RU2011779C1 - Hydraulic hammer - Google Patents

Abstract

FIELD: mining art. SUBSTANCE: the hydraulic hammer has a delivery valve spring-loaded relative to the seat and mounted in a hollow body above an adapter, pusher. The pusher is spring-loaded from the top by a piston with a hollow rod. The piston is located on the rod. The lower end of the rod is fixed on the upper end of the delivery valve for restricted axial movement. One end of the pusher is connected to the block head valve, and the other is located inside the delivery valve for restricted axial movement. Channels are provided in the seat of the delivery valve and in the bottom part of the rod for passage of flushing fluid. In the top part of the body provision is made for radial channels for communication of the space above the piston with the hole clearance. EFFECT: facilitated procedure. 4 dwg

Description

 The invention relates to the field of mining, namely to hydraulic hammers of exploratory drilling of wells.

 Hammers are of various designs, but in practice, direct impact hammers are most widely used as the simplest in design and reliable in operation.

 The well-known hydraulic hammer, adopted for the prototype, contains a hollow cylindrical body, inside of which there is an upper adapter, a lower spline adapter with an anvil, spring-loaded relative to the anvil of the hammer with a hollow rod and a spring-loaded striking valve located in its upper part.

 The work of the hammer is associated with controlling the flow of injection fluid and the formation of hydraulic shock, due to which forces are created for the reciprocating movement of the hammer and delivering useful blows to the anvil. This is due to the automatic closure of the striker valve in the upper and opening in the lower positions of the striker. After opening the valve, the firing pin moves by inertia until it hits the anvil. This range of motion is called the striker’s free travel, which in modern hydraulic hammers is 3-5 mm. The impact energy of the hammer and the anvil forms the useful energy of the impact of the hammer.

 A disadvantage of the known hammer is the low efficiency of the hammer due to the increase in the total mass of the excitation of the shock wave and the inefficient flow rate of the working fluid during the return stroke of the hammer.

 The aim of the invention is to increase the efficiency of the hammer at a low flow rate of flushing fluid.

 This goal is achieved by the fact that the hammer, containing a hollow cylindrical body, inside of which there is an upper adapter, a lower spline adapter with an anvil, spring-loaded relative to the anvil of the strikers with a hollow rod and a spring-loaded action valve located in its upper part, is equipped with a spring-mounted housing installed in the floor above the upper adapter a pressure valve, spring-loaded relative to the seat, a pusher, a piston spring-loaded from above and a hollow stem, the piston being placed on the stem, the lower end of The other end is mounted on the upper end of the discharge valve with the possibility of limited axial movement, with one end of the pusher connected to the striker valve and the other end of the pusher mounted inside the discharge valve with the possibility of limited axial movement, radial channels for passage are made in the seat of the discharge valve and in the lower part of the stem flushing fluid, and in the upper part of the housing there are made radial channels communicating the cavity above the piston with the annulus of the well.

 As a result of this technical solution, it becomes possible to significantly increase the effective power of the hammer at low flow rates of flushing fluid compared to the prototype. This is achieved by the fact that in the injection system, in the immediate vicinity of the hydraulic hammer, a single circulating system of fluid flow breaks down with a kind of spring accumulator of potential energy during the reverse stroke of the striker and converts it into kinetic with direct active stroke.

 Calculations show that the proposed technical solution allows, ceteris paribus, to increase the energy of a single blow in comparison with the prototype 1.3-1.5 times with a corresponding overall increase in the effective power of the hammer and efficiency. The effect is significantly increased if the hammer is installed above the bit during coreless drilling.

 In FIG. 1 shows a longitudinal section of a hydraulic hammer; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 is a section BB in FIG. 1; in FIG. 4 is a section BB of FIG. 1.

 The hydraulic hammer includes a spline adapter 1, a spline coupling 2, an anvil 3, a spike 4 with a spring 5, a stem 6 a spike, a middle adapter 7 with a sealing collar 8, a shock valve 9 with a spring 10, an upper adapter 11, a pressure valve 12 with a spring 13, sockets 14 valves with through holes 15, pusher 16, pins 17 to limit the lower stroke of the pusher 16, as well as an injection chamber made in the form of a cylinder 18 with side holes 19, a head 26 with a stem 20, an annular piston 21 with cuffs 22 and a power spring 23 and connection housing 24. V 20A is a channel 25 connecting the lower portion of the pump chamber cavity with drill pipe.

The work of the hammer is as follows. The hydraulic hammer is installed as part of the drill over the rock cutting tool (for core drilling - above the core set) and is in the initial position in a suspended state, i.e. the rock cutting tool does not come into contact with the bottom hole. In this case, the spline adapter 1, together with the striker 4, lowers down and forms a gap between the end face of the rod 6 and valve 9. The discharge valve 12 under the action of the spring 13 will be open by the value S ₃ . When the flushing fluid is injected into the well, it freely passes through the slotted gaps between the valve 9 and the socket 14, as well as the valve 9 and the end face of the rod 6 directly to the bottom of the well. The launch of the machine is carried out with the setting of the drill to the bottom of the well. As a result of this, the spline adapter 1 together with the striker 4 rises up and the end face of the rod 6 joins the valve 9. The fluid flow is blocked with the formation of hydroshock pressure, which creates a force to move the rod 6 with the striker 4 and the valve 9 down. The striker accelerates with the simultaneous compression of its spring and valve spring. The process of acceleration of the striker 4 - the active stroke - continues until the stop of valve 9 in the middle adapter 7. Simultaneously, the valve 12 settles through the pusher 16 due to its stop in the pins 17. In the future, the striker 4 moves by inertia by the amount of free travel S ₂ until the collision with an anvil 3. At this point, fluid will get free passage to the bottom of the well with a significant increase in the pressure head, due to which the valve 12 will close and the fluid flow will shut off with the corresponding hydraulic shock. Under the influence of hydraulic shock, an effort arises to move the piston 21 and compress the spring 23 with the accumulation of potential energy. At the same time, a rarefaction wave arises under the valve 12, which contributes to the return of the valve 9 under the action of the spring 10 to its initial upper position. After a collision with the anvil 3 firing pin 4 under the action of the force of the spring 5 will return to its original upper position. The articulation of the stem 6 of the striker and valve 9 will be accompanied by a collision, under the action of which the valve 12 will open, and the generated liquid pressure in the injection chamber will cause the striker 4 to move with the stem 6 and valve 9 down to the stop of valve 9 in the adapter 7. The cycle is repeated.

 The use of the proposed hydraulic hammer will significantly increase its efficiency at low liquid flow rates by reducing overhead energy costs during the reverse stroke and using the potential energy of the liquid, which accumulates directly in the discharge chamber. This will increase the efficiency of hydroshock drilling of exploration wells.

Claims (1)

 A hydraulic hammer containing a hollow cylindrical body, inside of which there is an upper adapter, a lower spline adapter with an anvil, spring-loaded relative to the anvil of the hammer with a hollow rod and a spring loaded hammer valve located in its upper part, characterized in that, in order to increase the efficiency of the hydraulic hammer at small liquid flow rate, it is equipped with a discharge valve installed in a hollow body above the upper adapter, spring-loaded relative to the seat, pusher spring-loaded from above a piston and a hollow rod, the piston is placed on the rod, the lower end of which is fixed to the upper end of the discharge valve with limited axial movement, one end of the pusher connected to the hammer valve, and the other end of the pusher mounted inside the discharge valve with limited axial movement, moreover, in the saddle of the discharge valve and in the lower part of the rod channels are made for the passage of flushing fluid, and the upper part of the housing is made of radial channels communicating spine above the piston to the annulus of the well.

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