RU2265699C1 - Draghead - Google Patents

Abstract

FIELD: hydromechanization equipment for construction as well as for hydromechanized production and laying of non-metallic building materials with the use of dredges namely floating earth-moving machines.

SUBSTANCE: draghead comprises ground pump with electric drive and with suction and pressure pipelines. The draghead also has ejection system. Ejection system includes water ejecting pump with suction and pressure pipelines adapted to supply water to flow mixing chamber arranged in suction pipeline of ground pump. Ejection system is provided with annular water manifold connected to pressure pipeline of water ejecting pump. The water manifold has hydraulic nozzles to supply water to conical flow mixing chamber. The flow mixing chamber is connected to suction pipeline of ground pump immersed in water under water surface layer.

EFFECT: increased depth of cavitation-free ground excavation without draghead productivity reduction, increased distance of ground hydrotransportation.

1 dwg

Description

The invention relates to the field of hydromechanization both in construction and in hydromechanized mining and laying of non-metallic building materials with dredgers - floating earth-moving machinery.

It is known [Glevitsky V.I. Hydromechanization in transport construction: Reference manual / V.I.Glevitsky. M .: Transport, 1988, pp.207-208] a dredger suction device with an ejector in the suction pipe of a regular (bilge) soil pump in order to create a dynamic backwater in its suction pipe, including an electric bilge soil pump, an ejector water pump mounted in the engine room dredger and water supplying through a pipeline to the annular collector and conoidal hydraulic nozzles of the ejector mounted on the suction pipe of the bilge soil pump. At the same time, dynamic backwater increases the cavitational reserve of the bilge soil pump, which, in turn, allows to increase either the depth of underwater mining of the soil or the soil productivity of the dredger.

The disadvantages of a replaceable dredger suction device with an ejector in the suction pipe of the bilge soil pump are:

1) the amount of dynamic backwater that is limited by the parameters of the complex hydraulic system of the bilge soil pump with an ejector in its suction pipe, which, in turn, limits the economically justified depth of underwater excavation at a given soil productivity or soil productivity at a given depth of underwater excavation; 2) the difficulty of practical implementation due to the lack of reliable methods for calculating the parameters of ejection at present, which is explained by the non-deterministic nature of the task of quantitative description of the parameters of a complex self-adjusting hydraulic system of a bilge soil pump with an ejector in its suction pipe.

It is also known dredging device [Shkundin B.M. Hydromechanization in energy construction. M .: Energoatomizdat, 1986, p.27-28], including a submersible soil pump, submerged under the water level in the bottom of the dredger to create a static backwater in the suction pipe of a submersible soil pump, with an electric drive, a pressure pipe with a hinge device. In this case, the static backwater increases the cavitation stock of the submersible soil pump, which, in turn, allows you to increase either the depth of the underwater mining of the soil or the soil productivity of the dredger.

The disadvantages of the dredging device of the dredger with the submersible soil pump are the difficulties of its practical implementation due to the need for a relatively large immersion of the submersible soil pump under the water level: 1) a significant strengthening of the design of the bow of the dredger; 2) the need to install additional nasal pontoons due to violation of the longitudinal stability of the dredger; 3) a significant amount of one-time costs, as well as a significant increase in specific energy costs for the development, transport and hydraulic laying of the soil.

The technical solutions described in the special literature are considered only as alternative [see, for example, Ogorodnikov SP Hydromechanization of soil development / SP. Ogorodnikov. - M., Stroyizdat, 1986, p. 57-59, 246-253; Popov Yu.A. A new concept of dredging in construction hydromechanization / Yu.A. Popov, D.V. Roshchupkin, M.A. Nyushkov // Izv. Universities. Pages - 1998. - No. 7. - S.75-80; Glevitsky V.I. Hydromechanization in transport construction: Reference manual / V.I. Glevitsky. M .: Transport, 1988, S.197-199, 206-208]. However, developed at NGASU (Sibstrin) [Laptev B.C. Deep underwater mining by hydromechanization / B.C. Laptev // Tr. NGASU, t.6, No. 5 (26). - 2003. - P.6-11] the solution of the problem under consideration by the method of morphological analysis and synthesis of known technical solutions with analysis according to six characteristics and twenty-three values convincingly confirmed the feasibility of combining the immersion of the soil pump under the water level in the bottom of the dredger and ejecting the suction pipe of the submersible soil pump. At the same time, a software product that has no analogues was created, which allows, firstly, to reliably calculate the ejection parameters, and secondly, to determine the economically justified depth of immersion of the soil pump under the water level in the bottom of the dredger [Popov Yu.A. Deep underwater mining by hydromechanization / Yu.A. Popov, B.C. Laptev // Izv. Universities. Str. - 2003. - No. 12. - S.54-60].

The closest in technical essence is the technical solution for AS No. 872662 A, MKI E 02 F 3/90, 10/15/1981 - prototype for a dredging projectile, including an electric soil pump, its suction and pressure pipelines, an ejection system consisting of an ejector water pump with its suction and pressure pipelines for water supply into the flow mixing chamber located in the suction pipe of the soil pump. However, due to design features, the technical solution prototype does not allow to increase the depth of cavitation-free underwater excavation of the soil, since only the ejection effect acts, while the proposed technical solution has the total effect of ejection and immersion.

The technical problem solved by the invention is to increase the depth of cavitation-free underwater excavation of the soil without reducing the soil productivity of the dredger by summing up the effects of static and dynamic backwater during the implementation of the cavitation stock of the soil pump dredger submerged beneath the water level, as well as a significant increase in the reduced range of soil hydrotransport due to congruent increase the passport pressure characteristic of submerged water dredging pump for the amount of static and dynamic backwater, and due to the dilution of the hydraulic mixture by pumping water with an ejector water pump.

The problem is solved as follows. In the dredging device of the dredger, including the electric drive dredge pump, its suction and pressure pipelines, the ejection system, which consists of an ejector water pump with its suction and pressure pipelines for supplying water to the flow mixing chamber located on the suction pipe of the soil pump, the ejection system is equipped with a pressure pump ejector water pump pipeline annular water collector with hydraulic nozzles for supplying water to the flow mixing chamber having a conic ical shape and disposed on the suction pipe immersed under the water level at the bottom gruntonasosa. In the suction pipe of the submersible pump submerged beneath the water level, the cavitation reserve is increased by the sum of the static and dynamic backwater. At the same time, a relatively small value of the static backwater allows you to avoid structural complications in the bow of the dredger, and a relatively small value of the dynamic backwater allows you to use a regular water pump mounted in the engine room of the dredger, that is, you can do without additional emergency equipment at the minimum one-time costs. Due to the increase in the cavitation reserve, the depth of non-cavitation underwater excavation increases by a factor of 2–3, or (by priority) the soil productivity of the dredger increases by a factor of 1.5–2. Additional pressure steps equal to the values of the static and dynamic supports, respectively, as well as the dilution of the hydraulic fluid mixture by pumping water with an ejector water pump into the transport line of the soil pump submerged under the water level in the bottom of the pump, can increase the reduced range of soil transportation up to 15-30%. Moreover, the summation of the effects of immersion under the water level in the bottom of the soil pump and from ejecting its suction pipe allows avoiding complications that occur when the immersion and ejection are separately used, for example, installing additional bow pontoons to increase the longitudinal stability of the dredger, strengthening the design of the frame of the dredging device and replacing the frame-lifting device winches for a more powerful installation of an emergency system of the ejector water pump with increased operating parameters, etc.

The drawing shows the proposed soil intake device dredger. The device includes a submersible soil pump 1 with an electric drive 2, a suction pipe 3 and a pressure pipe 4, an ejection system consisting of an ejector water pump 5, a suction 6 and a pressure pump 7 of an ejector water pump, an annular water collector 8 and hydraulic nozzles 9 that supply water from the water the ejector pump into the mixing chamber of the flows 10 from the ejector water pump and the suction pipe of a conical shaped submersible soil pump located in the suction pipe of the submerged the water level in the mine gruntonasosa.

The device operates as follows. Submersible soil pump 1 is immersed under the water level by the value of Z _Art . An ejection system (ejector water pump 5 → pressure pipe 7 → annular water collector 8 → hydraulic nozzles 9) in the mixing chamber 10 creates a dynamic back pressure Zd on the suction pipe of the submersible soil pump. Due to the total effect of the immersion of the submersible soil pump and the ejection of the suction pipe of the submersible soil pump, its cavitation reserve increases by the amount of Z _st + Z _d . An increased cavitation reserve of a submersible soil pump is realized either by increasing the depth of underwater excavation with a constant dredger productivity, or by increasing soil productivity with a constant depth of underwater mining. If necessary, they realize an additional positive effect - a substantial increase in the reduced range of soil hydrotransport due to both a congruent increase in the passport pressure characteristics of the submersible soil pump by the sum of the static and dynamic backwater, and due to the dilution of the hydraulic mixture by pumping water with an ejector water pump.

Production tests of a removable soil sampling device for a 180-60 dredger using a GrUT 2000/63 submersible soil pump showed that when a submersible soil pump is immersed only 3 m and using a standard water pump of the D200 / 95 ejector, the depth of underwater excavation can be increased by 10 m without reducing soil productivity dredger. At the same time, due to the full working out of the quarry, the number of permutations of the dredger in the face was reduced by 30%, which, in turn, led to an increase by 5% in the utilization factor of the working time of the dredger. A good agreement between the calculations and the actually achieved results was also confirmed. The reduced range of soil hydrotransport increased by 20% without reducing the soil productivity of the dredger. Structural modifications of the soil frame and the bow of the dredger were completely excluded.

Claims (1)

A suction dredger suction device, including an electrically driven soil pump, its suction and pressure pipes, an ejection system, consisting of an ejector water pump with its suction and pressure pipes for supplying water to the flow mixing chamber located in the suction pipe of the soil pump, characterized in that the ejection system is provided an annular water collector connected to the pressure pipe of the ejector water pump with hydraulic nozzles for supplying water to the mixing chamber shackles having a conical shape and disposed in the suction pipe immersed under the water level at the bottom gruntonasosa.