DE68917587T2 - Valve arrangement. - Google Patents

Description

The invention relates to a valve arrangement.

The flow of fluid in pumps is limited and controlled by various types of valve arrangements. Figures 8 and 9 show a valve arrangement used in plunger pumps, a type of pump often used for high pressure applications.

This valve arrangement consists of a tubular seat 100, a valve piece 102 with a circumferential flange 101 and a valve spring 103 which presses the valve piece 102 against the seat 100.

Because plunger pumps are used to pump materials such as cement clinker, in conventional valve arrangements solids present in the fluid can become trapped between the valve member 102 and the seat 100.

The tubular design of the seat 100 used in conventional valve assemblies makes it easy for solids to pass through; furthermore, since the seat 100 and the valve piece 102 are made of metal, the operation of the valve assembly can be adversely affected by solids caught between them. As a result, it is sometimes impossible to pump a constant amount of fluid at a constant rate, so that the operation of the pump is accompanied by a decrease in efficiency. Furthermore, solids caught between the seat 100 and the valve piece 102 can damage the seat and the valve piece, causing fluid to flow away. Typically, the valve must then be replaced, which interrupts operation.

EP-A-0 309 240 (which claims an earlier priority date than the present application, but was published after each of the priority dates of the present application) discloses a valve assembly for preventing the inflow of solids contained in a fluid and for improving the durability of the assembly. Such a valve assembly (see Figures 10 and 11) comprises a seat 107 which comprises a valve seat 104 in the form of a concave surface 105 which corresponds to a spherical surface section and a predetermined number of fluid passages 106 formed in the seat 107 and opening into the concave surface 105. There is also a valve member 108 having a surface corresponding to the shape of the concave surface 105 of the valve seat 104, and a valve cover 110 and a spring retainer 111 which hold the valve member 108 on the concave surface 105 of the seat 107 via a valve spring 109. In a valve assembly thus constructed, at least one of the seat 107 and the valve member 108 is either formed of or covered with a hard-to-give material, or one of the members is made of a hard-to-give material and the other is covered with a hard-to-give material. Furthermore, wood may be used instead of the hard-to-give material.

In a valve arrangement constructed in this way, the fluid passages 106 formed in the seat 107 have a smaller diameter, which makes it difficult for solids to pass through. Even if solids pass through the fluid passages 106 and become trapped between the seat 107 and the valve piece 108, the flexibility of the valve seat and/or valve part ensures that the effectiveness of the valve is not impaired.

However, such a valve arrangement is not very suitable for pumping at higher pressures because an increase in the pumped quantity can cause the valve part 108 to vibrate as the fluid flows in.

BE-A-520 270 discloses a valve arrangement with the features of the preamble of claim 1. US-A-1 092 782, US-A-3 298 320 and US-A-3 664 770 each disclose a valve arrangement in which a plurality of fluid passages are provided in front of a valve seat, but the valve seat is not spherically concave and the passages do not end at the valve seat surface but at a distance in front of this surface.

According to the present invention there is provided a valve assembly comprising:

a) a seat member in whose front surface a plurality of valve seats are formed, which are arranged at regular intervals along the edge,

b) a plurality of fluid passages in the seat member,

c) a plurality of valve parts, each valve part being in a respective valve seat and having a spherical surface,

d) a valve housing provided with elastic means, the elasticity of which presses the spherical surface of the valve parts onto the respective valve seats, characterized in that

e) each of the seats is of concave shape, with a surface corresponding to a spherical surface section, the spherical surface of each of the valve parts corresponding to the surface of the respective valve seat, and

f) for each of the valve seats, a respective plurality of fluid passages are provided in and through the seat member, communicating with and terminating at the surface of the valve seat.

The present invention is explained below by way of example with reference to the accompanying drawings, in which:

Figure 1 is a cross-section through an embodiment of a high-pressure pump,

Figure 2 is a cross-section of a valve arrangement according to an example of the present invention for the pump,

Figure 3 is a perspective view of the valve arrangement according to Figure 2, shown disassembled,

Figure 4 is a plan view of the valve housing shown in Figure 3,

Figure 5 is a cross-section along the line A--A according to Figure 4 ,

Figure 6 is a plan view of the seat member shown in Figure 2,

Figure 7 is a cross-section along the line A--A according to Figure 6,

Figures 8 and 9 are a sectional view and an exploded perspective view of a conventional valve assembly, and

Figures 10 and 11 are a sectional view and a disassembled perspective view of a valve arrangement which does not correspond to the invention.

The high-pressure fluid pump shown in Figure 1, for example for use in a cement mill, comprises a valve block 2 provided with a valve chamber 1, a plunger housing 4 provided with a plunger 3 and a housing 5 having a pressure generating chamber 5a arranged between the valve block 2 and the plunger housing 4.

The valve block 2 has an inlet channel 6 and an outlet channel 7 which communicate with the valve chamber 1 and which are provided with an inlet valve 80 and an outlet valve 81, respectively.

A side wall 2a of the valve block 2 is provided with a passage 17 which connects the pressure generating chamber 5a to the valve chamber 1. As explained below, the position of the passage 17 is determined according to the difference in the specific gravity between a liquid 28 and the fluid 14 to be pumped, so that the latter does not reach the pressure generating chamber 5a. If the liquid has a higher specific gravity than the fluid, the passage 17 is arranged in a higher position of the pressure generating chamber 5a, and if the liquid has a lower specific gravity, the passage 17 is arranged lower. In the example shown, the position in which the passage 17 opens into the pressure generating chamber 5a is higher than the inlet of the valve chamber 1. For this purpose, the position of the passage 17 is determined according to the ratio between the height of the pressure generating chamber 5a and the valve chamber 1 and taking into account the weights of the liquid and the fluid 14.

The end of the plunger 3, which is held in the cylinder 21 in the plunger housing 4 via a V-packing 22, extends into the pressure generating chamber 5a and is reciprocated at high speed by a drive (not shown).

An elastic membrane 23 is provided in the pressure generating chamber 5a to divide the pressure generating chamber 5a into a cylinder side A and a valve chamber side B. The cylinder side A of the elastic membrane 23 is filled with an operating medium 25, such as oil, via an oil channel 24 of the plunger housing 4. In addition, the valve chamber side B of the pressure generating chamber 5a and a part of the passage 17 are filled with liquid 28, such as oil, which has a lower specific gravity than the fluid 14 and does not mix with the fluid 14. The liquid 28 comes into partial contact with the fluid 14 along the passage 17.

Between the pressure generating chamber 5a and the passage 17, a screening device 29 is provided, which uses, for example, a mesh screen, to prevent particles exceeding a certain size from entering the pressure generating chamber 5a. The screening element 29 can be formed as an integral part of the valve housing 5 containing the pressure generating chamber 5a, and the passages 20 therein have a downward slope towards the side of the passage 17.

In the structure described above, a suction stroke of the plunger 3 leads to the contraction of the elastic membrane 23, whereby the volume on the cylinder side A of the pressure generating chamber 5a is reduced and the volume on the valve chamber side B is increased. The change in volume leads to an increase in the level of the liquid 28 in the passage 17. In addition, an amount of fluid 14 corresponding to the change in volume flows into the valve chamber 1 as soon as the inlet valve 80 opens. The discharge stroke of the plunger 3 leads to an expansion of the membrane 23 via the operating medium 25, and with the reduction in the volume on the valve chamber side B, the liquid 28 located on the valve chamber side B in the pressure generating chamber 5a is discharged. In addition, the level of the liquid 28 in the passage 18 drops and a corresponding amount of fluid 14 is expelled when the outlet valve 81 opens. The liquid 28 is only forced over a portion of the passage 17 and does not flow to the side of the valve chamber 1.

As shown in Figures 2 to 7, the inlet valve 80 and the outlet valve 81 each have a seat member 84 in the end face 82 which has a plurality of valve seats 83 (eight in the illustrated Example) arranged at regular intervals along the rim, each of which is formed in a concave shape corresponding to a spherical surface cutout; spherical valve parts 85 are arranged on the valve seats 83; and a valve housing 87 presses the valve parts 85 onto the valve seats 83 by springs 86.

For each of the valve seats 83, a plurality of fluid passages 88 (three in the example shown) are formed in the seat member 84, which extend axially through the seat member 84 and communicate with and terminate at the valve seat surface. Fluid passages 89 are arranged along the edge of the valve housing 87, corresponding to the valve seats 83, into which the valve parts 85 fit. The exit end of each of the fluid passages 89 is formed by a shoulder 90 as a smaller diameter portion. One end of each valve spring 86 is held on the shoulder 90. The valve housing 87 and the seat member 84 are each provided with corresponding central screw through holes 91 and 92, whereby they are screwed together with a screw 93 and a nut 94.

In addition to metal, the valve parts 85 and/or the seat member 84 may be made of or coated with a material that is difficult to yield, such as synthetic resin.

With the structure described above, a suction stroke of the plunger causes the elastic membrane 23 to contract and the volume on the cylinder side A of the pressure generating chamber 5a to decrease, causing the valve parts 85 of the inlet valve 80 to open against the resistance of the springs 36 and fluid 14 to flow into the valve chamber 1. At the same time, the valve parts 85 of the outlet valves 81 are pulled toward their closed position and thereby remain closed. Before the fluid can flow into the valve chamber 1, entrained particles that exceed a certain size are removed through the fluid passages 88 and then through the screen element 29. The discharge stroke of the plunger 3 expands the elastic membrane 23 and causes fluid 14 that has reached the valve chamber 1 to open the outlet valve 81 and be pumped out.

Since the operation of the valves 80 and 81 takes the form of small amplitude movements of many valve parts 85, the vibration accompanying the opening and closing of the valves can be prevented and, when used on pumps, reliable valve function and increased durability can be achieved compared to conventional arrangements.

Claims (1)

1. Valve arrangement with: a) a seat member (84) in whose front surface (82) a plurality of valve seats (83) are formed, which are arranged at regular intervals along the edge, b) a plurality of fluid passages (88) in the seat member (84), c) a plurality of valve parts (85), each valve part being in a respective valve seat and having a spherical surface, d) a valve housing (87) provided with elastic means (86) whose elasticity presses the spherical surface of the valve parts onto the respective valve seats, characterized in that e) each of the seats is of concave shape with a surface corresponding to a spherical surface section, the spherical surface of each of the valve parts corresponding to the surface of the respective valve seat, and f) for each of the valve seats, a respective plurality of fluid passages are provided in and through the seat member, which communicate with and terminate at the surface of the valve seat.