sections of the upper semi-box are located symmetrically at an angle of 145-155° with respect to the horizontal section. In this case, the resulting hexagonal semi-box is close to an ovoid shape with apex angles of 150°. The profile of the lower semi-box is made similar to the upper semi-box. Polyamide sliding supports are installed along the length of the boom. The technical result of the proposed model is to reduce the weight of the boom structure, increase the stability of the side walls and increase the strength of the boom.

The ovoid shape of the boom allows for a more rational perception of the payload than the box-shaped boom. The boom is made of bent semi-boxes welded along the neutral line, which made it possible to reduce its weight by 30% compared to box-type booms of the same load capacity, and to increase the stability of the walls.

The crane boom is three-section telescopic. Boom sections are welded box structures with a dodecagonal cross section.

The lower section of the boom at the base is attached by means of an axle to the pivot frame support. In the middle part of the section, a bracket is welded for mounting the rods of the boom lifting hydraulic cylinders.

The middle boom section is moved by a hydraulic cylinder. The eye of the rod of the hydraulic cylinder is pivotally fixed with an axis in the bracket of the base of the lower section. The hydraulic cylinder trunnions are held by bracket plates at the base of the middle section.

On the same bracket, with the help of an axis, the lug of the rod of the hydraulic cylinder for extending the upper section is tilted. The trunnions of the extension hydraulic cylinder of the upper section are mounted in a bracket welded at the base of the upper section. The tightening torque of the trunnion fastening bolts of both hydraulic cylinders is 52 kgf⋅m.

At the ends of the sleeves of the hydraulic cylinders, supporting supports are fixed. At the same time, the support of the sleeve of the extension hydraulic cylinder of the middle section is supported by the slider on the upper belt of the upper section, while remaining stationary during the operation of the cylinder.

The support of the sleeve of the hydraulic cylinder for extending the upper section during the operation of the cylinder moves along the lower belt of the upper section with the help of rollers.

When moving the boom section, they rest in front on the lower side bearings fixed on the inner lower surfaces of the lower and middle sections; at the back - on the upper bearings installed on the outer upper surfaces of the middle and upper sections, and on the bearings.

From lateral displacement, the boom sections are held in front and behind by stops.

The working blocks rotate on rolling bearings on the axles. Fences exclude the exit of the rope from the stream of the block. Optimum passage of the ropes over the boom is ensured by the deflecting roller.

To prevent the ropes from touching the metal structure:

supporting rollers are installed on the lower section of the boom;

polyamide plates are installed on the upper section of the boom.

To obtain the permissible angles of deviation of the cargo ropes on the blocks and the drum and the normal laying of the ropes on the drum, deflecting rollers are installed. Deflecting rollers are mounted on a lever pivotally welded to the upper chord of the lower section. The lever is suspended on cargo ropes by means of rollers and changes its position relative to the boom along with the change in reach.

On the head of the upper section there is a guard from the contact wire and a hook lifting height limiter.

For ease of maintenance of the boom equipment, a hatch is installed on the lower section.

The claimed technical solution is illustrated by drawings, where in Fig. 1 shows a 3D model of the boom; in fig. 2 arrow in section.

A telescopic boom is known from the prior art (patent No. 190009, application No. 2019108312 dated March 22, 2019, patent holder Chelyabinsk Mechanical Plant (RU)). The boom with the proposed shape of the section profile has higher strength properties due to the fact that the load is redistributed and the stability of the walls increases.

Claims (7)

1. A telescopic boom containing at least three sections of profiles included in each other, separated by corresponding sliding supports, the profile of each section, ovoid semi-boxes; the profile of the upper semi-box is formed by a horizontal section placed between two vertical sections, these vertical sections are connected to the ends of the horizontal section by inclined sections; the inclined sections of the upper semi-box are located symmetrically at an angle of 145-155° with respect to the horizontal section, while the resulting hexagonal semi-box is close to an ovoid shape with apex angles of 150°; having a device for fixing the hook clip on the boom during transportation. 2. Telescopic boom according to claim 1, characterized in that each section has 12 faces. 3. Telescopic boom according to claim 1, characterized in that the sections are made of two halves with a welded seam on the lateral vertical surface, which has minimal loads. 4. Telescopic boom according to claim 1, characterized in that the boom head has one row of blocks and is made horizontally for maximum lifting of the hook suspension when working under the contact wire. 5. Telescopic boom according to claim 1, characterized in that the cross section of the boom sections are symmetrical vertically and horizontally. 6. The telescopic boom according to claim 1, characterized in that the boom has no stops, and the sequence of extension of the boom sections is provided by the design of the telescoping hydraulic cylinders. 7. Telescopic boom according to claim 1, characterized in that the hook clip is attached to the boom head.

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