DE2118480A1 - Fluid operated flow motor - Google Patents

Description

Patent attorneys
Dr. Ing.H. Negendank

Dipl. Ing. H. Hauck

Dipl. Phys. W. Schmitz

4 Munich i5; Kos 2i.-tsir.23

Tel. 5380536

Societe Anonymous DBA.

98 Boulevard Victor Hugo, April 14, 1971

92 CIichy, France Lawyer File M-1549

Fluid operated flow motor

The invention relates to a fluid-actuated, reciprocating flow motor, in particular for actuating a in a motor vehicle usable pump, with a housing which is divided by a movable wall into two pressure chambers, wherein the forward and backward reciprocable wall is resiliently biased in the rearward direction, and a Control device which, depending on the position of the movable wall, controls a distribution valve that controls one of the pressure chambers alternately with a higher pressure, which balances the pressure permanently prevailing in the other pressure chamber, and with one applied lower pressure.

In a known flow motor of this type, the movable wall is connected to a piston which can be displaced in a cylinder, whereby a pump unit is formed which sucks in fluid and releases the fluid again under pressure. The movement of the wall is caused by a pressure difference acting on the wall- ■■■■ '<" .?.": -:% · _# .-'*; *: p..r! Fi -2-

109844/1261

~ ² ~ 2118A80

renz generated, the operating phases of the pressure difference by operating phases balanced pressure are separated, in which the movable wall by elastic means in its rearward position is moved back. The working fluid can be a gas or a liquid. For example, if air is chosen as the working fluid, one of the pressure chambers can be permanently connected to the atmosphere, and the movement of the movable wall is then achieved by that the other pressure chamber alternates with the atmosphere and with a low pressure source (e.g. the suction line a vehicle engine) is connected.

It is known to use a distributor valve, for example a slide valve, to use to determine the operating frequency of the pressure changes in the one pressure chamber in which the pressure changes periodically should be generated. The position of the distribution valve is controlled depending on the position of the movable wall, and by means of a mechanical control device which is composed of movable components. The structural design of the mechanical control device is very expensive; not only does it require a lot of space, it also limits the speed of operation of the fluid flow motor due to inertial forces. In addition, the movable components of the mechanical control device subject to wear and tear, reducing the life of the fluid flow motor.

The invention is intended to provide a flow motor of the type specified at the beginning Kind be created in which the distribution valve is controlled by a control device that does not have any movable components

109844/1261 BATH ORIGINAL

has, so that the stromun. smotor smaller and more robust than the known ones Flow motors can be formed. This will be invented Sgernäß achieved in that the control device and the distribution valve are arranged within the movable wall and the control device is designed as a flow flip-flop.

Advantageous refinements of the invention are set out in the subclaims suggest.

The invention makes a flow motor of small dimensions and great service life, its operating speed can be higher than that of the known flow motors.

Based on the drawings, preferred embodiments of the Invention explained in more detail. Show it:

Fig. 1 is a cross section through a pump unit, which of a; flow impeller according to the invention is driven,

Fi ₁ -. 2 shows a pump unit with another exemplary embodiment of a flow motor according to the invention.

The in F5. 1 shown pump unit is powered by a flow motor angetr-iecen, the housing of which consists of a front housing part 1 and a rear housing part 2 consists. The two housing parts 1, 2 are connected to one another by flanges, between which the outer edge an annular membrane 6 is tightly clamped. The inner edge of the membrane 6 is connected to a circular plate 5, which divides the housing into a front and a rear pressure

109844 / 12B *

chamber 3 or 4 divided. The membrane β is sufficiently flexible so that the plate 5 can be moved axially in the housing.

A cylinder 8, which is attached to the outer surface of the front housing part 1 is attached in the middle, works together with a piston 7, which is connected to the movable plate 5. A suction valve 11, an inlet valve 12 and a vent valve I3 are in the head of the Cylinder 8 is provided.

The movable plate 5 is reciprocable in the forward and backward directions and transmits its movement to the piston 'J.

The movement of the plate 5 in the forward direction, i.e. in the direction on the front housing part 1 is generated by a pressure difference, as will be explained further below. The backward movement, 'der Plate 5 takes place when the pressure x ^ ieder balanced it-t, and is generated by the force of a helical spring 10 which is pretensioned between the housing part 1 and the plate 5.

In the embodiment shown in Fig. 1 is the rear Pressure chamber 4 is permanently connected to the atmosphere via an opening 14. The movement of the plate 5 in the forward direction is thereby generated that in the front pressure chamber 3, a negative pressure is produced.

According to the invention, the alternating application of pressure and pressure relief of the front pressure chamber 3 takes place by means of a device which consists of a slide valve 15 and a bistable flow flip-flop 16. _r _

1098U / 1261

The bistable flow flip-flop ΐβ is a conventional flip-flop with one inlet 17, two control inputs 18, 19 and two Outlets 20, 21. Two interconnected vents 22, 23 are assigned to the outlet 20 and 21, respectively.

The outlet 20 is connected to the slide valve 15. The outlet 21 is through an opening 25 in the movable plate 5 with the front pressure chamber 3 in connection. The ventilation openings 22, 23 are via an inlet line 26 running along the slide valve 15 extends, connected to an opening 27. the Opening 27 is connected to a low pressure source via a flexible hose 28 which does not hinder the movements of the plate 5 (not shown) connected, which is formed for example by the intake line of a vehicle engine.

The slide valve 15 is connected to the inlet line 26 via two openings 29, 30 arranged at a distance from one another and via another opening 32 to the atmospheric pressure of the rear pressure chamber. The slide valve has a closure piece 3I with two annular collars 3IA, 3IB. The annular collars 3IA, 3IB and the openings 30, 32 are arranged in such a way that the opening 30 is closed by the annular collar 3IA when the closure piece 3I is in the upper position (as shown in the figures), whereas the opening 32 is closed by the Ring collar 3IB is closed when the closure piece is in the lower position. The space between the annular collars 3IA and 3IB forms a distribution chamber which is connected to the low pressure of the front pressure chamber 3 via a channel 33 running through the movable wall 5. The locking piece 31 is biased upward by a spring J> k, and

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its downward stroke is limited by a stop 35.

When the pump unit is not working or the movable plate 5 has reached the end of its return stroke (shown in FIG Position), the control input 18 of the flip-flop, that of the back facing the housing, closed by a valve seat 36, which is formed on a projection 37 of the rear housing part 2 is. At the end of the forward stroke, the other control input 19 of the flip-flop, which faces the front housing part 3, of a valve seat 33 closed. The valve seat 38 is within, attached to an opening of the movable plate 5, and at the end of the return stroke it is from a projection 39 of the front housing part 3 printed against the control input 19.

It is assumed that the pump is not working, so that the pump assumes the position shown in FIG. The movable plate 5 is then biased in the rearward direction by the spring 10, so that the control input l8 at the front valve seat 16 is closed. The spring J> K provided in the slide valve pushes the closure piece 31 upwards so that the opening 32 is released. As a result, the front pressure chamber 3 is connected to the rear pressure chamber 4 and thus to the atmosphere, since the rear pressure chamber is permanently connected to the atmosphere via the opening Ik.

When the low pressure source is put into operation (for example, when the engine is started, the suction line of which is connected to the hose 28), a negative pressure is created in the inlet line 26 and air is drawn in from the lower portion of the slide valve 15 through the opening 29. Air is also drawn through the ent _ä .dwo. «** 1 098 U / 126 1" ⁷ "

Ventilation openings 22, 23 of the flop-flop sucked in, whereby in the Outlets 20, 21 of the flip-flop a negative pressure is generated.

The negative pressure generated by the ventilation openings 22, 23 causes a high velocity jet through inlet 17 flows, and through this jet, a negative pressure is generated in the control input IG. Since the opposite tax authority, rank 19 is connected to the atmosphere by a duct 40, the beam is deflected into the wall of the outlet 20, and the beam adheres to this wall as long as the control conditions are not changed, i.e. as long as none in the control input 19 Negative pressure is generated, even when there is atmospheric pressure in the control input 13 again.

The one through the Auslai? 20 flowing jet hits the closure piece ^ l on. The breech block is then moved down until it rests against the stop 35, since the lower section of the Sehieoerventils is vented ;. During the movement of the slide valve 31, the opening 32 is closed and the opening 30 is opened. In the front pressure chamber 3 is then through the inlet line 26, the opening 30 and the channel 33 generate a negative pressure. The negative pressure is made forner by a bypass, consisting of the opening 25, which is connected to the. Outlet 21 of the flip-flop and the ventilation opening 23 is connected. Because of the negative pressure prevailing in the front pressure chamber 3, the plate 5 moves in the direction of the front housing part 1; this represents the forward stroke of the plate 5. The fluid contained in the cylinder ΰ (for example oil) is compressed by the piston 7 and then

discharged through the inlet valve 12. ρ

1 098AA / 126 1

ORIGINAL BATHROOM

At the end of the forward stroke, the control input 19 is closed by the projection 59, which moves the valve seat 38, while the other control input 18 is connected to the atmosphere. This reversal of the operating conditions prevailing in the control inputs results in a change in the state of equilibrium of the jet. The jet detaches itself from the wall of the outlet 20 and jumps over to the wall of the outlet 21. The outlet 20 is thus subjected to negative pressure, and due to the pressure equalization, the closure piece 3I is moved upwards by the spring y \.

When the closure piece 3I has reached the upper position, the opening 30 is closed and the opening 32 is released again. Air enters the front pressure chamber 3 through the channel 33 and through the opening 25 connected to the flip-flop, and when the pressure equalization is achieved, the spring 10 moves the movable plate 5 in the rearward direction. An amount of the fluid (oil) to be pumped corresponding to the stroke of the piston 7 is then sucked into the cylinder 8 through the suction valve 11.

The operating cycle described above is repeated for as long as negative pressure prevails in the hose 28.

In the embodiment shown in FIG. 1, the slide valve is controlled jointly by the jet which acts on one end of the closure piece and the spring which acts on the other end of the closure piece.

Fig. 2 shows an embodiment in which the beam alternately directed at one or the other end of the closure piece

1 098AA / 1261 -9-

will. Which can be found in FIGS. 1 and 2 corresponding components provided with the same reference numerals. In the exemplary embodiment according to Fig. 2 has the lower portion of the Schfeberventlls 15 no stop, no spring and none with the inlet line 26 connected opening. In addition, the outlet 21 of the flip-flop is not connected to the front pressure chamber 3. In contrast, the outlet 21 of the flip-flop is via a line 4l to the lower section of the slide valve 15 connected. Through openings 30, 32 and through the channel 33, negative pressure and atmospheric pressure are generated alternately in the front pressure chamber 3.

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1098U / 1281

Claims (5)

Patent attorneys
Dr. Ing. H- Nr-j * -n
Dipl. Ing. K. -i-.
Dipl. Fbys. V ,.
3 Some! 3 _# Μοζ
Societe Anonyme DBA Tel. 538 «» Boulevard Victor Hugo, April 14, 197I Clichy, France "Attorney's File M-15 ^ 9 Claims . \ Pressure medium-actuated, reciprocating flow motor, in particular for actuating a pump that can be used in a motor vehicle, with a housing which is divided into two pressure chambers by a movable wall, the wall, which can be reciprocated in the forward and backward direction, in the rearward direction is elastically biased, and a control device that controls a distribution valve as a function of the position of the movable wall, which one of the pressure chambers alternately with a higher pressure, which equalizes the pressure constantly prevailing in the other pressure chambers, and with a lower pressure, thereby characterized in that the control device (16) and the distribution valve (15) are arranged within the movable wall (5,6) and the control device (16) is designed as a flow flip-flop. 2. Flow motor according to claim 1, characterized in that the ¹ flip-flop (16) has: an inlet (If), which is continuously subjected to the higher pressure, a first control input (l8), -11-10 9 8 4 4/1281 - ii - 211848Q which is closed by a first valve seat (36) when the movable wall (5,6) reaches the end of its backward stroke, a second control input (19) * that of a second valve seat (38) is closed when the movable wall (5 * 6) the The end of the forward stroke is reached, and two outlets (20, 21), each of which is assigned a ventilation opening (22, 23), wherein the first outlet (20) is connected to the movable closure piece (31) of the distribution valve (15), whereas the vent openings (22,23) of both outlets via an inlet channel (26) and a flexible line, preferably a hose (28), which follows the movements of the movable wall (5,6), are acted upon together with the low pressure. 3. flow motor according to claim 2, characterized in that the second outlet (21) of the flow flip-flop (16) is connected to the pressure chamber (3) exposed to the pressure changes, and that the inlet kazial (26) has an opening (29) with the distributor valve (15) on that side of the distributor valve, which is opposite to the side connected to the first outlet (20). 4. flow motor according to claim 2, characterized in that the second outlet (21) with the distribution valve (15) on that side of the distribution valve which is connected to the first outlet (20) Opposite side, communicates. 5. Flow motor according to one of the preceding claims, characterized characterized in that the working fluid of the flow motor is air, •. -12- 109844/1261 the higher pressure is atmospheric pressure and the lower pressure is the intake pressure in the intake pipe of an engine. 1 0 98 k A / 1? R 1 Blank page