PL74175Y1 - Controlled check valve - Google Patents

Abstract

The application concerns a controlled check valve, used particularly in hydraulic systems of powered roof supports. The valve piston (3.3) is mounted in a cylindrical guide (3.2) of the valve insert (3) with a fit tolerance of the outer diameter d₂ in the inner diameter d₁ of the cylindrical guide (3.2), constituting the radial run-out deviation for the rotary connection. Preferably, the outer diameter d₂ of the valve piston (3.3) relates to the outer diameter d₄ of the external control piston (4.3) as 0.65 ÷ 0.53. The valve insert (3) has a gland (3.10) connected to the cylindrical guide (3.2).

Description

Description of the design The subject of the utility model is a controlled check valve, particularly suitable for use in hydraulic systems of powered mining roof supports.

In conditions of very high rock mass pressures affecting powered support sections, it is necessary to use high-flow hydraulic valves in their casings.

Such valves are susceptible to hydraulic vibrations, which significantly reduce their efficiency and, consequently, their service life and operational reliability over time. Reducing this phenomenon has been achieved by designing externally controlled valves with two-stage opening and passage throttling.

Known, for example, from the description of a Polish utility model, is a controlled check valve with a cylindrical body equipped with holes in the side walls containing a valve insert, releasably and non-slidably mounted above the hydraulic fluid inlet. The valve insert consists of a lower sleeve, a center ring, and an upper sleeve, inside which is a differential chamber with a slidably mounted valve cone. A slidably mounted control piston is located inside the valve insert, its upper end releasably attached to a tension piston, which is expanded by a spring mounted in a screw screwed into the upper sleeve of the valve insert. The valve cone is expanded by the spring against the upper surface of the differential chamber.

The control piston is an integral element with the piston, with a diameter gradually decreasing upwards. It is mounted at the lower end of the lower sleeve above the bottom of the body. In its central part, below the center ring, the control piston has an offset against which the valve cone face rests. This design of the controlled check valve allows for a two-stage opening of the hydraulic medium outlet, which is intended to prevent dynamic hydraulic vibrations.

The purpose of the utility model is to further improve the design of a controlled check valve, used in hydraulic systems with very large flows of hydraulic medium, with relatively minor design changes.

A controlled check valve with a cylindrical body has, at one end, a coaxial valve insert with adjustable position mounted in the valve chamber, and within it, a valve piston with a conical head, slidable along the longitudinal axis by means of a spring, is mounted. This valve piston has a conical head, closing the annular opening of the valve seat and regulating the flow of the medium through the valve insert to the receiver port. At the other end, in the body's control seat, there is an external control piston, slidable along the longitudinal axis, below the stop ring, and inside it, an internal control piston, also slidable coaxially and expanded by a spring, with an axial pusher with a free end located under the conical head. valve piston. The essence of the utility model is that the valve piston is slidably mounted in the cylindrical guide of the valve insert with a fit tolerance of the outer diameter in the inner diameter of the cylindrical guide constituting the radial run-out deviation for the rotary connection, wherein the stroke of the outer control piston in the control chamber is less than the distance between the surface of the valve seat and the lower edges of the inlet holes of the valve insert, while the stroke of the inner control piston in the outer control piston is not less than the distance between the surface of the annular valve seat of the valve insert and the upper edges of the valve insert holes.

Preferably, the outer diameter of the valve piston is in the range of 0.65 to 0.53 of the outer diameter of the external control piston.

It is also advantageous when the valve insert is connected to the upper part of the cylindrical guide via a throttle.

The main advantage of the check valve controlled according to the utility model is the selection of the hydraulic medium flow which, in the first stage, allows for partial lifting of the conical valve head and partial flow of the hydraulic medium through the gap resulting from the tolerance of the rotational seating of the valve piston in the valve chamber, and the second stage occurs after the pressures behind and before the conical head are equalized and the valve insert holes are opened by lifting the conical valve head with the pusher of the internal control piston above the upper edge of these holes. As can be seen, during control, a smooth, continuous flow of hydraulic fluid through the valve chamber occurs without water hammer, which is crucial for protection against destructive hydraulic vibrations. Matching a specific control check valve to the hydraulic fluid flow rates intended in the hydraulic supply system is relatively easy to achieve by appropriately matching the outside diameter of the valve piston and the outside diameter of the external control piston. To relieve pressure in the upper part of the valve seat, the valve insert preferably has a throttle.

The utility model is presented in the drawing, where Fig. 1 shows a longitudinally cross-sectioned check valve with a schematic diagram of the connections in the hydraulic system, Fig. 2 shows a longitudinally cross-sectioned check valve with connections as in Fig. 1 in the first stage of valve piston control, and Fig. 3 shows a longitudinally cross-sectioned check valve with connections as in Fig. 1 and Fig. 2 in the second stage of valve piston control.

The controlled check valve 1, Fig. 1, has a cylindrical body 2, into which a valve insert 3 is screwed at one end through thread 2, and a control insert 4, also threaded 4, at the other end. The body 2 is equipped with through-flow supply connection sockets Z1, Z2 and return connection sockets Z3, Z4. The valve insert 3 has a cylindrical, coaxial valve chamber 3, inside which a valve piston 3 is slidably mounted in a cylindrical guide 3 and expanded by a spring 3a. The valve piston 3 is directed with its conical head 3 towards the valve seat 3, which is coaxially placed in the valve insert 3 below the holes 3 located radially on its circumference and connected by the valve chamber 3 to the connection socket Z1. The valve piston 3 has an outer diameter d2 and is slidably mounted in a cylindrical guide 3 with an inner diameter d1, with the tolerance of the outer diameter d2 in the inner diameter d1 representing the radial runout deviation of the rotary connection that would occur if these elements were rotatably connected. The position of the valve seat 3 is determined by a ring 3 mounted by a thread 3 in the tip of the valve insert 3. Below the ring 3, the cylindrical body 2 has a through-port connection socket Z2, which is connected to the valve seat 3 and the conical head 3 of the valve piston 3.

The control insert 4 is screwed into the body 2 with a thread 4 so that its upper end is located below the connection socket Z2. In the control insert 4, an external control piston 4 is mounted coaxially in the control chamber 4, and in its internal cavity 4, an internal control piston 4 is mounted slidably along the longitudinal axis O and expanded by a spring 4. The internal control piston 4 is equipped with a push rod 4, led out under the conical head 3 of the valve piston 3 and guided in a sliding manner in a stop ring 4 at the upper end of the control insert 4. The control insert 4 has a circumferential chamber 4 connected to the downstream connection sockets Z3 and Z4. The external control piston 4 has an orifice of 40. The connection sockets Z2 and Z4 are connected to the control valve R, while the connection sockets Z1 and Z3 are connected to the hydraulic cylinder S.

At the same time, the external diameter d2 of the valve piston 3 is within the range of 0.65 to 0.53 of the external diameter d1 of the external control piston 4 and this ratio is selected taking into account the specific value of the hydraulic medium flow through the controlled check valve 1. The stroke L1 of the external control piston 4 in the control chamber 4 is smaller than the distance L2 between the surface of the valve seat 3 and the distal edges 3a of the inlets of the holes 3 of the valve insert 3, while the stroke L3 of the internal control piston 4 in the external control piston 4 is not smaller than the distance L4 between the surface of the valve seat 3 of the valve insert 3 and the upper edges 3b of the holes 3 of the valve insert 3. Thanks to the strokes L1, L2, L3 and L4 selected in this way, it is possible to properly open the hydraulic medium flow in two stages with the first stage being sufficiently advanced to the second stage, while eliminating the abrupt increase in flow. It is also advantageous for such control of the hydraulic medium flow to equip the valve insert 3 with a throttle 30, connected to the upper part of its cylindrical guide 3.

In the natural position of the control valve lever R (fig. 1), the connection ports Z2 and Z4 of the controlled check valve 1 are connected through the control valve R to the flow line, and then the conical head 3 of the valve piston 3 is pressed by the spring 3a against the valve seat 3, closing the outflow of hydraulic fluid from the space under the piston of the actuator S, preventing the slide of this actuator S. Switching the control valve R to a position that allows the hydraulic fluid to flow to the connection port Z4 (fig. 2) and further through the connection port Z3 to the space above the piston of the actuator S. At the same time, the hydraulic fluid acts on the surface of the external control piston 4 of the control insert 4, which moves upwards. by stroke L1 until the external control piston 4 contacts the stop ring 4. Together with the external control piston 4, the internal control piston 4 moves with the push rod 4. The push rod 4 rests on the conical head 3 and, together with the external control piston 4, lifts it upwards by stroke L1. Due to the rotational tolerance of the valve piston 3 in the cylindrical guide 3, a partial flow of hydraulic medium occurs from the connection port Z2 through the valve chamber 3 to the flow port Z1, and at the same time, hydraulic fluid flows out from the space under the piston of the cylinder S through the controlled check valve 1 and the control valve R into the conduit of the shallow hole 3 of the valve system 3. The valve piston 3 remains covered by the valve piston 3, and the space between the cylindrical part of the valve piston 3 with diameter d2 and the cylindrical guide 3 with diameter d1 allows hydraulic fluid to pass through as a piston, which results in a constant, slow pressure drop of the hydraulic medium in the space under the piston of the cylinder S.

In the current connection, the check valve is controlled until the forces resulting from the action of pressure on the diameter d2 of the valve piston 3 are balanced with the force resulting from the action of the hydraulic medium pressure on the orifice 40 with the diameter d3 of the internal control piston 4. Then, a further pressure drop causes the internal control piston 4 to move inside the external control piston 4 until it reaches full stroke L3, which gradually opens the flow of hydraulic medium through the holes 3 of the valve insert 3 until they are fully open (Fig. 3).

As can be seen from the operating cycle of the controlled check valve shown above, the flow of the hydraulic medium under pressure increases gradually, thus preventing destructive valve vibration.

Claims (3)

Protective Disclaimers 1. A controlled check valve in a cylindrical body of which a coaxial valve insert with adjustable position is mounted at one end in the valve chamber, and a valve piston with a conical head is mounted in it, slidably along the longitudinal axis by means of an expansion spring, closing the annular opening of the valve seat and regulating the flow of the medium through the valve insert to the receiver port, while at the other end, in the body control seat, there is an external control piston mounted slidably along the longitudinal axis, below the stop ring, and inside it, also coaxially slidable and spring-expanded, an internal control piston with an axial pusher with a free end located under the conical head of the valve piston, characterized by in that the valve piston (3.3) is mounted in the cylindrical guide (3.2) of the valve insert (3) with a fit tolerance of the outer diameter (d2) in the inner diameter (d1) of the cylindrical guide (3.2) constituting the radial run-out deviation for the rotary connection, wherein the stroke (L1) of the external control piston (4.3) in the control chamber (4.2) is smaller than the distance (L2) between the surface of the valve seat (3.5) and the lower edges (3.6a) of the inlets of the holes (3.6) of the valve insert (3), while the stroke (L3) of the internal control piston (4.6) in the external control piston (4.3) is not smaller than the distance (L4) between the surface of the valve seat (3.5) of the valve insert (3), and the upper edges (3.6b) of the holes (3.6) of the valve insert (3). 2. A valve according to claim 1, characterized in that the outer diameter (d2) of the valve piston (3.3) is within the range of 0.65 to 0.53 of the outer diameter (d4) of the external control piston (4.3). 3. A valve according to claim 1, characterized in that the valve insert (3) is connected to the upper part of the cylindrical guide (3.2) via a throttle (3.10).