FI96132B - Pressure medium device and pump - Google Patents

Description

96135

PRESSURE EQUIPMENT AND PUMP

The invention relates to a device for producing a reciprocating linear movement with a pressure medium. The device is characterized by the structure of the primary reciprocating piston, the piston containing the necessary valves.

It is already known as means for generating reciprocating motion by means of a pressure medium, e.g. hydraulic cylinders as well as various impact machines in which the impact piston receives its kinetic energy in different ways from the pressure medium. The percussion machines use self-acting valves to control the pressure medium, whereby the percussion machines themselves make a continuous reciprocating movement. Hydraulic cylinders are generally controlled by an external valve. The percussion machines have used a pressure accumulator, such as a compressed air tank, to store sufficient pressure and to release it abruptly against the movable piston to allow rapid movement of the piston in at least one direction. Valve actuators are generally housed in a device body and the piston is only a body that transmits motion or force.

Current devices are not only suitable for hydraulic reciprocating continuous reciprocating motion, especially when motion should be rapid in both directions, pressure shocks in valves should be avoided, and no gas accumulator should be used to accelerate motion.

A device operating on a pressure medium according to the invention, in particular a liquid medium, achieves a decisive improvement in this drawback and the invention is characterized by what is stated in the appended claims.

The main advantages of the invention are that the valve built into the piston achieves a pressure-free reversal at the extremes of the movement of the piston by means of pre-pressure control. This is important because the device uses a relatively large fluid flow relative to its size. No pressure shock to the fluid line 2 96132 is generated because the piston is freely "floating" at the extreme, i.e. it changes its direction as the pressures acting on different sides of the piston change. Thus, the piston does not have a well-defined pivot point at which the valve would be mechanically closed and opened in the blink of an eye.

In addition, the device has the advantage of its simple and compact design, and its applicability to many different uses. The rapid reciprocating motion generated by the device can be used to pump liquids and gases, also against high back pressure, the motion of the device can be converted to vibrator vibration motion, impact machine shock motion, etc. By changing the ratios of annular piston cross-sections, the movement of the direction also becomes stronger.

In the following, the invention will be explained in more detail with reference to the accompanying drawing, in which

Figure 1 shows a sectional view of a pump application.

Fig. 2 shows a sectional view of the pump application of Fig. 1 during the return movement of the piston.

Figure 3 shows a sectional view of the valve.

Figure 1 shows an exemplary pump application of the invention. The device is a hydraulically operated pressure washer pump with two cylinder spaces 20. The water suction channels are 22 and the pressure channels 21. There are cylinders 1 at each end of the device. The secondary pistons 14 and 15 perform the pumping. The secondary pistons 14 and 15 are separated from the working fluid space 6 and 18 by pairs of seals 16. There are leakage flow channels 17 between the pairs of seals 16. The cylinders 1 and the central body 2 are simple cylindrical bodies. The pressure fluid inlet channel is 4 and the return channel is 5.

Inside the central body 2 there is a primary piston 3, the actual piston portion of which is the largest diameter part of the ring. The secondary pistons 14, 15 are threadedly attached to the primary piston 3.

In Figure 1, all of the plungers moving to the right in the direction of the arrow. The fluid pressure acts on the annular surface A of the primary piston 3

n 3 96132 and pushes the piston 3 to the right. The pressure fluid in the chamber space 18 exits along the channels 12, 10 and 7 to the return pipe 5.

Valve 8,9 remains on the left side when the pressure acts on the closing part 9. The piston 3 moves to the right to its extreme position. The extreme position where the piston changes direction is determined by the displacement of the leakage channel 13 to the edge of the annular chamber 19. In this case, full operating pressure is generated through the leakage channel 13 behind the piston part 8 of the valve 8.9 and it presses the valve to the right and opens the channel closed by the closing member 9. The cross-sectional area of the piston 8 is larger than the area of the opening 23 closed by the closing member 9.

As the valve 8,9 moves rapidly to the right, the pressure ratios on the sides A and B of the primary piston 3 immediately change. The closing member 9 opens its closed opening 23 and the piston part 8 moves to close the opening leading to the channel 7. The primary piston 3 and the connected pump pistons 14,15 left. Primary piston 3 on the A side and B due to the same full pressure, and the B-side, due to a larger surface area of the piston 3 starts at the B side pressure force acting on the left. During this movement, the liquid in the chamber 6 leaves the return line. In the arrangement according to Fig. 2, the piston 3 moves to the left and Fig. 2 illustrates a situation in which the movement of the pistons is just at the leftmost end.

In Figure 2, the valve 8,9 is still in the state where the pistons 3,14,15 move to the left. The valve part 9 is in the free chamber space. The piston 8 is pushed full pressure to the left by the force determined by the cross-section of the closing opening and to the right the full pressure is pushed by the piston 8 from the space of the rear of the piston 8. The piston remains in the position on the right edge until, in the situation according to Fig. 2, the leakage channel 13 again reaches the edge of the annular chamber 6, whereby the pressure behind the piston 8 decreases considerably.

• The full pressure through the closing opening in the piston 8 is now able to move the piston to the left closing position and the closing member 9 in turn closes the closing opening 23 and the situation according to Fig. 1 is reached.

.. The leakage channel 13 is connected to the channel 10 by a side channel which is provided with a throttling point 11. Thanks to the side channel, the operation of the valve 6,9 is more reliable and clearer pressure differences are created to move the valve 8,9.

Figure 3 is a partial enlargement and a sectional view of the structure of the valve 8.9. The beveled surface 25 of the part 8 is sealed to the corresponding seat surface of the part 3. In this case, the pressure acting on the part 8 through the closing opening 23 only affects an area the size of the closing opening in the end face of the piston 8. As soon as this valve opens a little, the pressure also acts immediately on the bevel surface 25 and the movement of the valve 8.9 suddenly intensifies. The part 9 has a cylindrical surface with a loose surface to the inner surface 23 of the opening and the sealing is performed on the tip surface 24 of the part 9 against the end face of the part 3. The structure provides reliable operation of the valve. This closing member also behaves like a seat valve fitted to the piston 8, i.e. when the closing member 9 closes the opening 23 at its tip surface and starts to open, the pressure immediately also acts on the larger annular area located centrally from the tip surface 24. The resulting force enhances and accelerates the movement of the part 9 to the right. The feature described above is best achieved by using seat valves as in Figure 3.

The reciprocating motion of the primary piston 3 can be utilized in a wide variety of devices. The pistons 14,15 or only one of them can be replaced by a movable arm which comes out of the housing and whose movement is exploited. Moreover, it is not desired to limit the device to certain applications, but many modifications are possible within the scope of the inventive idea defined by the appended claims.

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Claims (6)

1. A pressure-driven apparatus which generates and eats moving motion for one or more pistons (14,15) or equivalent shaft, which transmits movement, which apparatus comprises in a enclosed space a primary piston (3) which moves forward and only eats with the aid of pressure medium and in which apparatus the pressure valves control valves (8,9) pouring in motion of the primary piston (3) are located within said primary piston, characterized in that there is in the apparatus for controlling the aforementioned forward and eating occurring movement. a separate seat valve (8), (9) for both directions of movement, in which the moving part (8), (9) comprises an annular compressive end surface (24), (25), at which the pressure at the opening of said valves immediately acts and amplifies force that opens valves (8,9). 2. An apparatus according to claim 1, characterized in that in the primary piston (3) is a flow channel (13), through which a rise and / or decrease in the pressure of the medium causes the closing and opening of seat valves (8,9). An apparatus according to claim 1 or 2, characterized in that the channel lying in the primary piston (3) moving with respect to the stem (2) has in the stem (2) a closing means (26), the length of which determines the primary piston. forward and eat happening movement length. 4. An apparatus according to claim 3, characterized in that the means (26) which closes and opens the channel (13) is the inner surface of the cylinder housing (2). 5. A pressurized medium pump comprising a cylindrical pump housing (2), one or more front and ate moving pump pistons (14), (15), a corresponding cylinder (1) for each piston to pump liquid or gas, and inside in the stem (2) a primary piston (3), coupled to a pump piston (14,15), characterized in that the primary piston (3) comprises for driving pressure medium valves (8,9) for controlling pressure medium to both sides of the primary piston, a flow channel (13) controlling the operation of valves (8.9) 8 96132 and a shut-off means (26) of the flow channel (13) which regulates stroke of the primary piston. A pump according to claim 5, characterized in that there are two pump pistons (14,15) against each other, the primary piston (3) is driven by the pressure of hydraulic fluid, and that the valves (8,9) are pressure controlled seat valves. i «il