RU2013540C1 - Impact device - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: impact device is additionally provided with a drain chamber which is alternately connected to a drain line (during the idle stroke of the hammer) or to the lead-up chamber and to the operation stroke chamber (during the operation stroke). There is a chamber made under an elastic diaphragm which is constantly connected to the operation stroke chamber via channel made in the body of the device. EFFECT: enlarged operating capabilities. 2 dwg

Description

 The invention relates to a high-energy propelled pneumohydraulic hammer designed for splitting, crushing, breaking rocks of rock-like materials, reinforced concrete, metallurgical waste, ferroalloys and other high-strength materials. The main field of application is mining pits, a hammer as a replaceable working tool, fixed by means of a damper mechanism on the boom of an excavator of the corresponding standard size.

 Hydraulic shock devices are known in which the striker is accelerated when the working fluid flows from the platoon cavity into the working stroke cavity, for example, a Finmer Rammer type hydraulic hammer S1600ND (USSR patent N 1422988), including a housing with a striker movably located in it, a spool valve , pressure valve and accumulator.

 The main disadvantage of this hydraulic hammer is its low efficiency due to the fact that the overflow of the spent liquid from the platoon cavity to the drain tank takes place through the working cavity, which is constantly in communication with the gas cavity through an elastic membrane. In this device, for energy storage during cocking, it is necessary that the discharge of the spent liquid from the cavity of the working stroke occurs through hydraulic resistance, which creates a pressure drop that exceeds the differential pressure of the compressed gas in the gas cavity. For this, a pressure valve is installed on the drain line.

 A shock device (ed. St. N 1493778) is known, comprising a housing forming an idling chamber with a piston-hammer, and a working chamber communicating alternately with a pressure or drain line via a spool valve and a normally open valve with a control chamber. This device has a higher efficiency, since it has a working chamber through which the spent liquid is drained into the tank, at the beginning of the idle of the drummer it is open to drain and the liquid enters the drain at a small pressure drop.

 The described devices are characterized by a common drawback: controlling the operation of the percussion device using three elements - a spool valve, pressure or control valve, bores and channels on the hammer and in the device body. For normal operation of devices in which the firing pin is used to distribute the flow of the working fluid, it is necessary that the diametrical gaps between the guiding surfaces of the body and the firing pin are not more than 0.03-0.06 mm. All this complicates the design of the device and the manufacturing technology of the main parts, in addition, with relatively small wear of the guide surfaces of the main parts, the operation of the device is disrupted.

 By author St. N 1273535 known percussion device, comprising a housing forming with a hammer, having a rod with a groove and a piston, cocking, overflow and accumulating chambers, and a step valve with a bore in the lower part mounted on the rod with the possibility of axial movement.

 The control of the drummer in this device is carried out by means of one step valve, which provides periodic communication between the cocking and overflow cavities. The passage channels with the valve open have large cross sections, which ensures the flow of the working fluid from the platoon cavity into the working cavity of the striker with minimal energy loss.

 However, in this device, the control of the step valve in the forward position of the hammer is provided by a groove in the hammer rod. This leads to a violation of the diametrical gaps on the guide surfaces and gas leakage through the elastic seals, which negatively affects the performance of the device and its reliability.

 The purpose of the invention is to improve the operational characteristics of the percussion device controlled by one step valve located coaxially to the projectile, to exclude refueling of the gas cavity in the field conditions of the device, to reduce the pulsation of the working fluid in the pressure line when it flows from the cocking cavity into the working during the working stroke of the hammer , i.e., increase the frequency of shock of the device by increasing the volumetric efficiency, increase its efficiency.

 To this end, in a device including a housing, in the bore of which a hammer with a piston protrusion and a stepped control valve are installed coaxially, forming an accumulator cavity, a platoon and a working cavity, a pressure cavity constantly connected with a pressure source and a platoon cavity and periodically with the cavity with the bores of the housing stroke, drain line, pressure accumulator with an elastic membrane, the hydraulic chamber of the accumulator is constantly in communication with the cavity of the stroke, and the housing of the device with The pressure accumulator has a rod located in its accumulator cavity, a drain chamber is formed in the hammer rod, which is included in the accumulator cavity, with the possibility of placement in the last rod of the housing, while the drain chamber is provided through a central axial channel made in the rod body, channel and bores in the housing devices and annular grooves of the stepped valve has the ability to periodically communicate with the hydraulic chamber of the accumulator or with a drain line.

 These design features made it possible to achieve a volumetric efficiency of the device close to 100% and a high shock frequency (400-600 beats / min).

 In FIG. 1 is a schematic diagram of a percussion device; in FIG. 2 - node I in FIG. 1.

The impact device consists of a housing 1, in the guides 2 and 3 of which the hammer 4 is movably mounted with the tool 5 fixed in its lower part. In the middle part of the hammer 4 there is a piston protrusion with a stage 6 of diameter D ₃ and a stage 7 of diameter D ₄ . The lower part 8 of the hammer 4 has a diameter D ₁ . The diameter D _{2 of the} upper part 9 of the hammer 4 is smaller than the diameter D _{1 of} its lower part 8.

 In the housing 1 from the side of the hydraulic accumulator 10 there is a rod 11 with an axial channel 12 located in the battery cavity 13 of the housing 1. The rod 11 is coupled to a guide 14 of the drain chamber 15 made in the rod of the hammer 4. This drain chamber 15 is isolated from the battery cavity 13 by means of a soft seals.

The piston protrusion of the striker 4 by stage 6 is constantly in contact with the inner surface of the sleeve 16 located in the housing 1. The internal cavity of the sleeve 16 is divided by the piston protrusion of the striker 4 into a platoon cavity 17 and a working stroke cavity 18. The platoon cavity 17 is connected through holes 19 with an annular channel 20 formed by the bore of the housing 1 and the outer surface of the sleeve 16. A stepped valve 21 is installed in the cylindrical bore of the housing 1 with the possibility of longitudinal movement. The working edge 22 (see Fig. 2) of the valve 21 is in contact with the conical surface 23 of the sleeve 16. In this case, the diameter D _{5 of the} working edge 22 of the valve 21 is larger than the diameter D ₆ (see Fig. 1) of the tail of the valve 21. The valve 21 (see Fig. 2) below (according to the drawing) its working edge 22 has a cylindrical girdle 24, which is out the surface is mated with the surface of the bore 25 of the housing 1. A pressure source 26 through the pressure line 27, channel 28 and holes 29 (see Fig. 2) made in the body of valve 21, an annular gap 30 between the valve 21 and the sleeve 16 and the annular channel 20 in the housing 1 and the hole 19 communicates with the cavity 17 of the platoon, and when opening the control step valve 21 through the annular gap between the working edges of the valve 21 and the sleeve 16 - with the cavity 18 of the stroke. The cavity 18 of the stroke through the channel 31 is constantly connected to the chamber 32 under the elastic diaphragm 33 of the accumulator 10.

 The drain chamber 15 in the rod of the hammer 4 through the axial channel 12 in the rod 11 of the housing 1, the channel 35 in the housing 1, the annular groove 36 on the control step valve 21, the bore 37 and the channel 38 in the housing alternately communicates with the drain line 39 or through the annular groove 36 in the valve 21, the bore 40 in the housing 1, the channels 41 and 31 with a cavity 18 of the stroke and a hydraulic cavity with a chamber 32 of the hydraulic accumulator 10.

 The battery cavity 13 of the device may be in communication with the atmosphere or filled with compressed gas.

 The device operates as follows.

 In the initial state, the striker 4 is in its lowest position, resting tool 5 in the processed material 34 or step 6 in the lower end wall of the cavity 17 of the platoon.

 The control valve 21 with its working edge 22 is in contact with the conical surface 23 of the sleeve 16. In this case, the cocking cavity 17 through the openings 19, the annular channel 20, the openings 29, the pressure pipe 27 is connected to the pressure source 26. The working stroke cavity 18 is constantly in communication with the channel 31 with hydraulic chamber 32 under the diaphragm 33 of the hydraulic accumulator 10. The drain chamber 15 through the channel 35 in the housing 1, the grooves 36 on the control step valve 21, the channel 38 is connected to the drain line 39.

, где Р_взв. - давление жидкости в полости взвода 17;
Р_р.х. - давление жидкости в полости 18 рабочего хода.When the working fluid from the pressure source 26 in the cavity 17 of the platoon increases the pressure. Upon reaching a fluid pressure equal to
P _arr. = P _r.x ·

where P _arr. - fluid pressure in the platoon cavity 17;
R _r.h. - fluid pressure in the cavity 18 of the stroke.

 Drummer 4 begins to move upward, idling and displacing fluid from the working space cavity 18 through channel 31 to chamber 32 under diaphragm 33 of hydraulic accumulator 10. The fluid located in drain chamber 15 passes through channel 35, groove 36, and channel 38 to drain line 39.

(D₅ ²-D₆ ²).In this case, the control valve 21 with its working edge 22 is pressed against the conical surface 23 of the sleeve 16 by a force equal to
P = P _pl. ·

(D ₅ ² -D ₆ ² ).

 Thus, the greater the fluid pressure in the platoon cavity 17, the greater the force with which the valve 21 is pressed against the conical surface 23 of the sleeve 16.

(D₁ ²-D₂ ²), где Р_ак - давление жидкости в газовой камере 32 гидроаккумулятора 10.At the end of idling, the protrusion of the stage 7 with a diameter D _{4 of the} hammer 4 enters the inner bore with a diameter of D ₉ . This movement continues until the upper end of the stage 6, in contact with the end face of the valve 21, lifts it, tearing its working edge 22 from the conical surface 23 of the sleeve 16. Between the edge 22 and the conical surface 23 a gap is formed through which a message occurs between the cavities 17 and 18. The pressure in both cavities becomes approximately the same. In this case, on the hammer 4 from the side of the cavity 18 of the working stroke is a force of fluid pressure equal
P = P

(D ₁ ² -D ₂ ² ), where R _ak - the pressure of the liquid in the gas chamber 32 of the hydraulic accumulator 10.

Under the action of this force, the striker 4 accelerates downward. The working fluid from the platoon cavity 17 through the openings 19, the annular channel 20, the slot 30 between the valve 21 and the sleeve 16 enters the cavity 18 of the working stroke. Due to the resistance of the specified gap between the cavities 17 and 18, a pressure differential is created. Due to this pressure differential, a force equal to the lower end of the cylindrical girdle 24 of the valve 21 acts
P ₁ = Δ P ₁ ˙ S, Δ P ₁ = K ₁ ˙ V _y ² , where P ₁ is the pressure drop between the cavities 17 and 18;
S is the area of the end face of the annular belt 24 of the valve 21;
V _y is the speed of the hammer 4;
To ₁ is the coefficient of proportionality.

 At this moment, under the action of the fluid coming from the pressure source 26, from the platoon cavity 17, the valve 21 moves up until the stage 7 of the hammer 4 comes out of the inner bore of the valve 21.

Between the pressure cavity A and the cavity 18 of the working stroke, a pressure difference P _{2 is established} due to the resistance to the flow of liquid through the holes 29, equal to
P ₂ = K ₂ ˙V _w ² = K ₃ ˙ Q ^{2 of the} _pump , where V _w is the fluid velocity in openings 29;
Q _pump - fluid supply from a pressure source 26;
K ₂ and K ₃ are proportionality coefficients.

At the first moment after the acceleration of the hammer 4, while its speed is small, the pressure drop Δ P _{1 is} small, and the pressure drop Δ P ₂ determined by the pump capacity is constant and exceeds the value Δ P ₁ . Therefore, the force 21 is directed downward and tends to reduce the gap between the working edge 22 of the valve 21 and the conical surface 23 of the sleeve 16.

[(D₁ ²-D₂ ²)+D₁ $\genfrac{}{}{0ex}{}{\text{2}}{\text{0}}$ ] , где Р_ак - давление жидкости в гидроаккумуляторе 10.As the striker 4 accelerates, the pressure drop Δ P ₁ increases in proportion to the square of the velocity of the striker 4 and, at a certain speed, the forces acting on the valve 21 from the bottom and top are balanced. The valve 21 stops, then it moves up, increasing the gap between the working edge 22 of the valve 21 and the surface 23 of the sleeve 16. This condition persists until the hammer 4 performs an accelerated downward movement. When the valve 21 is open, the closed drain chamber 15 through the channel 35, the groove 36, the bore 40 and the channel 41 communicates with the working cavity 18 and through the channel 31 with the hydraulic chamber 32 of the hydraulic accumulator 10. The force acting on the hammer 4 at the moment of its acceleration is determined by the equation
P _beats = P

[(D ₁ ² -D ₂ ² ) + D ₁ $\genfrac{}{}{0ex}{}{\text{2}}{\text{0}}$ ], where R _AK - the pressure of the fluid in the accumulator 10.

 At the end of its working stroke, the striker of the striker 4 strikes the processed material, there is a sharp braking and stop of the striker.

 In the absence of an obstacle (material to be processed), the piston protrusion (stage 6) of the striker 4 with its outer cylindrical surface overlaps the openings 19 and the liquid is displaced from the closed cavity through a narrow gap between the inner surface of the sleeve 16 and the outer surface of the stage 6. As a result, in this closed cavity high pressure, which acts on the lower end of stage 6, causing braking of the hammer 4 and its stop.

At the moment of stop of the striker 4, the fluid flow through the target 30 stops, and the pressure drop Δ P ₁ between the cavities 17 and 18 also disappears. As a result, the valve 21 moves down due to the difference Δ P ₂ down to the contact of its working edge 22 with the surface 23 of the sleeve 16. The pressure in the platoon cavity 17 rises and the striker 4 makes a repeated platoon stroke. Next, the cycle repeats.

 Thus, the introduction of a closed drain chamber 15 into the hammer 4, the separation of the gas cavity of the accumulator 10 with an airtight separation diaphragm 33, the groove 36 on the control step valve 21 made it possible, on the one hand, to achieve a volumetric efficiency close to 100% and, consequently, the maximum frequency of impacts .

 On the other hand, to increase the reliability of the percussion device by eliminating gas leaks from the gas cavity of the accumulator 10 due to the separation diaphragm 33.

Claims (1)

 SHOCK ACTION DEVICE, comprising a housing, in the bore of which a hammer with a piston protrusion is coaxially mounted, the diameter of the stem of which under the piston protrusion exceeds its diameter above the piston protrusion, and a control step valve with an annular bore, a hammer and a control valve form an accumulator cavity with a cavity of the platoon and the stroke of the striker, the pressure cavity constantly in communication with the pressure source and the cavity of the platoon and periodically with the cavity of the stroke, drain line, hydraulic pressure accumulator with an elastic membrane dividing its cavity into gas and hydraulic chambers, characterized in that the hydraulic chamber of the pressure accumulator is constantly connected to the working stroke cavity of the hammer, while the housing on the side of the hydraulic accumulator has a rod located in the battery cavity, and above a piston protrusion is formed drain chamber with the possibility of placement in the last rod of the housing, while the specified camera through the Central axial channel made in the rod body a, the channel and the bores made in the device body, and the annular groove of the control step valve has the possibility of periodic communication with the hydraulic chamber of the hydraulic accumulator, or with a drain line.

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