DE4230185C2 - Directional spool for hydraulic controls - Google Patents

Description

The invention relates to a directional spool Preamble of claim 1 specified type.

With way valves is because of the space required and Weight aimed for a compact design. Frequently controls the spool when moving into and from the control positions control pressure medium, the Throughput is much lower than that of Working fluid. Sufficient for the control pressure medium much smaller channels than for the Working fluid. Must the control pressure medium over the same stroke can be controlled as that Working pressure medium, then for the control function the control pressure medium in the housing bore and Piston spool used the same overall length as for the control function of the working pressure medium. This therefore leads because of the control function of the Control pressure medium to unsuitably great length of the Slide piston and the housing bore or the housing and stands for a compact Directional spool towards. Even if the control channel mouth is small, the bridging channel in the Spool overlap the required stroke, and it must be ensured that the Bridging channel in control end positions of the Slide piston to neighboring working channel mouths in the slide bore a required Adheres to the sealing cover.  

For example, Figures 3, 3A of the US illustrate 39 71 216 how big through for a control function for Control pressure medium provided bypass channels in the Piston spool the length of the housing and Spool is. EP 01 67 818 B1, Fig. 2, shows that for the control function of the control pressure medium with the bridging channel in the spool approximately again the same axial length of the spool and the housing is used as for the Working pressure control function.

In a rotary valve known from FR 15 86 673 the channel openings in the slide bore are slanted offset from each other. It is for the Working pressure control function required channels. At one known from US 44 11 189 Directional spools are small in the spool Bores or axial longitudinal slots for the Control function of the control pressure medium provided. At one known from US 41 09 561 Directional spools are for the control function of the Control pressure by means of axial grooves in the scope of Slide piston provided by a cross continuous bore fluidly connected are. In a known from DE 30 22 592 A1 Directional spool is the control function of the Control pressure fluid that is in a small bore mouth the slide piston bore is present by a sealing axial region of the circumference of the Sliding piston and an end edge of the same. From JP-59-34 006 (A) it is known in one Directional control valve for the control function of the Working pressure by means of control notches or in the circumferential direction to use offset holes in the directional spool.

The invention has for its object a To create directional spool of the type mentioned, the despite having at least one tax function Sliding piston controlled control pressure medium builds short.

The object is achieved with the im Claim 1 specified Features resolved.

The bridging channel extends over the length predetermined axial section of the spool to the Control function of the control pressure medium with the Get working fluid control function, however can the control channel mouth because of each other separate depressions in the spool very close sit down a working channel mouth, because each one out the area of overlap with the control channel mouth in Depression shifted towards the mouth of the working channel neither with the control channel mouth nor with the in Longitudinal direction next following depression is connected. This means that the bridging channel in the Piston spool close to an adjacent working channel is set because of the bypass channel only some neighboring ones, but not all of them are active for the control function and the inactive depressions pose no risk of a wrong one Represent flow connection. This saves overall length. A gain in length is also for the opposite Direction of movement of the spool reached, in which e.g. B., the bridging channel with one or more just inactive wells with the return overlaps. The spool is despite the Control function for the control pressure medium in Longitudinal direction very compact. The control function for that Control pressure medium is perfect too  realize because the outlines of the recesses are in each other Overlap lengthwise so that one is active Deepening their flow connection only when the next deepening the Flow connection has opened sufficiently. Each The depression is only so large in the longitudinal direction that it is the passes the required amount of control pressure medium, and not bigger. The predetermined length Axial section and the stroke of the spool, over that the control function must be maintained, are encroached upon by a corresponding number of depressions, only a few of which are always active or those Activated and deactivated as a series or in groups become. It has the bridging channel Active lengths, which are the stroke of the spool in about corresponds via which the control function is needed. The distance of the control channel mouths from the neighboring one Working channel shortens compared to the distance conventional directional spool valves with a control function for the control pressure medium by approx. 30-45%. It connects the Bridging channel over the two control channel mouths the length of the predetermined axial section of the Slide piston during its displacement movement, whereby only some wells are active while others are can safely overlap with other channels. At a directional spool, the spool of which consists of a Neutral position in opposite directions in two Control positions is adjustable, being for each Direction of a control function is provided the length reduction achieved four times and therefore particularly clear.

In the embodiment according to claim 2, each recess able to because of the size of their outline to connect the control channel mouths alone.  

In the embodiment according to claim 3, which in such directional slide valve usual sealing cover has, it is ensured that despite the shortened Construction the sealing cover is observed.

The embodiments according to FIGS Claims 4 and 5. Alternatively, it is also possible according to claim 6 additionally save overall length by for example, the beginning and end Depressions within the axial section of the Sliding piston formed with a smaller diameter become.

The manufacturing technology is also favorable Embodiment according to claim 7. It is also conceivable, the wells within the Distribute the axial section of the spool so that two each overlapping in the longitudinal direction Wells absolutely arranged with spacing are much larger than the sealing cover are.

So there is no gap between adjacent wells Pressure fluid exchange takes place when one of them is on another channel mouth is aligned, it is according to Claim 8 advantageous if the absolute distance of the outlines at least adjacent depressions corresponds to the axial sealing overlap.

Based on the drawing, embodiments of the Subject of the invention explained. Show it:

Fig. 1 is a block diagram of a spool valve of a hydraulic control,

Fig. 2 is a partial section through the directional spool of Fig. 1, in the upper half in a working position a at the start of a control function, in the lower half, however, after the end of the control function in a 0 position, and

Fig. 2a shows a detail to FIG. 2.

In a hydraulic control H according to FIG. 1, a directional spool W serves, for example, for load-independent speed control of a hydraulic consumer, not shown, which can be acted upon on both sides. The directional spool W slidably contains a slide piston K in a housing bore 1 , which is adjusted by an indicated actuator 2 . Two working lines A, B are connected to one side of the housing bore 1 , the working channel mouth of the working line B in the housing bore 1 being highlighted by 10 . On the other side of the housing bore 1 , a pump line P with a working channel mouth 9 and a return line R are connected. Furthermore, a control channel system with control channel orifices 3 , 4 , 5 , 6 is arranged in the housing bore 1 in such a way that bridging channels C in the slide piston K are run over during its displacement movement. The slide piston K can be displaced from a zero position 0 into a control position b and into a control position a. For the control position a, the bridging channel C connects the control channel orifices 5 and 6 to one another when a working channel 8 of the slide piston K connects the working channel orifices 10 and 9 to one another. For the control position a, the other bridging channel C serves to connect the control channel openings 3 , 4 . The control channel orifices 5 , 6 are connected to two control channels 12 , 13 , which are then connected in a pressure-transmitting manner via the transmission channel C when the spool K is moved from the 0 position to the control position a. The structural requirements for this control function are explained below with reference to FIGS. 2 and 2a.

In Fig. 2, upper half, the spool K is at the end of the control position a. The working channel 8 in the spool K connects the working channel openings 9 and 10 and thus the pump line P to the working line A. The control channel openings 5 , 6 , which are formed by circumferential grooves at least over part of the inner circumference of the housing bore 1 , are via the bridging channel C connected. The width of the working channel 8 and the working channel mouths 9 and 10 is indicated with y '. The stroke of the slide piston K between the zero position 0 (lower half of Fig. 2) and the control position a is indicated with s'. It is larger than y ′ by a dimension Ü, the so-called sealing cover. The bridging channel C is limited in length to an axial section y (or to an axial section s), where y (or s) correspond approximately to y 'and s'. Corresponds to y approximately y ', then the bridging channel C connects the control channel orifices 5 and 6 via the stroke of the slide piston, via which the working channel 8 establishes a flow connection between the working channel orifices 9 , 10 . Corresponds to the length of the axial section s approximately s', then the control channel mouths 5 , 6 are connected to each other until the working channel 8 has reached the 0 position. The length of the axial section (s, y) over which the bridging channel C extends is matched to the operating conditions, that is to say to the stroke of the slide piston K, via which the control channels 12 , 13 must be connected to one another.

The bridging channel C consists of several individual recesses 14 in the circumference of the slide piston spaced apart in the piston slide circumference, z. B. blind holes. The absolute distance between adjacent depressions 14 corresponds approximately to the sealing overlap Ü. In the longitudinal direction of the slide piston K, the outlines of adjacent recesses 14 overlap to such an extent that (see FIG. 2a) a next recess 14 opens its flow connection between the control channel openings 5 , 6 before the previous recess 14 interrupts its flow connection.

In Fig. 2a, the dashed depressions 14 are folded to clarify the outline overlaps in the sectional plane of the left recess shown in solid lines.

The axial distance between the working channel mouth 9 and the closest control channel mouth 6 is expediently d + Ü ( FIG. 2). With an average directional spool size, this distance can be approximately 4.5 to 6.0 mm, whereas previously this distance had to be between 8 and 10.5 mm. If necessary, the control channel mouth 6 can be moved even closer to the working channel mouths 9 , 10 .

The depressions 14 are optionally distributed over the axial section s or y (as indicated by 14 'in the lower half of Fig. 2), so that between the contours of two axially successive depressions 14 ' as large as possible and the mutual sealing between these depressions ensures absolute Distances exist while they overlap lengthways.

In terms of production technology, it is expedient to arrange the depressions 14 along an imaginary thread line in the circumference of the slide piston K. Within the axial section s or y distributed over the circumference of the slide piston several similarly acting groups then even smaller recesses 14 or 14 'may be provided. The diameter or the outline d of each recess 14 , 14 'is at least as large as the longitudinal distance x between the control channel openings 5 , 6 , preferably as large as x plus the axial widths w of the control channel openings 5 , 6 . The bridging channel C could also be assigned more than two control channel openings.

In the lower half of FIG. 2, the working channel 8 is separated from the working channel mouths 9 , 10 . The bridging channel C has moved out of the axial region of the control channel openings 5 , 6 . The control channel mouths 5 , 6 are z. B. separated from each other at the moment when the outline of the rearmost recess 14 , 14 'passes over the edge of the control channel mouth 5 . The length of the axial section s or y is expediently chosen such that the control function begins as soon as the working channel 8 comes into contact with the working channel mouths 9 , 10 and ends as soon as this connection is broken. However, it is also possible to initiate or terminate the control function in advance or lag.

The control function indicated in FIG. 1 for the control position b between the control channel openings 3 , 4 and the bridging channel C functions in the same way. The outlines of the recesses 14 , 14 'do not have to be circular. It can e.g. B. depending on the machining process in the manufacture of the slide piston K, any outline shape can be selected. Recesses on one circumferential side of the slide piston K can be connected to an inner channel of the slide piston and / or through bores with depressions on the other circumferential side.

Claims (8)

1. Directional spool (W) for hydraulic controls (H), with a slide piston (K) which can be displaced in a housing bore ( 1 ), with at least one working channel (P, A) opening into the housing bore ( 1 ) and with at least one in the slide piston (K ) provided on a length-predetermined axial section (s, y) of the spool (K) bridging channel (C) for control pressure medium guided in at least two separate control channels ( 12, 13 ), characterized in that several of each other as the bridging channel (C) recesses ( 14 , 14 ') which are spaced apart from the circumference of the spool are provided in the spool (K), the contours of which overlap one another in the longitudinal direction of the spool (K), but are spaced transversely to the longitudinal direction in such a way that the lengthwise outline (d) of each recess ( 14 , 14 ') is smaller than the length of the predetermined axial section (s, y) of the slide piston (K), and that for the tax channels ( 12, 13 ) in the housing bore ( 1 ) at least two axially adjacent control channel openings ( 3, 4; 5, 6 ) are provided. 2. Directional spool valve according to claim 1, characterized in that the outline (d) of each recess ( 14, 14 ' ) larger than the distance (x) between the control channel mouths ( 3, 4; 5, 6 ), preferably approximately equal to the distance (x) plus the axial width (w) of the control channel mouths ( 3, 4; 5, 6 ) and that the recesses ( 14 , 14 ') overlap so far that over the recesses and over one of the lengths (s, y ) of the predetermined axial section in approximately corresponding stroke (s') of the slide piston (K) between the control channel openings ( 3, 4; 5, 6 ) a bridging connection of approximately constant size can be produced. 3. Directional spool valve according to claim 1, wherein working channel openings in the housing bore and working channels in the slide piston are spaced apart in predetermined control positions of the slide piston with an axial sealing cover, characterized in that the axial distance between the working channel opening ( 9 , 10 ) and the adjacent control channel opening ( 6 ) corresponds approximately to the length of the axial sealing cover (Ü) plus the outline width (d) of a depression ( 14 , 14 '). 4. Directional spool valve according to one of claims 1 to 3, characterized in that the recesses ( 14 , 14 ') are blind holes. 5. Directional spool valve according to one of claims 1 to 4, characterized in that the depressions ( 14 , 14 ') have the same outline widths (d) or diameter. 6. Directional spool valve according to one of claims 1 to 4, characterized in that the recesses ( 14 , 14 ') have different outline widths (d) or diameter, preferably such that the outline width or the diameter of a working channel (A, P ) closest and most distant recesses ( 14 , 14 ') is smaller than the outline widths or diameter of intermediate recesses ( 14 , 14 '). 7. Directional spool valve according to one of claims 1 to 6, characterized in that the recesses ( 14, 14 ' ) are distributed along an imaginary thread-like line of the circumference of the slide piston (K). 8. Directional spool valve according to claim 1, characterized in that the absolute distance between the contours of two adjacent depressions ( 14 , 14 ') in the spool piston circumference corresponds at least to the axial sealing cover (Ü).