Valve of a hydraulic circuit with constant pressure drop

Abstract

A pressure valve including a body including at least one admission opening and at least one discharge opening, a slide valve sliding in the body, the slide valve defining a chamber, with the body, and including a head arranged facing a seat of the admission opening, a spring pressing the head of the slide valve against the seat, a lip for applying the head to the seat. The head includes at least one hole bringing the chamber into communication with the discharge opening, each hole being arranged facing the seat and downstream from the lip in relation to the admission opening in order to reduce the pressure in the chamber by a Venturi effect when the slide valve is open.

Claims

1. A pressure valve comprising: a body including at least one discharge opening and at least one intake opening provided with a seat, a fluid being able to pass from upstream to downstream from the intake opening to the at least one discharge opening, a slide valve sliding in a housing of said body opposite the seat, said slide valve including a cylindrical skirt closed by a head to delimit with said housing a chamber, a spring tending to bring a flank of the head closer to a face of the seat, a sealing lip by which the flank of the head and the face of the seat are maintained at a distance when the head is bearing on the seat under the action of the spring, the head including at least one hole passing through the flank of the head to communicate the chamber with at least the at least one discharge opening, a first end of the at least one hole opening into an inner diameter of the spring, a second end of the at least one hole opening into an annular space communicating with the at least one discharge opening, being located opposite the face of the seat and downstream of the sealing lip relative to the intake opening, said at least one hole extending in a direction perpendicular to the face of the seat, said annular space delimiting with the sealing lip a widening forming a diverging portion for the fluid passing through the pressure valve in order to reduce the pressure in the chamber by a Venturi effect when the slide valve is open, wherein the flank of the head and the face of the seat that carries the sealing lip are conical and the flank of the head and the face of the seat are parallel.

2. The pressure valve according to claim 1, wherein the housing has a shape of a cylindrical blind hole having an internal diameter corresponding to an external diameter of the cylindrical skirt.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a sectional view of a valve known from the prior art;

(2) FIG. 2 is a graph representative of the increase in the pressure drop C with the increase in the flow D and in the pressure P with the valve known from the prior art, from a threshold opening pressure P0;

(3) FIG. 3 is a sectional view of a valve according to the invention;

(4) FIG. 4 is a detail sectional view of the fluid flow in the vicinity of the seat in the valve according to the invention;

(5) FIG. 5 is a graph showing the very small variation in the pressure drop C with the increase in the flow D and the pressure P with the valve according to the invention from an opening threshold pressure P0.

DETAILED DESCRIPTION OF PARTICULAR EMBODIMENTS

(6) In FIG. 3, the pressure valve according to the invention which is identified by 11 includes a body 12 wherein is mounted a sliding valve 13 with a system for returning in a position (or else biasing element) such as a spring 14 tending to press this slide valve against a seat 16 of an intake opening 17 of this body 12 (which can be produced with several parts) which also includes one or more discharge openings 18 and 19. The discharge opening(s) may be freely located behind the seat.

(7) The slide valve 13 is located opposite the seat 16 of the intake opening 17, this seat 16 thus delimiting the internal mouth-piece of this opening 17. The slide valve 13 is mounted in a corresponding housing 21 of the body 12, located opposite the seat 16.

(8) This slide valve 13 has a general shape of revolution, comprising a cylindrical skirt 22 which is open on the side of the housing 21 and which is closed by a slide valve head 23 opposite the seat 16.

(9) As can be seen in FIG. 3, the housing 21 has the shape of a cylindrical blind hole having an internal diameter corresponding to the external diameter of the skirt 22, so that the slide valve 13 slides in the cylindrical housing 21, delimiting jointly with the latter an internal chamber 24 whose volume decreases when the slide valve moves away from the seat 16 and increases when it is pressed against this seat 16 by the spring 14.

(10) The head 23 of the slide valve has a general conical or spherical shape to form a contact surface 26, also called seat.

(11) As can be seen more clearly in FIG. 4, the seat 16 includes a circumferential edge or rib 28 which surrounds the opening 17 at its internal mouth-piece projecting towards the valve. This edge 28 is internally delimited by a conical crown 29 face located opposite the flank 26.

(12) Additionally, the seat 16 includes at its base, that is to say in the region through which the conical or spherical ring 29 is connected to the cylindrical internal face of the intake opening 17 a circumferential flange or lip 31, which projects from the conical crown 29 in the direction of the conical or spherical flank 26.

(13) When the slide valve 13 is closed, its conical or spherical flank 26 is bearing on the lip 31 to establish a sealed closure, and an annular region 32 remains between the flank 26 and the crown 29 which extend parallel to each other while being radially distant from each other.

(14) In addition, the head 23 of the slide valve includes one or more through holes 33 formed through the wall delimiting the flank 26 and which open into the chamber 24 of the slide valve 13 in order to communicate it with the annular region 32, that is to say with the discharge opening(s) 18, 19.

(15) As can be seen in FIG. 4, the lip 31 delimits with the annular space 32 a widening forming a diverging portion which allows generating an aspiration effect when a flow passes through the valve 11. In other words, and as illustrated in FIG. 4, the current lines LC move apart from each other when they enter into the annular space 32 forming a diverging portion.

(16) More particularly, when the pressure in the intake opening 17 exceeds a threshold depending in particular on the stiffness and the pretension of the spring 14, the slide valve 13 retracts in the housing 21 by sliding against the spring 14, so that the flank 26 substantially moves away from the lip 31, which delimits a fluid passage section in the shape of a conical or spherical crown.

(17) After having crossed this passage section, the fluid reaches the annular region 32 which provides a larger passage section because the face 29 is radially set back relative to the lip 31. Due to this increase in the passage section, the fluid undergoes a Venturi effect so that its pressure decreases, which generates an aspiration effect through the holes 33 causing a reduction in the pressure in the chamber 24.

(18) The holes 33 thus constitute depressurisation holes in the chamber 24: the pressure in these holes is lower than the outlet pressure thanks to the suction effect caused by the Venturi effect resulting from the passage of the fluid in the diverging annular region 32 downstream of the lip 31.

(19) As can be seen in FIG. 3, the chamber 24 being substantially sealingly delimited by the housing 21 and the slide valve 13, the reduction in the pressure in this chamber 24 causes an increase in the setback of the slide valve, the flank 26 of which deviates more strongly from the lip so as to increase the fluid passage section.

(20) Thanks to this operation, an increase in the flow when the valve is open tends to open this valve more strongly to increase the passage section. More concretely, at first, an increase in flow results in a greater speed of the fluid through the annular region 32, which increases the Venturi effect, and thereby the pressure drop in the holes 33 and in the chamber 24. This decrease in the pressure in the chamber 24 causes a greater setback of the slide valve 13, that is to say an increase in the passage section when the flow increases.

(21) Thus, the pressure drop introduced by the valve is substantially constant due to the fact that the passage section provided by this valve fluctuates with the flow. Under these conditions, it is possible to dimension the valve to obtain a pressure drop C which is substantially constant relative to the flow D passing through the valve, as illustrated by the curve C in FIG. 5, which shows the slight change in pressure drop denoted P with the flow.