RU2425928C1 - Energy-saving operating equipment of excavator with articulated digging arm - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: energy-saving operating equipment includes digging arm base, digging arm head, handle, bucket, the main hydraulic cylinders for lifting the digging arm, control hydraulic cylinder of the digging arm length, additional balancing pneumatic cylinder connected to portal and to the digging arm base. Piston cavity of balancing pneumatic hydraulic cylinder is connected to gas bottle charged with pressure of more than 10 MPa and having the volume equal at least to five operating volumes of balancing pneumatic hydraulic cylinder. At that, to piston cavity at least of one main hydraulic cylinder for lifting the digging arm there connected is hydropneumatic accumulator the gas cavity of which is charged with initial pressure of more than 10 MPa and divided at least into two gas chambers separated with a partition in which an adjustable orifice is installed.

EFFECT: higher operating efficiency of machine, lower energy losses and higher efficiency of operating equipment.

2 dwg

Description

The invention relates to single-bucket universal excavators having an articulated boom.

Known working equipment of an excavator with a telescopic boom, for example [AS No. 384988, 05/29/1973, BI No. 25], containing a wheeled base tractor, an arrow containing the base of the boom and the head of the boom, the base of the boom made in the form of a pipe in which the head of the boom is located and a hydraulic cylinder for adjusting the length of the boom.

The disadvantage of this device is the large dimensions of the boom, due to the sequential arrangement of the hydraulic cylinder for adjusting the length of the boom, the tip of the boom and the base of the boom.

The closest in technical essence of the known technical solutions to the proposed device is the working equipment of a single-bucket excavator with an articulated boom [A.V. Rannev. Single bucket construction excavators. Moscow, "Higher School", 1991. - 304 p. P.35], comprising a tracked base vehicle, boom base, boom head, handle, bucket, main boom lifting hydraulic cylinders, boom length hydraulic cylinder.

The disadvantage of this device is the large load of the boom lifting cylinders, due to the increased cantilever of the working equipment, a large digging radius and a large digging depth.

Another disadvantage of the device is the large dynamic loads in the boom hydraulic drive at the beginning of its acceleration during lifting and at the time of braking when lowering, due to the high design pressure in the hydraulic drive (32 MPA) and the large cantilever arrangement of the gravity of the working equipment elements relative to the boom mounting hinge on the portal.

The working equipment of a single-bucket excavator according to AS No. 384988 and the prototype [A.V. Rannev. Single bucket construction excavators. Moscow, "Higher School", 1991. - 304 p. P.20, p.35], is energy-consuming, since when lifting a payload in a bucket, considerable energy is useless to overcome the gravity of the boom, stick, bucket. To overcome these forces of gravity, the engine consumes fuel.

The objective of the invention is to improve the design of the working equipment of the excavator by balancing the gravity of the boom, stick and bucket and providing damping oscillations of the boom under dynamic loads.

The object of the invention is solved in that in the known device, including an articulated boom containing the base of the boom, head of the boom, handle, bucket, main hydraulic cylinders for raising the boom, hydraulic cylinder for adjusting the length of the boom, a balancing pneumohydraulic cylinder, pivotally connected to the portal and the base of the boom, is additionally used the cavity of which is connected to a gas cylinder charged with a pressure of more than 10 MPa, the volume of which is equal to at least five working volumes of a balancing pneumog drotsilindra, while in the piston chamber, at least one main cylinder boom connected hydropneumatic accumulator, gas cavity is charged with an initial pressure of more than 10 MPa and is divided into at least two gas chambers separated by a partition, wherein an adjustable throttle.

The proposed invention made it possible to create energy-saving working equipment and to damp boom vibrations in dynamic operating modes.

The invention is illustrated by drawings, where Fig. 1 shows a general view of an energy-saving working equipment of an excavator, in which the main boom lifting hydraulic cylinders close the balancing pneumohydraulic cylinder located inside. Figure 2 shows energy-saving working equipment on which the main boom lifting cylinders are conventionally cut off and a balancing pneumohydrocylinder is shown in the lower digging position and the upper position when unloading the bucket.

The invention comprises a lower frame with a caterpillar running gear 1, a rotary platform 2 with a portal 3, on which the base of the boom 4 is pivotally mounted pivotally connected to the head of the boom 5, the handle 6, the bucket 7, the main hydraulic cylinders 8 of the boom lift, balancing the pneumohydrocylinder 9, the piston cavity which is connected to the gas cylinder 10 (see figure 2) by a line 11. In the piston cavity of the main hydraulic cylinder 8 for lifting the boom, a hydraulic accumulator 13 is connected by a hydraulic line 12 (see figure 1), in which the piston 14 divides the hydraulic and gas cavities.

The gas cavity 15 of the pneumatic accumulator is divided into two gas cavities by a partition 16 in which an adjustable throttle 17 is installed. The base of the boom 4 and the head of the boom 5 are connected by a hydraulic cylinder 18 for controlling the length of the boom.

The work of energy-saving working equipment is as follows. The working operations of turning the bucket and handle are performed in the usual way and are not subject to description.

To lift the working equipment with the bucket filled, the rods of the main hydraulic cylinders 8 extend out of the hydraulic cylinders and rotate the base of the boom 4 counterclockwise relative to the portal 3. At the same time (see Fig. 2), the balancing pneumohydrocylinder 9, the piston cavity of which is connected by hydraulic line 11 to the gas cylinder 10, carries out balancing the gravity of the base of the boom 4, the tip of the boom 5, the handle 6 and the bucket 7. As a result, when lifting the working equipment, the main hydraulic cylinders 8 when lifting the boom they only payload by the weight of the payload in the bucket. As a result of this, the load on the engine, hydraulic pumps, hydraulic cylinders is reduced and the durability of the considered elements is increased. At the same time, engine fuel consumption is significantly reduced and the efficiency of the working equipment is increased.

When lowering the working equipment, the rods are retracted into the hydraulic cylinders 8, the working equipment rotates clockwise relative to the portal 3, while the gas from the piston cavity of the balancing pneumohydrocylinder 9 returns to the gas cylinder 10 with virtually no resistance. Moreover, the volume of the gas cylinder 10 is equal to at least five times the working volume of the balancing pneumohydrocylinder, as a result of which the pressure in the gas cylinder 10 remains approximately constant when the boom is raised and lowered.

At the beginning of the lifting of the working equipment with the load in the bucket and during braking during the lifting process, significant inertia forces arise from the masses of the load, bucket, stick, boom head and base of the boom. To damp vibrations of the boom into the piston cavities of the main hydraulic cylinders 8, a hydraulic accumulator 13 is connected by a hydraulic line 12 (see Fig. 1). The gas cavity 15 of the pneumatic accumulator 13 is divided into two chambers by a partition 16, which is equipped with an adjustable throttle 17.

When the pressure in the piston cavities of the main hydraulic cylinders 8 is less than 10 MPa, the damping system does not work, and the piston 14 of the pneumatic accumulator 13 is in the lower limit position.

When the dynamic loads on the working equipment become significant (more than 10 MPa), the piston 14 begins to move upward, compressing the gas in the working chamber 15. As a result, the gas pressure above the piston 14 is much higher than above the dividing wall 16. Therefore, the gas in the pneumatic accumulator is not exposed only elastic compression, but is also throttled by the throttle 17. Due to the appearance of additional damping forces, the hydraulic system stiffness of the main hydraulic cylinders 8 is reduced and limited level of dynamic pressures in the hydraulic drive and pump.

Claims (1)

Energy-saving working equipment for an excavator with an articulated boom, including boom base, boom head, handle, bucket, main boom lifting hydraulic cylinders, boom length hydraulic control cylinder, characterized in that an additional balancing pneumohydraulic cylinder is used, connected to the portal and boom base, the piston cavity of which is connected to a gas cylinder charged with a pressure of more than 10 MPa and having a volume equal to at least five working volumes of a balancing pneumohydrocylinder while a pneumatic accumulator is connected to the piston cavity of at least one main boom lifting hydraulic cylinder, the gas cavity of which is charged with an initial pressure of more than 10 MPa and is divided into at least two gas chambers separated by a partition in which an adjustable throttle is installed.

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