DE20321390U1 - Multi-port rotary disc valve for inflating and deflating pressure cells in therapeutic massage sleeve comprises rotary distributor having channels arranged in channel pattern, rotor and movably mounted mask - Google Patents

Abstract

A multi-port rotary disc valve comprises a rotary distributor having channels arranged in a channel pattern and including a rotor and a movably mounted mask. The rotor and the mask accommodate the channels. The mask is adapted to change the channel pattern by changing its position with respect to the rotor to enable the disc valve to perform different predetermined sequences corresponding to different positions of the mask. A multi-port rotary disc valve comprises a stator (14) with fluid flow ports and a rotary distributor with channels (35, 36) arranged in a channel pattern. The channels are adapted to connect the ports between them and/or to the environment in predetermined combinations. Each combination is associated with an angular position of the rotary distributor with respect to the stator. A succession of the combinations performed during a full or partial unidirectional turn of the rotary distributor constitutes a predetermined sequence. The rotary distributor comprises a rotor (16) and a movably mounted mask (20). The rotor and the mask accommodate the channels. The mask is adapted to change the channel pattern by changing its position with respect to the rotor to enable the disc valve to perform different predetermined sequences corresponding to different positions of the mask.

Description

Territory of invention

These The invention relates to rotary valves for supplying a fluid flow and / or Pressure in several openings, in particular valves for carrying out a certain cycle of delivery processes, such as For example, numerous cyclic filling and emptying several Pressure cells in a fillable or inflatable device.

background the invention

In US-P-5,014,681, incorporated herein by reference, is a rotary valve for filling and emptying pressure cells in a therapeutic envelope disclosed. This rotary valve consists of two discs: one Stator disk with fluid flow openings, which can be connected to a compressor and the pressure cells, and a rotary distribution disc, with the two discs along a planar, perpendicular to the axis of rotation contact surface in occlusive manner get in touch. The openings open the stator disc at the contact surface. The Turn-distribution disk has several U-channels and continuous Windows open on the touch surface as well are open. The channels and windows are sized such that during rotation of the rotary distribution disc the compressor flow successively through the appropriate openings is directed to fill the corresponding pressure cells, which then successively to the atmosphere open all of which follows a particular sequence.

The JP 01145474 discloses a rotary valve having a similar function in which the stator comprises two disks fixed relative to each other, the stator disk slidingly contacting a rotor distributor disk therebetween. The rotor disk has U-channels and through-holes, which connects the openings of the stator during rotation of the rotor distributor disc in various combinations.

The US-P-4,614,205 discloses a multi-opening rotary valve with a similar function for connecting several at the same time channels after a certain cycle. The stator and the rotary distribution device In this rotary valve are superstructures, each two parallel Include plates or discs. The rotary construction is between two parallel plates of the stator assembly sandwich-like arranged. Between the rotor plates extend transfer tubes to comparable to the mentioned above versions either U-channels or train passageways.

The known rotary valves are capable of a specific Cycle (sequence) of connections between the stator openings perform. The connections can by controlling the regular speed and the position of the rotor can be varied in time, their course however, is due to the patterns of the channels in the rotor and the stator established.

Summary the invention

In accordance with the present invention, a multi-opening rotary valve is provided, which includes a stator with multiple fluid flow openings and a rotary distribution device having a plurality of arranged in a channel pattern Channels. The channels are adjusted, the openings between each other and / or with the environment in several particular Combine combinations, with each combination with an angular position the rotary distribution device associated with the stator is. A sequence of such combinations that during a full or partial unidirectional rotation of the rotary distribution device accomplished be, form a specific sequence. The rotary distribution device comprises a rotor and a mask mounted thereon, being several channels are housed. The mask is adapted to the channel pattern by changing its Changing position with respect to the rotor, causing the disc valve allows will execute different specific sequences, which are different Correspond to positions of the mask.

In a preferred embodiment the mask and the rotor are coaxially arranged and rotatable together Discs caused by a reversible, controllable electric Drive are driven. The rotary distribution device is relative to the stator rotatably mounted only in a first direction while the Mask disc with respect the rotor disk only in a second direction, opposite to the first direction, is rotatably mounted. This turns the Rotary distribution device only when the electric Drive turns in the first direction while the mask disc in terms of the rotor disk only rotates when the drive is in the second Direction turns.

In a further embodiment of the rotary valve, the rotor disk has two sides, with at least a part of the rotary distribution device channels connecting them. The first side closes in contact with one side of the stator, with the connections between the stator openings and the rotary distribution device channels are executed via this page. The second side closes into contact with one side of the mask disk and the mask disk changes the channel pattern by switching connections between those channels exiting the second side.

The Rotary valve for filling and Emptying of N cells used comprises a central inlet port and N outlet openings, around the central opening are arranged. The rotor disk has a supply channel which is such is configured during that a rotation of the rotary distribution device, the central inlet opening in successively connects with each of the outlet openings.

The Rotary valve is also for a group escape of all N filled cells suitable. To this Purpose, the rotor disk on N passage windows, which the connect the first page to the second page and are configured to that at a certain angular position A of the rotary distribution device with respect to the stator, the N passage windows with the N outlet openings match. The mask disk has a group escape channel configured such that at a certain angular position B of the mask disc with respect to the rotor disc of the group escape passage is connected to all of the passage window of the rotor disk. The group escaping channel may further be connected to a vacuum source, such as connected to the input of a compressor or a pump, whereby a group evacuation of any volumes is made possible those with the N outlet openings of the stator, provided that the positions A and B are reached simultaneously.

Preferably, the rotary valve is adapted to operate as part of a computer-based system for filling and draining in cycles of N cells connected to the N outlet ports. The stator of the rotary valve has N through-pressure ports respectively disposed adjacent to one of the N exhaust ports, and a pressure port connecting the pressure ports to a pressure port. The rotor disk has a bypass passage configured to be able, when rotated, to connect any one of the exhaust ports to the corresponding adjacent pressure port while keeping the residual pressure ports stopped, thereby providing detection of Pressure P _{C is} made possible in a volume which is connected to any outlet opening. Preferably, the bypass passage is disposed behind the supply passage with respect to the first rotational direction, so that the bypass passage is connected to the discharge port No. n when the supply passage is between the discharge port No. n + 1 and the discharge port No. n + 2 where n is an ordinal number from an exhaust port, where n increases in the first direction. The system comprises a sensor for detecting the pressure P ₀ in the central inlet port and a sensor for detecting the pressure P ₀ in the pressure outlet. The system is programmed to terminate the filling of a given cell at a given instantaneous value of the pressure P ₀ to obtain a built-up target pressure P _E in the cell, and wherein the system is adapted to correct the instantaneous value in a next cycle, when the detected pressure P _C in a current cycle is different from the target pressure P _E.

Short description the drawings

Around to understand the invention and to see how they are carried out in practice can now be a preferred embodiment only by a non-limiting example with reference to the accompanying drawings be described, wherein:

1 an exploded view of a rotary valve according to the invention is;

2A . 2 B and 2C each views from below, above and a sectional view of in 1 shown stator are;

3A . 3B and 3C each views from below, above and a sectional view of in 1 shown rotor disk are; and

4A . 4B and 4C each views from below, above and a sectional view of in 1 are shown mask disk.

Full Description of the invention

In 1 is a multi-opening rotary valve 10 according to the present invention, for example, to be used with a fillable device having a plurality of pressure cells. An example of such a fillable device is used in the statements without limiting the scope of the invention. The device is a therapeutic massage sheath with N-annular cells surrounding a human limb (not shown), as described in incorporated US-P-5,014,681. The annular cells are close to each other or even overlap slightly, and they must be cyclically filled or deflated in various sequences depending on the therapeutic method.

The rotary valve 10 includes a housing 12 , a stator disc 14 , a rotor disk 16 , a mask disk 20 , a coupling disc 22 and a drive motor 24 in which all are for a coaxial construction along axis 2 are adapted to the valve.

The housing 12 is a massive plate with an annular recess 26 that the stator 14 with several N outlet windows 28 around the axis 2 are arranged in a fan-like manner with a certain uniform angular distance Δα from each other. The outlet windows 28 are through individual channels (not visible) with outlet openings 30 connected. In operation are the outlet openings 30 connected by tubes to the fillable cells of a fillable device, such as a massage sheath (not shown). The housing 12 also has a central inlet opening 32 , which can be connected to a source of pressurized fluid, such as the discharge of an air compressor (not shown), an escape port 34 and a vacuum port 33 , which can be connected to a vacuum source, such as the inlet of an air compressor. The housing also has a channel 35 for detecting the air pressure of the inlet flow on and a channel 36 for detecting the air pressure in filled cells, as will be described in more detail below.

In the 2A . 2 B and 2C , is the stator 14 a disc with a wide axial opening 38 and with several different passage windows, recesses and channels. In particular, the stator 14 N passage outlet window 40 on that with the outlet windows 28 match the housing, and N through-pressure openings 46 , each adjacent to an outlet window 40 are arranged. At the bottom, the case 12 ( 2A ) facing side of the stator are the output sides of the N outlet window 40 , a curved, the windows 40 concentric spanning vacuum channel 42 , and a curved with the vacuum channel 42 concentric cell pressure channel 44 , which internally with the N pressure ports 46 connected is. When the stator is mounted in the housing, the end fits 47 of the cell pressure channel 44 with the inlet of the detection channel 36 together. An escape recess 48 that is positioned to with the escape opening 34 of the housing 12 to fit together stands by a slot 51 with an escape window 50 on the upper side of the stator ( 2 B ) in fluid communication. At the top, the rotor 16 facing side of the stator are also the input sides of the outlet window 40 and several recesses 52 in a fan-like manner between the outlet windows 40 are arranged. The recesses 52 are further from the window axis than the windows 40 and are internally with the escape channel 42 connected to the lower side of the disc. The printing openings 46 connect the cell pressure channel 44 on the bottom surface of the stator with the top, the rotor 16 facing surface of the stator. A long, arched recess 54 has a wide opening 56 which is adapted to the vacuum opening 33 in the case 12 to fit together and through a slot 55 with the escape channel 42 is in fluid communication. An extension 58 the recess 54 is through a narrow passage 60 connected.

The stator 16 is on the case 12 in the recess 50 in occlusive fashion and works as an integral body with the housing.

With reference to 3A . 3B and 3C has the rotor disk 16 at the bottom, the stator 14 ( 3A ) facing side a hidden or blind recess 62 on. On the same side, the rotor has a radial supply channel 64 up, extending from the recess 62 extends to a radius that is suitable to the outlet window 40 on the stator 14 to cover when the valve is built. On one side of the feed channel 64 are several N + 3 windows 66 arranged in a fan-like manner. The window 66 are at an angular distance Δα from each other and from the supply channel 64 so they are capable of using the windows 40 on the stator 16 to fit together when the valve is assembled. A group of three windows 68A . 68B and 68C that are similar to the windows 66 are on the other side of the feed channel 64 localized. Between the windows 66 is a group of N openings 70 arranged by the axis 2 the valve continues as the outer edge of the windows 66 are removed. One and a half angular steps Δα from the feed channel 64 is a single bypass recess 72 placed. The recess 72 has such a radial extent that it is the fluid connection between a window 40 and a corresponding pressure opening 46 can cover and build on the stator when the valve is built (also in 2 B shown in broken line). The rotor also has a wide window 74 on top of that, the arch of the windows 66 and 68 completed to a whole ring. There is a wide escape opening on the rotor 76 arranged by the axis 2 further than the openings 70 is removed and configured to work with the recess 54 to fit together on the stator. At the circumference of the rotor disk 16 There are several inclined teeth 78 , which form part of a ratchet or a ratchet or a gearbox, and are adapted to with the coupling disc 22 ( 1 ) to be engaged.

In the 4A . 4B and 4C has the mask disk 20 a wide, arched fens ter 80 with a radial extent similar to that of the windows 66 on the rotor 16 on, and an angular extent that is suitable N window 66 to cover when the mask disc 20 on the rotor 16 is appropriate. The mask disk 20 also has a group of three adjacent escape windows 82A . 82B and 82C on and a remote escape window 84 each adapted to the escape opening 76 on the rotor 16 to fit together. At the bottom, the rotor 16 facing side of the mask is a group escape recess 86 which is similarly shaped to and adjacent to the group of windows 82 is arranged. The group escape recess 86 stands with an arcuate escape channel 88 in conjunction, which has an angular extent, a radial position and a width, which are suitable with the openings 70 to fit together and all this through the escape recess 86 with the escape opening 76 to connect to the rotor when the mask disk 20 on the rotor 16 is appropriate. At the circumference of the mask disk 20 There are three pairs of teeth 90 to the mask disc with the coupling disc 22 ( 1 ) to couple.

In the 1 is the coupling disc 22 a thin disk with three straight teeth 92 that with the tooth 90 at the mask disk 20 fit together, and a spring latch 94 , The coupling disc is on the shaft (not visible) of the electric motor 24 fixed.

The electric engine 24 is reversible and controllable by angular velocity and angular coordinate. The control system (not shown) includes, among other things, a sensor 96 for the angular position of the rotor disk 16 and a sensor 98 for the angular position of the mask disk 20 ,

When assembled, the rotor sits 16 on the stator 14 and is by a one-way camp 18 that allows rotation of the rotor only in direction A, rotatable with the housing 12 connected. The mask disk 20 sits rotatably on the rotor 16 , The coupling disc 22 is with the mask disk 20 through the tooth 90 and 92 engaged to turn the mask in any direction. At the same time the spring latch 94 the coupling disc 22 with the tooth 78 the rotor disk 16 engaged to form a ratchet mechanism, that of the mask 20 allowed with respect to the rotor 16 only to be turned in direction B The stator 14 , the rotor 16 and the mask 20 are pressed together by a spring means (not shown) for airtightness. Thus, turning when the engine 24 towards A, the mask disc 20 and the rotor 16 together as a single body, and form a rotary distribution device with the stator 14 cooperates to control the air coming from the air compressor in a particular sequence to the exhaust ports 30 respectively. This mode of rotation is referred to as a "ready to operate" mode. When the motor turns in direction B, the rotor stops 16 in relation to the stator 14 quiet while the mask disk 20 with respect to the rotor 16 slides to change its angular position with respect to the rotor, thus producing another rotary distribution device capable of executing another specific sequence. This manner of rotation is referred to as "installation mode". Thereby, the rotary valve according to the invention can perform the function of various conventional multi-opening spool valves.

below For example, a number of particular sequences are explained by way of example only.

Sequence A: Sequential Filling - simultaneous emptying.

The mask disk 20 becomes with respect to the rotor 16 turned towards B in a position where the escape window 84 with the escape opening 76 and at the same time the wide, arched window 80 the mask all N windows 66 covered by the rotor. In the initial position of the rotor 16 in relation to the stator 14 is the supply channel 64 above the escape window 50 , This is a standby or idle mode where the pressurized air from the compressor is through the central inlet port 32 and the axial opening 38 to the recess 62 and the feed channel 64 comes and the rotary valve through the escape window 50 and the escape opening 34 leaves.

If the rotor 16 begins to turn toward A, the supply channel moves 64 over the nearest outlet window 40 ₁ , which is connected to the first annular cell, and begins to fill. After a certain time or after a certain pressure has been reached in the first cell, the rotor continues to move and the supply channel 64 fits now with the nearest recess 52 ₁ together, with the escape channel 42 is connected while the fluid connection with the first cell is stopped. This is also a standby mode. After a certain time, the rotor will continue to move and the feed channel will match the next outlet window 40 ₂ together to fill the next cell. Thus, all N cells are filled in sequence until the feed channel is the last outlet window 40 _N reached. After a certain time, the rotor makes about half a turn, leaving all N outlet windows 40 with the windows 66 match up and with the atmosphere over the window 80 communicate with the mask. There The cells are simultaneously emptied and sequence A is terminated.

Sequence B: Sequential Filling - sequential emptying.

The mask disk 20 becomes with respect to the rotor 16 turned towards B in a position where the escape window 82A with the escape opening 76 and at the same time the wide, arched window 80 the mask the windows 68A . 68B and 68C covered by the rotor. In the initial position of the rotor 16 in relation to the stator 14 is located, as above, the supply channel 64 above the escape window 50 ,

If the rotor 16 starts to turn towards A, the supply channel moves 64 over the nearest outlet window 40 ₁ which is connected to the first annular cell, and it is filled. Then the rotor continues to move and the feed channel 64 fits now with the nearest recess 52 , together (standby mode). After a certain time, the rotor continues to move and the supply channel 64 fits with the next outlet window 40 ₂ together to fill the next cell. At the same time the window fits 68A of the rotor with the first outlet window 40 ₁ together and the first cell releases its pressure through the window 80 into the atmosphere. Thus, all N cells are filled in sequence and each is emptied when the next cell is filled.

If the escape window 82B the mask alternatively opposite to the escape opening 76 the rotor is fixed, then the window 80 the mask only windows 68B and 68C of the rotor. Thus, the outlet window becomes 40 ₁ only open to the atmosphere when the window 68B matches with it what will happen when the supply channel 64 the outlet window 40 ₃ reached. When the escape window 82C the mask opposite to the escape opening 76 is fixed, opens the outlet window in a similar manner 40 ₁ to the atmosphere only if that window 68C mates with it, which occurs when the supply channel 64 the outlet window 40 ₄ reached. This sets the three escape windows 82A . 82B and 82C the mask with the cooperation of the three windows 68A . 68B and 68C of the rotor provide three sequences B, each characterized by a different offset in cell depletion.

Sequence C: Active suction.

The mask disk 20 becomes with respect to the rotor 16 rotated in the direction B in a position at which the group escape recess 86 with the escape opening 76 matches. The rotor 16 will now be together with the mask disk 20 in relation to the stator 14 turned in the direction A in a position in which the supply channel 64 above the escape window 50 in standby mode, as above. The escape opening 76 is now above the arcuate recess 54 positioned and in fluid communication with the vacuum port 33 which is connected to the compressor input. The arcuate escape channel 88 covers all openings 70 of the rotor, in turn, with the inlet windows 40 match. Thus, the Kompressorsaugung provides the rapid emptying of Massagehüllzellen ready.

The rotary valve of the present invention may conveniently be used in a computer-based filling and deflation system in cycles of multiple cells connected to the outlet ports, for example, in the therapeutic sheath shown in U.S. Patent No. 5,014,681. The system is programmable to complete the filling of each cell when a given instantaneous value of the pressure P _{0 is} reached (ie by moving the supply channel 64 to the standby position or to the next cell). However, the instantaneous pressure P ₀ is unstable during filling, and even if the system stops filling at P ₀ = P _E , the build-up pressure P _C in the cell may be different from the target pressure P _E after a short time. Another factor that can affect the build-up pressure P _C in the cell is filling the next adjacent cell, especially when the cells overlap. The computer-based system that controls the fill-empty method requires that the actual built-up pressure P _C in the cell be detected to compare it with the target pressure P _E and to try the difference ΔP = P _E -P _C by minimizing the determined pressure P ₀ for that particular cell when the next round comes to fill the same cell.

The rotary valve facilitates the above-mentioned method for precisely reaching a target pressure P _E in the filled cells. The instantaneous pressure P ₀ is detected at the central inlet opening of the rotary valve by a pressure sensor connected to the channel 35 connected is. The detection of the established cell pressure P _C is, after the next cell is filled, through the bypass recess 72 provided on the rotor, the one and a half angular steps .DELTA..alpha. with respect to a rotation direction A behind the supply channel 64 is localized. When the feed channel 64 two consecutive cells via the corresponding outlet windows 40 filled and in standby position halfway to a third outlet window 40 is located, then covers the bypass recess 72 the first outlet window 40 and a corresponding opening 46 on the stator. This is a fluid connection between the ers filled cell and the cell pressure channel 44 provided via the detection channel 36 is connected to a pressure sensor, and the built-up cell pressure P _C is detected.

Although a description of specific embodiments has been presented, it is contemplated that various changes may be made without departing from the scope of the present invention. For example, the mask may be movable relative to the rotor not only by rotation, but by any other way that provides commutation of the channels of the rotary distribution device; the mask may comprise a plurality of movable parts; the rotor and the mask may be driven by means other than an electric motor; the rotary distribution device may be driven by a motor and the mask may be driven by another motor; the disks may come in contact therebetween along a conical or other surface of rotation, etc. The stator may also comprise two disks with inlet or outlet windows on either side of the rotary distribution device, in a manner similar to the US Pat. 4,614,205 or to JP 01145474 , which are hereby incorporated by reference.

Claims (23)

Multi-opening rotary valve ( 10 ), which comprises a stator ( 14 ) with a plurality of fluid flow openings ( 38 . 40 . 56 ), and a rotary distributor device ( 16 . 20 ) with several channels ( 64 - 76 . 80 - 88 ), which are arranged in a channel pattern, wherein the channels are adapted to connect the openings between each other and / or the environment in several specific combinations, each combination with an angular position of the rotary distribution device ( 16 . 20 ) with respect to the stator ( 14 ), wherein the rotary distributor device comprises a rotor ( 16 ) and a mask ( 20 ) movably mounted thereon for movement between positions with respect to the rotor, wherein 20 ) cover at least a portion of the channels accommodated by the rotor to connect at least a portion of the openings between each other and positions in which the mask allows at least a portion of the latter channels to communicate with the environment. Rotary valve according to claim 1, wherein the mask ( 20 ) is movable by rotation with respect to the rotor. Rotary valve according to claim 2, wherein the rotation of the rotary distributor device ( 16 . 20 ) and the rotation of the mask ( 20 ) around the same axis. Rotary valve according to claim 3, wherein the rotor ( 16 ) and the mask ( 20 ) are coaxial and rotatable discs together. A rotary valve according to any one of claims 1 to 4, wherein the rotary distributor means ( 16 . 20 ) by means of an electric drive ( 24 ) is rotatable. Rotary valve according to one of claims 1 to 5, wherein the mask ( 20 ) by an electric drive ( 24 ) is rotatable. Rotary valve according to claim 4, wherein the rotary distributor device ( 16 . 20 ) is rotatable with respect to the stator only in a first direction. Rotary slide device according to claim 7, wherein the mask disc ( 20 ) with respect to the rotor disk only in a second direction, opposite to the first direction, is rotatable. Rotary valve according to one of claims 1 to 8, wherein the rotation of the mask disc ( 20 ) in the second direction (B) only by a pawl lock mechanism ( 78 . 94 ). Rotary valve according to one of claims 1 to 9, which further comprises a single reversible, electric drive ( 24 ), whereby the rotary distribution device ( 16 . 20 ) only rotates when the drive ( 24 ) in the first direction (A), and the mask disc ( 20 ) with respect to the rotor disk ( 16 ) only rotates when the drive rotates in the second direction (B). Rotary slide valve according to one of claims 1 to 10, wherein the rotor disc ( 16 ) has a first side in occlusive manner with one side of the stator ( 14 ) and the connections between the stator openings ( 40 ) and the rotary distribution device channels ( 64 - 76 ) on the first page. Rotary slide valve according to claim 11, wherein the rotor disc ( 16 ) has a second side in occlusive manner with one side of the mask disc ( 20 ), at least a portion of the plurality of channels ( 66 - 76 ) on the second side, and the mask disc ( 20 ) changes the channel pattern by switching connections between the part of channels that exit at the second side. A rotary valve according to claim 12, wherein the plurality of fluid flow openings comprise a central inlet opening (16). 38 ) and N outlet openings ( 40 ), which are arranged around the central opening. Rotary valve according to claim 13, wherein the rotor disc ( 16 ) a supply channel ( 64 ) configured such that during a rotation of the rotary distribution device ( 16 . 20 ) the supply channel ( 64 ) successively the central inlet opening ( 38 ) with each of the N outlet openings ( 40 ) connects. Rotary valve according to claim 14, wherein the rotor disk ( 16 ) N passage window ( 66 ), which connect the first side to the second side, with such a configuration that at a certain angular position A of the rotary distribution device ( 16 . 20 ) with respect to the stator ( 14 ) the N passage windows ( 66 ) with the N outlet openings ( 40 ) match. A rotary valve according to claim 15, wherein the mask disc ( 20 ) a group escaping channel ( 86 - 88 ) configured such that at a certain angular position B of the mask disk ( 20 ) with respect to the rotor disk ( 16 ) the group escape channel ( 86 - 88 ) with all N passage windows ( 66 ) of the rotor disk ( 16 ), and can be connected to a vacuum source, thereby enabling group evacuation of any volumes associated with the N outlets (FIGS. 40 ) of the stator, provided that the positions A and B are reached. A rotary valve according to claim 16, wherein the vacuum source an entrance opening a compressor or a pump. Rotary valve according to claim 16 or 17, wherein the stator ( 14 ) a vacuum opening ( 54 - 56 - 33 ), which can be connected to the vacuum source, and the rotor disc ( 16 ) an escape opening ( 76 ) which is configured to be in the position B of the mask disk (FIG. 20 ) with the group escaping channel ( 86 - 88 ) and in the position A of the rotary distribution device ( 16 20 ) mates with the vacuum port. A rotary valve according to any one of claims 14 to 18, wherein the plurality of fluid flow ports ( 38 . 40 . 56 ), several escape openings ( 52 ) connected to the ambient atmosphere ( 42 ) and at least in part between the N outlet openings ( 40 ) are arranged so that the supply channel ( 64 ) during a rotation of the rotary distribution device ( 16 20 ) with one of the escape openings ( 52 ) while not communicating with any of the N outlets ( 40 ) communicates. Rotary valve according to one of claims 14 to 19, wherein the stator ( 14 ) N through-pressure openings ( 46 ), each adjacent to one of the N outlet openings ( 40 ) are arranged, and wherein a pressure channel ( 44 ) the printing openings ( 46 ) with a pressure outlet ( 47 . 36 ), which can be connected to a pressure sensor, wherein the rotor disk ( 16 ) a bypass channel ( 72 configured to rotate, when rotated, any one of the N outlet ports (FIGS. 40 ) with the corresponding adjacent pressure opening ( 46 ), while keeping the residual pressure ports stopped, thereby enabling detection of pressure P _C in a volume connected to the arbitrary outlet port by means of the sensor. A rotary valve according to claim 20, wherein the bypass channel ( 72 ) behind the feed channel ( 64 ) with respect to the first direction of rotation (A) is arranged, so that the bypass channel ( 72 ) with outlet opening no. n ( 40 _n ) is connected when the supply channel ( 64 ) between outlet port no. n + 1 and outlet port no. n + 2, where n is an ordinal number of one of the N outlet ports ( 40 ), where n increases in the first direction. A rotary valve according to claim 21, which forms part of a computer-based system for filling and emptying cycles of N cells which, by rotating the rotary distribution device ( 16 . 20 ), with the N outlet openings ( 40 ), the system further comprising a sensor for detecting the pressure P ₀ in the central inlet port ( 38 ), and wherein the pressure sensor for detecting the pressure P _C in the pressure outlet ( 47 . 36 ), the system being programmable to terminate the filling of one of the N cells at a given instantaneous value of the pressure P ₀ to obtain a formed target pressure P _E in the one cell, and wherein the system is adjusted to the instantaneous value in a next cycle when the detected pressure P _C in a present cycle is different from the target pressure P _E. Rotary slide valve according to one of claims 1 to 22, wherein the stator comprises two plates, each plate having a Housing part of the fluid flow openings, wherein the rotary distribution device between the two plates sandwich-like arranged.