DE8220406U1 - Solenoid operated pressure control valve - Google Patents

Description

Legal file: G 831 FIAT AUTO S.p.A.

I-10135 Turin

Solenoid operated pressure control valve

The invention relates to a pressure control valve, which is in a hydraulic Circuit can be switched on, between a source of pressurized, flowable medium, a User and a dispensing reservoir. In particular, but not exclusively, the invention relates to such a pressure control valve, that is used in a hydraulic circuit of a device for controlling or regulating a continuous, automatic transmission Can be found.

The engagement and disengagement of clutches becomes an automatic Transmission by means of the supply or interruption of | pressurized oil to or from the clutch is controlled. Around To achieve a gentle engagement (or release), the pressure as well as the throughput of the supplied fluid medium are through to regulate suitable valves.

The invention is based on the object of creating a pressure control valve that is in a hydraulic circuit between a Source of a pressurized flowable medium and a consumer lies to the throughput of the pressurized Medium to control or regulate the consumer depending on an external electrical signal, for example by a signal given by a central control system. Further The invention is based on the object of providing a feed delay valve that selectively shares the said consumer can interconnect the dispensing reservoir.

According to the invention there is provided a pressure control valve which is in a hydraulic circuit between a source a pressurized flowable medium and a. Consumers can be switched on to selectively the latter to be connected to the source of the pressurized medium or to a reservoir for dispensing said medium, with a control chamber which has an inlet and an outlet for a control medium, the outlet with a electrically controlled or regulated valve is provided, further with a coil having a first, active surface zuiii Detecting the pressure in the control chamber is equipped and which is movable against the action of an elastic means between a first position in which the coil can connect a first channel connected to the consumer to a second channel connected to said Reservoir is connected, and a plurality of positions in which said coil has the first channel can connect a third channel that is connected to the pressure wave. The invention is characterized in that a reaction chamber is provided, which by means of a connecting channel connected to said first channel and equipped with a second active surface, which is the said first active surface is opposite and rigidly connected to the coil that said second active surface reacts to the pressure of the flowable medium present in the reaction chamber, and that the volume of the latter varies with the displacement of the coil.

The invention is explained in more detail with reference to the drawing. The following is shown in detail:

Figure 1 illustrates schematically a simplified hydraulic Circuit, a valve designed according to the invention being provided.

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Figures 2 and 3 each give a longitudinal section of the Valve shown in Figure 1 in two different operative positions again.

Figure 4 illustrates a variant of the valve according to of Figures 1 and 3

The reproduced in Figure 1 hydraulic circuit 1 comprises a source 2 of a pressurized flowable medium, a closed consumer 3> for example a disc clutch, a pressure control valve 4, which is between source 2 and. Consumer 3 is switched and a dispensing reservoir 5 (Reservoir) that is open to the atmosphere. A pipe 6 connects the source 2 with the valve 4, while the latter is connected to the consumer 3 and to the reservoir 5 by means of pipes 7 and 8, respectively.

The valve 4 shown in FIGS. 2 and 3 has a base body 9 on ₃ which has a bore 10. In the bore there is a substantially cylindrical, slidable coil 11 (valve slide). The bore 10 is closed at its opposite ends by corresponding plugs 12 and 13; these are assigned sealing rings 14 which are embedded in corresponding seats 15 and 16 of the base body. In the embodiment shown, the plug is secured by means of a locking ring 17.

Plug 13 is hollow; on him is an electromagnet 18 in known Way screwed, which receives control signals from an electrical control system, not shown here and in dependence thereon outputs an axial displacement of a pin 19 in a proportional manner. Pin 19 acts on the valve member 20, which in turn is enclosed by the base body 9. It comprises a bushing 21 molded into a bore 10 Seat 22 runs and with a seal 23 and with a Kali-

brierten bore 24 is equipped. Bore 24 can be progressively shut off by a floating ball 25, the in turn sits in a seat 26 of bushing 21 and is pressed against bore 24 by pins 19.

The bore 10 is divided into a series of adjacent chambers in which the valve slide is movable. Bore 10 comprises in particular a control chamber 27 in the area of the socket 2I _3, a reaction chamber 28 in the area of the plug 12 and three end chambers 29, 30 and 31, into which channels 6, 7 and 8 open. The numbers correspond to the reference numbers of the pipelines in FIG. 1. The chambers 29, 30 and 31 are arranged one behind the other and communicate with one another through corresponding outlets 32 and 33. Slide 11 cooperates with these outlets 32 and 33 and has corresponding cylindrical outer surfaces 34 and 35 j which are molded onto land zones 36 and 37 of slide 11 and which can then shut off outlets 32 and 33 in a liquid-tight manner when these outlets with land zones • 36 and 37 work together.

Slide 11 has two end bores 38 and 39, each of which Chambers 27 and 28 are facing, which represent extensions for this purpose. Bore 38 has an active area 40, which on the pressure prevailing in chamber 27 reacts, chamber 27 is constantly filled with control medium which enters chamber 27 through an inlet, which in turn consists of a calibrated bore 4l which is formed in slide 11 and with Channel 6 communicates. Chamber 27 is also provided with an outlet provided for control liquid; this outlet consists of of the bore 24, the cross-sectional area of which by the position the floating ball 25 is determined, which in turn is positioned by the magnet 18 via the pin 19. the Control fluid passing through bore 24, collects in a between socket 21 and pin 13-

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internal chamber from which the liquid in channel 8 flows through an outlet channel 42.

Bore 39 contains a helical spring 43, which is located between slide 11 and plug 12, and against the effect of which the slide can be displaced. Bore 39 also has an active surface 44 which is opposite surface 40 and which is on the reaction chamber 28 pressure reacts.

The reaction chamber 28 communicates in each position of Slide 11 with bore 30 and the associated channel 7 by means of a connecting channel 45 which is formed on the slide 11. It is therefore filled with pressurized medium, the the consumer 3 is supplied. The chambers 27 and 28 are finally provided with corresponding stroke limit stops 46 and 47 equipped for the slide 11, each molded onto the plug 12 and the socket 21.

In the variant of the valve according to FIGS. 2 and 3 shown in FIG. 4, the same or similar parts have the same Provided reference signs. The valve 4 according to Figure 4 is very similar to that according to Figures 2 and 3; it deviates from this by a different shape of the slide 11. Slide is in particular with substantially cylindrical bores 3 8 and 39 equipped, the dimensions of which are larger than those of the corresponding bores in valve 4 of FIGS. Bonrung 39 has a stop 49 for the spring 43 and is with channel 7 via a connecting channel, which is formed from a radial bore 50, which in turn the slide 11 is integrally formed. Slide 11 has an end 51, which faces a shoulder 47, which in turn is equipped with grooves 52. Control medium can be passed through these grooves pass from chamber 27 to chamber 38 and thus a Apply pressure to the active surface 40. The control medium

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enters chamber 27 through a ßinlaßkanal 53, the is equipped with a socket 54, which is a calibrated Has bore 41. The control medium can flow from chamber 27 through bore 24, the cross-sectional area of which through the Position of ball 25 is determined] it then argued through Outlet channel 42, which is partly formed from base body 9 and partly from plug 13.

The mode of operation of valve 4 will be explained below with reference to FIGS. 1 to 3.

If no pressurized medium is to be supplied to the consumer 3 no signal whatsoever is fed to the electromagnet 18. In this way, pin 19 will not hit the ball pressed so that it can be moved in seat 26 without blocking the bore 24. Therefore, control medium that is in Chamber 27 can enter, flow out without difficulty.

In this state, slide 11 is in the position shown in FIG shuts off while outlet 33 is open because it does not cooperate with land area 37. In chamber 27 there is a very low pressure, since the pressurized control medium flows out through the calibrated bore 41 and thus a experiences a sharp drop in pressure. For this reason, the pressure exerted on the slide 11 by means of the spring 43 is greater than the pressure exerted by the control medium on the active surface 40, and therefore the slide 11 becomes against the shoulder pressed on. In the position of slide 11 shown in FIG. 2, channel 7 can therefore be connected to channel 8 via outlet 33 communicate; valve 4 therefore connects consumer 3 with dispensing reservoir 5.

If, on the other hand, it is desired to supply pressurized medium to the consumer 3, the electromagnet fed a specific electrical signal that causes the pen to be shifted to a predetermined position

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and thereby blocking the bore 24 by means of a ball 25. ψ Because of the reduction in the Querschnittsfläehe of bore 24 increases the pressure of the control medium in chamber 27 at which control medium r because there partially accumulates. According to . > This increase in pressure is the pressure exerted by the control medium to the slider 11 "initially equal to the pressure of the \ spring 43, and then exceeds this. Slider 11 starts

then to move towards the plug 12 * and thereby compress the spring 43 in order to assume a new position of equilibrium. Depends on. The pressure of the medium in chamber 27 allows gate valve 11 to travel to a plurality of general positions, one of which is illustrated in FIG. In f, this position outlet is shut off by the surface 35 33 f while the outlet 32 is open and duct 6 connects with duct. 7 In this way, consumer 3 communicates with source 2 and j> is blocked from outlet 5. During the change between κ the opening of outlet 32 and the stopping of the slide 11 Ι in the new equilibrium position, the pressure in channel 7 increases progressively until it is equal to the pressure in channel 6, since the medium exits through outlet 32 and is accordingly in the Consumer 3 accumulates. The pressure in channel 7 rises very slowly, since the movement of slide 11 is counteracted not only by the force of the spring, but also by the pressure exerted on active surface 44 by the medium in channel 7. The pressurized medium fills the reaction chamber 28 via channel 45 and exerts a counter pressure on the slide 11, which delays the movement. The equation of the equilibrium of the slider is as follows:

P.A = Pl.Al + KX, (1)

where P and Pl are the pressure of the medium in chamber 27 and the ■ Pressure of the medium in chamber 28, A and Al denote the sizes of areas 40 and 44, respectively (where A is preferably = Al), K denotes is the elastic constant of the spring 43 and X is the displacement of the slide 11 is against the spring 43.

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Therefore the movement of slide 11 is counteracted by the expression (Pl.Al), which slows slide 11 progressively.

At the end of the movement, the pressure exerted by the medium in chamber 28 and by the spring 43 exceeds the pressure the control medium; therefore the direction of movement of slide 11 is reversed - the increase in volume in chamber 28 following the displacement of slide 11 against plug 13, the pressure of the medium contained in chamber 28 can drop. Therefore slide 11 stops as soon as the pressure acting on it is in equilibrium. Thus, a cheaper one Get a stabilization effect that does not allow a reopening of the connection with channel 8, which is dangerous Vibrations of the slide 11 would lead.

If a different signal is fed to the magnet 18, a different pressure is achieved in the control chamber 27. That's why it is for example possible to open the outlet 33 and the progressive To regulate delivery of consumer 3. It is also possible to set the operation time of valve 4 (spool passage time) to change.

Claims (9)

Legal file: P + G 831 FIAT AUTO S.p.A. 1-10135 Turin ntjämsprehe 1.Pressure control valve (4), which can be switched into an electrical circuit (1) between a source (2) of a pressurized medium and a consumer (3) to selectively connect the latter to the pressure source (2) or a discharge reservoir ( 5) z, this printing medium "u connect, with a control chamber (27) having an inlet (41, 53) and an outlet (24) for control medium, wherein the outlet (24) controlled by an electrically controlled (which is controlled) Valve (20) and a slide (11) is equipped which has a first surface (40) which responds to the pressure prevailing in the control chamber (27), which the slide (11) counter to the action of an elastic means (43) is movable between a first position in which the slider a first channel (7) _s connected to the consumer (3) (11), which is connected to the reservoir (5) having a second channel (8), in conjunction can bring, and a number of positions, in which the slide (11) can connect the first channel (7) to a third channel (6) which in turn is connected to the source (2), characterized in that the valve (4) has a reaction chamber (28), which is connected to the first channel (7) by means of a connecting channel (45, 50), that a second active surface (44) is also provided which is opposite the first active surface (40) and which can be moved together with the slide (11) is, wherein the second active surface (44) is responsive to the pressure of the medium in the reaction chamber (28), the volume of which varies with the displacement of the slide (11). 2. Valve (4) according to claim 1, characterized in that the slide (11) has a substantially cylindrical frame and is able to slide into a bore (10) which is formed on the base body (9), and in which the first (7), second (8) and third (6) channels open, and which finally includes the control chamber (27) and the reaction chamber (28). 3. Valve (4) according to claim 2, characterized in that the control chamber (27) and the reaction chamber (28) are arranged at the opposite ends of the bore (10), and that the bore (10) has three end chambers (30, 31, 29), which with the first (7) and the second (8) and the third (6) channel communicate and have a first outlet (32) and a second outlet (33). 4. Valve (4) according to claim 3, characterized in that the slide (11) is slidable with the first and the second outlet (32, 33) engages and shuts off the first and second outlets (32, 33) with corresponding lateral Flat (34, 35) is provided. 5. Valve (4) according to one of claims one to four, characterized in that the connecting channel (45, 50) to the Slide (11) is integrally formed. 6. Valve (4) according to one of claims one to five, characterized characterized in that the inlet (53) of the control chamber (27) is equipped with a socket (54) which is a calibrated Has bore (41). 7. Valve (4) according to one of claims one to five, characterized characterized in that the inlet to the control chamber (27) is formed by a calibrated bore (41) which the Slide (11) is formed and communicates with the third channel (6). 8. Valve (4) according to one of claims one to seven, characterized in that the second active surface (44) the slide (11) at the end of a bore (39) and this is formed accordingly, facing the reaction chamber (28) and receives the elastic means (43). ■ ■ 9. Valve (4) according to one of claims one to eight, characterized in that the control chamber (27) and the Reaction chamber (28) with end stroke stops (46, 47) for the Slider (11) are provided =