DE4321647A1 - Reversing valve - Google Patents

Abstract

A reversing valve (7) for pressure medium has a one-piece, plate-shaped housing (20) in whose cylindrical housing space (28) a cylindrical slide (36) is pivotably arranged. An annular groove (31) is formed in the housing (20). At least one inlet (22, 23) and at least one outlet (23 to 26) lead into the annular groove (31). A sealing ring (35) is arranged in the annular groove (31). In one position, when a flat (38, 39) on the slide (36) bridges an inlet (22, 23) and an adjacent outlet (23 to 26), the sealing ring (35) is pressed against the flat (38, 39), as a result of which a bridging space (44, 45) is formed between the outer boundary surface (32) of the annular groove (31) and the sealing ring (35). The single sealing ring (35) serves to seal the inlets (22, 23) and the outlets (23 to 26) from one another and to seal the valve to the outside. <IMAGE>

Description

The invention relates to a changeover valve according to the preamble of the saying 1.

With such changeover valves, on the one hand, there is a considerable amount of you effort and on the other hand a considerable amount of design effort required.

The invention is therefore based on the object of a changeover valve Generic type so that the sealing effort is strong is reduced, at the same time a simple constructive Ausgestal tion should be made possible.

This task is performed with a changeover valve of the generic type solved by the features in the characterizing part of claim 1.

The measures according to the invention ensure that with a single sealing ring the sealing of one or more entrances ge compared to a maximum of two exits and the sealing of the valve can be done externally.

Numerous, partly inventive, configurations result from the Subclaims and the following description of an embodiment example.

Further features, advantages and details of the invention emerge from the description of an embodiment with reference to the drawing. Show it

Fig. 1 is a hydraulic adjusting device, and two pairs of column ben-cylinder units, which are connected through a switching valve with an alternate apparatus

Fig. 2 shows a section through the housing of the switching valve according to the section line II-II in Fig. 3,

Fig. 3 shows a cross section through the housing of the switching valve accordingly the section line III-III in Fig. 2,

Fig. 4 shows a slider of the switching valve in side view,

Fig. 5 shows a cross section through the slide valve along the line VV in Fig. 4,

Fig. 6 shows a cross section through the change-over valve according to the section line VI-VI in Fig. 7,

Fig. 7 shows a cross section through the change-over valve according to the section line VII-VII in Fig. 6,

Fig. 8 is a plan view of the switch valve according to the arrow VIII in Fig. 9 and

Fig. 9 is a side view of the switching valve according to the arrow IX in Fig. 8.

In Fig. 1, a hydraulic adjusting device 1 is shown, which is known from EP 0 026 526 B1 (corresponding to US Patent 4,373,334) and DE 43 08 455 A1 and as they under the protected name "MOVOTEC "of VERIN SA / Switzerland, is commercially available. It has a housing 2 in which pistons, not shown, can be adjusted in the direction of the longitudinal axis 4 of the housing 2 by means of a spindle 3 which can be driven in rotation from the outside. As a result of this adjustment of the pistons, pressure fluid is pressed into pressure medium supply lines 5 , 6 , which are connected to a changeover valve 7 . From the changeover valve 7 , four pressure medium lines 8 , 9 , 10 , 11 lead out, which lead to hydraulically loadable piston-cylinder units 12 , 13 , 14 , 15 , the respective piston rods 16 and 17 of which are in pairs mutually associated cylinders 18 , 19 are extendable. The total length of the piston-cylinder units 12 and 13 or 14 and 15 can be changed by evenly retracting or extending the piston rods 16 from the cylinders 18 or the piston rods 17 from the cylinders 19 . The piston-cylinder units 12 , 13 and 14 , 15 assigned to each other in pairs can be, for example, two columns of a work table or a work bench or a work platform or the like. This possibility of use is also known from EP 0 026 526 B1 (corresponding to US Pat. No. 4,373,334) and DE 43 08 455 A1 and is implemented in the practical designs. The changeover valve 7 is new in this context.

The switch valve 7 has a housing 20 which is plate-shaped, that is to say relatively flat, and has two bores 21 , for example for attachment to the underside of a table top or the like. The lines 5 , 6 and 8 to 11 are formed in the housing 20 , distributed over the circumference of the connections connected to this. These connections form inputs 22 , 23 for the pressure medium supply lines 5 , 6 and outputs 24 , 25 , 26 , 27 for the pressure medium lines 8 , 9 , 10 , 11 . A cylindrical housing space 28 extending through the housing 20 is formed in the middle of the housing 20 of the changeover valve 7 . An annular groove 31 is machined into the cylindrical boundary wall 30 of this space 28 concentrically with its central axis 29 . In the - seen from the central axis 29 - radially outer, in cross-section semicircular, the groove base forming, outer boundary surface 32 of the annular groove 31 , the inputs 22 , 23 and the outputs 24 to 27 each open via a connecting channel 33 , the diameter a clearly is smaller than the diameter b of the outer boundary surface 32 , which speaks the extent b of the annular groove 31 in the direction of the axis 29 ent. At the semicircular outer boundary surface 32 of the annular groove 31 adjoin two mutually parallel annular loading boundary surfaces 34 , which are also concentric to the axis 29 and extend from the boundary wall 30 to the outer boundary surface 32 and the distance from each other is b. 0.6 bc b applies to the depth c of the annular groove 31 from the boundary wall 30 in the radial direction from the axis 29 . Preferably 0.8 b <c <b.

In the annular groove 31 , a sealing ring 35 is arranged in the form of an O-ring, whose diameter d corresponds approximately to the diameter d 'of the annular groove 31 and whose cross-sectional diameter e corresponds approximately to the cross-sectional diameter b of the outer boundary surface 32 . When the sealing ring 35 is inserted into the annular groove 31 , it protrudes - which is not immediately apparent from the drawing - radially inwards somewhat beyond the boundary wall 30 into the cylindrical housing space 28 .

In the cylindrical space 28, a slide 36 is arranged, which in principle has a cylindrical shape whose diameter f - at Vernach lässigung the necessary play - the diameter g of the housing 28 corresponds to Rau mes. The length h of the slide 36 in the direction of the axis 29 is less than the thickness i of the plate-shaped housing 20 . The slide 36 has on its cylindrical outer surface 37 two parallel to the axis 29 flats 38 , 39 which - based on the circular cross-section of the slide 36 - are limited or formed by secants. The flats 38 , 39 are diametrically opposite one another. The slider 36 presses with its partially cylindrical surfaces 36 a, the device ring 35 into the annular groove 31 .

As can be seen from the drawing, the two inputs 22 , 23 are arranged diametrically opposite one another in the housing 20 . Each input 22 or 23 is assigned two outputs, namely an output which leads to a piston-cylinder unit of the pair of units 12 , 13 and an output which leads to a piston-cylinder unit of the pair of units 14 , 15 . Specifically, the two outputs 24 , 26 are assigned to the input 22 and the outputs 25 , 27 to the input 23 . Each of a, a gear 22 and 23 respectively associated with outputs 24, 26 and 25, 27 on both sides of the respective input 22 and 23, and indeed at equal intervals of k junctions 40 of the connecting channels 33 in the annular groove 31 from each other. These distances k each a mouth 40 of a connec tion channel 33 of the outputs 24 and 26 from the input 22 and from the outputs 25 and 27 from the input 23 is slightly smaller than the secant length l of the flats 38 , 39 , again the secant length l is significantly smaller than the distance m between the openings 40 of the outputs 24 , 26 and 25 , 27 assigned to an input 22 and 23 , respectively. This makes it possible for the flats 38 , 39 to connect the two inputs 22 , 23 either to the outputs 24 and 25 or to the outputs 26 , 27 in a pivoting position of the slide 36 . In the pivot position 41 , the piston-cylinder units 12 , 13 are connected to the adjusting device 1 , while in the pivot position 42, as shown in FIG. 8, the other two piston-cylinder units 14 forming a pair , 15 are connected to the setting device 1 . In the intermediate position 43 located between these two pivot positions 41 , 42 , no outlet 24 , 25 , 26 , 27 is connected to an inlet 22 , 23 .

In the described bridging of inputs 22 , 23 and outputs 24 , 25 , 26 , 27 , the O-shaped sealing ring 35 is caused by the pressure of the pressure fluid, which at the corresponding inlet 22 or 23 or at the corresponding outlet 24 , 25 or 26 , 27 is present, pressed against the associated flattening 38 or 39 of the slide 36 , whereby a bridging space 44 or 45 is formed between the sealing ring 35 and the outer boundary surface 32 of the annular groove 31 , which bridges the input and the output. These bridging spaces 44 , 45 connect the openings 40 of the connecting channels 33 in the manner described. During this deformation of the sealing ring 35, it remains in the annular groove 31 in a sealing manner, and in particular it remains in sealing contact with the annular boundary surfaces 34 . The two bridging spaces 44 , 45 are thus still sealed against the cylindrical housing space 28 in the housing 20 . No hydraulic fluid can flow there. Also in the circumferential direction, no liquid can flow into the annular groove 31 , since the sealing ring 35 is pressed firmly and sealingly into the annular groove 31 by the partially cylindrical flanks 36 a of the slide 36 .

When the spindle 3 is actuated An alternate apparatus 1 in such a manner in the pivotal position 41 of the slider 36 so that pressurized fluid from the adjustment device 1 through the pressure supply conduit 5, 6 flows, the piston rods 16 of the cylinders 18 are the extended in the piston-cylinder units 12 , 13 forming a pair. Here, the pressure of the fluid at the inlets 40 of the A located passages 22, 23 and presses from here, starting the sealing ring 35 Ge Gen the flats 38,. 39 On the other hand, if the spindle 3 is actuated in such a way that the hydraulic fluid flows back into the adjusting device 1 , then the corresponding fluid pressure is present at the orifices 40 of the outputs 24 , 25 and, starting from there, presses the sealing ring 35 against the flattenings 38 , 39 . The same applies to the pivot position 42 .

The pivoting of the slide 36 takes place by means of an actuating lever 46 which can be attached in a rotationally fixed manner to a pivot pin 47 of the slide 36 by means of a screw 48 serving as an anti-rotation device.

In the housing 20 cover plates 49 , 50 are pressed into corresponding ring-cylindrical recesses 51 after the assembly of the sealing ring 35 and the slide 36 . These cover plates 49 , 50 hold the slide 36 in its position in the direction of the axis 29 so that it can not move. On the side of the housing 20 assigned to the actuating lever 46 , stops 52 , 53 can be formed for fixing the pivot positions 41 , 42 .

In addition, the distance m between two adjacent outlets 40 from adjacent but not paired outputs 25 and 26 or 24 and 27 is greater than the secant length l, so that even in the absence of the stops 52 , 53 such outputs are not bridged can.

The described design makes it possible to connect two pairs of piston-cylinder units with one adjustment device and to adjust their length absolutely uniformly. At a setting device 1 , for example, two work tables, Ar beitsbühnen or the like can be connected, which are each supported on two height-adjustable supports.

The input 22 and the associated outputs 24 , 26 or alternatively the input 23 and the associated outputs 25 , 26 can be closed by grafting, so that only one input with two outputs remains available. It should also be pointed out that the term input and the term output are a question of definition. As can be seen from the above description, the outputs 23 to 26 act on the return flow of the pressure medium to the setting device 1 as inputs and the inputs 22 and 23 in this context as outputs.

Claims (7)

1. changeover valve with a housing ( 20 ) which has a housing space ( 28 ) into which at least one inlet ( 22 , 23 ) and at least one outlet ( 23 to 26 ) for a pressure medium opens, and with one in the housing space ( 28 ) arranged about an axis ( 29 ) pivotable slide ( 36 ), which is seen with at least one recess (flattened area 38, 39 ), optionally in an input ( 22 , 23 ) and one From output ( 23 to 26 ) bridging position can be brought, sealing means for sealing the at least one input ( 22 , 23 ) against the at least one output ( 23 to 26 ) and the housing space ( 28 ) are provided to the outside, thereby characterized in that in the housing ( 20 ) to the housing space ( 28 ) open to the axis ( 29 ) concentric annular groove ( 31 ) is formed by a radially outer boundary surface ( 32 ) forming the groove base and two itself to this subsequent to the Ge housing space ( 28 ) directed ri Ng-shaped boundary surfaces ( 34 ) is limited so that the at least one inlet ( 22 , 23 ) and the at least one outlet ( 23 to 26 ) open into the annular groove ( 31 ) in the region of the outer loading boundary surface ( 32 ) that in the annular groove ( 31 ) a sealing ring ( 35 ) is arranged, which bears against part-cylindrical surfaces ( 36 a) of the slide ( 36 ) and is sealingly pressed against the outer boundary surface ( 32 ) and the annular boundary surfaces ( 34 ), and that the at least one recess (Flattening 38, 39 ) of the slide ( 36 ) in such a way that in the position bridging an inlet ( 22 , 23 ) and an outlet ( 23 to 26 ) the sealing ring ( 35 ) under the pressure of the pressure medium from the outer boundary surface ( 32 ) lifts off and into the recess (flattened 38, 39 ) of the slide ( 36 ), but remains in sealing contact with the annular boundary surfaces ( 34 ), whereby a the entrance ( 22 , 23 ) and de n an outlet ( 23 to 26 ) connecting, sealed bridging space ( 44 , 45 ) is formed between the sealing ring ( 35 ) and the outer boundary surface ( 32 ) of the annular groove ( 31 ). 2. changeover valve according to claim 1, characterized in that the slide ( 36 ) is cylindrical and is provided with at least one recess forming the parallel to the axis ( 29 ) flattening ( 38 , 39 ). 3. changeover valve according to claim 1 or 2, characterized in that on both sides of an input ( 22 , 23 ) two outputs ( 24 to 27 ) at equal intervals (k) to the respective input ( 22 , 23 ) in the annular groove ( 31 ) lead to. 4. changeover valve according to one of claims 1 to 3, characterized in that the boundary wall ( 30 ) of the housing space ( 28 ) on both sides of the annular groove ( 31 ) is cylindrical. 5. changeover valve according to one of claims 1 to 4, characterized in that the depth (c) of the annular groove ( 31 ) radially to the axis ( 29 ) is narrower than its extension (b) in the direction of the axis ( 29 ) . 6. changeover valve according to claim 5, characterized in that for the radial depth (c) of the annular groove ( 31 ) in relation to its axial extension (b) applies: 0.6 b <c <b. 7. changeover valve according to one of claims 1 to 6, characterized in that the housing ( 20 ) is integrally, plate-shaped.