PL194598B1 - Valve, especially radiator valve - Google Patents

Abstract

The invention relates to a valve, especially a radiator valve for hot water heating systems. The inventive valve comprises a housing (1), two supply channels (2, 3) for the inlet and the outlet, a valve seat (4) and a spring-loaded closing member (5) that is actuated from the exterior and that covers the valve seat (4). Said closing member (5) has a piston (9) on the side facing away from the valve seat (4). Said piston sealingly extends into a cylinder chamber (10) whose effective pressure surface substantially equals the surface enclosed the by the valve seat (4). The cylinder chamber (10) communicates with the space within the valve seat (4). The valve is also provided with a zone (12) in which the cross-section of the closing member (5) increases towards the valve seat (4). An annular flange (13) is provided at the free end of the piston (9), partially overlaps said zone (12) and is subject to the pressure acting upon the zone (12). Accordingly, the valve can be used for both directions of flow.

Description

Description of the invention

The invention relates to a valve, in particular a radiator valve for heating installations supplied with hot water, having a housing, two connection channels for inlet and outlet, a valve seat and an externally actuated valve, spring-loaded and covering the valve seat.

Known valves of this type, such as that described in DE 44 02 752 A1, are designed for the flow direction in which the inlet pressure acts in the opening direction of the shutter. When operated in the opposite direction of flow, the shutter would be loaded with inlet pressure in the closing direction, so that, with the valve closed, the force exerted by the opening spring would not be sufficient to open the valve.

In a closing device for liquid media, in particular high-pressure liquids, shown in US Patent 3,680,832 and illustrated there in Fig. 2, the cylindrical shutter is inserted into an O-ring, and on the other at the end it has a larger diameter piston which travels in a sealed way in the cylindrical chamber. The cylindrical chamber is connected by a pressure reducing channel to the opposite side of the shutter. The difference in diameter results in an annular space surrounding the disc and sealed at both ends in the axial direction.

The object of the invention is to design a radiator valve that will be able to operate in both flow directions.

In the valve according to the invention, the plug has a piston on the side opposite to the valve seat, sealingly engaging the cylindrical chamber, the working pressure surface of which is substantially equal to the area enclosed by the valve seat, and the cylindrical chamber is connected to the space inside the valve seat.

As a result, the larger surface of the shutter is pressure relieved in both flow directions and, in a particularly preferred case, completely pressure relieved. Therefore, the surfaces that can be affected by the pressure acting in the flow direction are small or not present at all. The closing forces exerted by the flowing medium are therefore so low that they can be overcome by the opening spring without any difficulty.

Thus, it is possible to operate the valve in both directions of medium flow. When designing an installation, for example a heating installation, it is therefore not necessary to pay attention to the direction of flow, which allows for considerable simplification. Only small thermostatic elements with low actuating forces are sufficient for actuating the valve.

It is also advantageous for the valve according to the invention to have at least one channel connecting both face sides thereof. This leads to a particularly simple construction.

It is also suitable for the valve according to the invention to have a zone in which its cross-section increases towards the valve seat, and that the annular flange at the free end of the piston partially covers this zone and is subjected to the pressure acting on this zone. This covering causes a partial pressure reduction, so that the closing forces can be further reduced.

In this case, in the valve according to the invention, it is preferable that the increase in the cross-section in this zone is formed by a cone, against which the cylindrical section provided with an annular flange abuts.

It is also particularly advantageous that the valve plug or valve seat is made of an elastic material. This improves the sealing properties.

In order to prevent vibrations of the elastic element, which could occur in some cases, especially at high temperatures of the heat transfer medium, it is recommended that in the valve according to the invention, the valve seat is surrounded by a circumferential channel. The circumferential trough in conjunction with the flow cross section covered by the valve seat in both flow directions causes the upstream pressure to increase and the downstream pressure to drop, so that the forces exerted on the valve seat are largely mutually canceled out.

It is advantageous if, in the valve according to the invention, the depth of the circumferential channel gradually increases radially from the outside to the inside and is limited by the annular shaft situated on the circumferential wall of the valve seat. This ensures largely the same valve properties irrespective of the direction of flow.

PL 194 598 B1

It is particularly advantageous if the valve seat has a curved cross-section in the valve according to the invention.

The subject of the invention is shown below in a preferred embodiment in the drawing, in which:

1 shows a schematic cross-section of a valve according to the invention, FIG. 2 according to the invention for use in heat treatment in UJ, FIG. 3 shows the zone A of FIG. 2 in the fascia, FIG. 4 corresponds to the drawing of FIG. 3 in the opposite direction of flow.

The valve shown in FIG. 1 has a housing 1 with a first connection channel 2 and a second connection channel 3. The valve seat 4 is assigned a valve seat 5 which covers the valve seat 4 with its face 6. The position of the valve head 5 can be changed from the outside by means of led out through the seal 7 of the valve rod 8 by a force of an opening spring not shown in the drawing.

The valve 5 has on the side opposite to the valve seat 4 a piston 9 which is guided in a sealed manner in the cylindrical chamber 10. The cylindrical chamber is connected by means of channels 11 to the head side 6 of the valve 5 and, taking into account the cross-section of the valve rod 8, a pressure effective area of the cross-section equal to the area enclosed by the valve seat 4. This leads to a practically complete cancellation of the pressure exerted by the shutter 5 in relation to the pressure in the connection conduit 2.

On the outer side of the valve head 5 there is a zone 12, the cross-section of which increases towards the valve seat 4, so that the valve head 5 can also cover the valve seat 4. The piston 9 of the valve head 5 has an annular flange 13 which cuts partially onto the zone 12 and similarly to the valve seat 4. the zone 12 is exposed to the pressure from the connection channel 3, which causes a large or complete reduction of this pressure, taking into account the inlet zone between the valve head 5 and the valve seat 4. For this reason, the forces acting in both flow directions, towards the closing of the valve 5, are as follows small that they can be directly overcome by a spring not shown in the figure.

In the embodiment shown in Figs. 2 to 4, the counterparts of the components have been increased by 100. The housing 101 has a projection 115 which forms the connection channel 102 and the valve seat 104. The second connection channel 103 is located on the side of the cap 105 and is formed by a cut-out in the housing 101. The valve 105 is actuated by a valve rod 116 which is loaded by an opening spring 117 and delimited by a valve spindle 108 that has been led out through the seal 107 to the outside. Between the housing 101 and the shutter 105 there is an adjustment sleeve 119 rotated by a knob 120, which enables the cross-section of the connection channel 103 to be changed.

The shutter 105 has a piston 109 which is guided sealed in the cylindrical chamber 110. The cylindrical chamber is connected by channels 111 to the face 106 of the shutter inside the valve seat 104.

The pressure-active cross-section of the cylindrical chamber 110 is equal to the area of the cross-sectional area of the closure enclosed by the valve seat 104, which provides a complete pressure reduction with respect to the pressure in the connection conduit.

The zone 112, the cross-section of which increases with respect to the valve seat 104, is conical. This cone is partially affected by the annular flange 113 and, similarly to the cone itself, is influenced by the pressure from the connection channel 103. For this reason, again, there is a large or complete reduction in pressure taking into account the overlap zone between the valve seat 105 and valve seat 104.

The shutter 105 is made of a flexible material.

In order to avoid rattling or vibration of the obturator, the configuration shown in Figs. 3 and 4 is possible.

In this case, the valve seat 104 is surrounded by a peripheral channel 121. Its radial depth gradually increases from the outside to the inside. It ends at the peripheral wall of the valve seat 104, which is convex and has the shape of a projecting annular shaft 122.

PL 194 598 B1

With the flow direction as shown in FIG. 3, the circumferential trough 121 causes a large reduction in cross-section near the valve seat 104, which leads to a corresponding increase in pressure (shown by the symbol "+ +), while there is a corresponding increase downstream of the valve seat. cross section, thereby leading to a corresponding pressure reduction (represented by the symbol "- -), which consequently leads to the canceling forces represented by the arrows 123 and 124.

A similar effect due to the increase in pressure upstream of the valve seat 104 and the decrease in pressure downstream of the valve seat also arises in the opposite direction of flow, as shown in Figure 4.

Consequently, a number of measures have been taken altogether to bring the flow conditions in both directions closer together, so that it is not necessary to pay attention to the direction of flow during assembly.

The illustrated embodiments can be varied in many respects without departing from the basic idea of the invention. The valve according to the invention can be used not only in conjunction with manual or thermostatic cap-operated radiator valves, but also in any type of valve where the direction of flow should not be important.

In this connection, it should be noted that many of the valve components according to the invention are identical to valve components on the market, which allows the production of larger numbers of pieces and thus the corresponding savings. For example, the valve shown in Fig. 2 differs from the valve known only by the plug 105 and the tongue 115.

Claims (8)

1.Valve, valve g for heating systems supplied with warm water, having a housing, two connection channels for inlet and outlet, a valve seat and an externally actuated damper, spring-loaded and covering the valve seat, characterized in that the valve (5; 105) has on the side opposed to the valve seat (4; 104), a piston (9; 109), sealingly engaging a cylindrical chamber (10; 110), the working pressure surface of which is substantially equal to that of the valve seat (4; 104), and that the chamber the cylindrical (10; 110) communicates with the space inside the valve seat. 2. The valve according to the principle. 1, in that the shutter (5; 105) has at least one channel (11; 111) connecting its two face sides. 3. The valve according to claim The valve as claimed in claim 1 or 2, characterized in that the obturator (5; 105) has a zone (12; 112) in which its cross-section increases towards the valve seat (4; 104), and that located at the free end of the piston (9; 109), the annular flange (13; 113) partially covers this zone (12; 112) and is loaded with the pressure acting on this zone. 4. The valve according to claim The method according to claim 3, characterized in that in the zone (112), the increase in cross-section is formed by a cone, against which a cylindrical section provided with an annular flange (113) rests. 5. Valve according to flow. 1 or 2, 3 or 4, in that the shutter (5; 105) or the valve seat (4; 104) is made of a flexible material. 6. Valve according to suS. A circuit according to any one of the preceding claims, characterized in that the valve seat (104) is surrounded by a circumferential trough (121). 7. The valve as claimed in claim The method of claim 6, characterized in that the depth of the circumferential channel (1211 increases gradually in a radial direction from the outside to the inside and is limited by the annular shaft (122) provided on the circumferential wall of the valve seat (104). 8. The valve according to claim 3. The valve seat (104) as claimed in any of the preceding claims, characterized in that the valve seat (104) has a curved cross-section.