DE2308872A1 - CHANGEOVER SLIDER - Google Patents

Description

Reversing slide The invention relates to a reversing slide.

A known magnetic piston valve arrangement is provided with switches, by actuating the electromagnets are switched on and off, so that they cause the slide piston to move into one or more working positions can or the slide piston located in a working position is released so that it is returned to a neutral or rest position by spring force will. In this known arrangement, the electromagnets are called lifting magnets used that can move the piston valve over a considerable distance, so that this is effectively power operated. On the other hand, closing one allows Switch no manual control of the spool, so this when closing of a switch immediately from the neutral position to the assigned working position is moved and the operator neither the flow of the pressure medium to the device fed with it throttle the spool in an intermediate position can stop.

The invention creates a reversing valve with a housing that an inlet opening for connection to a pressure medium pressure source, a return flow opening for connection to a pressure medium container and a piston drive opening for connection to a piston drive, furthermore with a slide piston, which is in the housing by hand to control the pressurization of the piston drive from a neutral one Position in which the flow connection between the inlet opening and the piston drive opening is locked, is movable in working positions in which the Kolbentrieböffnuné aiahlweise with the inlet or return flow opening in connection, as well as with a peder assembly that moves the piston into the neutral position seeks, and an electromagnetic locking device, which is excited State holds the spool in one of its working positions and one on that Housing fastened body an arranged in the body, with the slide piston has coaxial solenoid and a magnetizable member, which with one end of the spool and can move with it until it's fed up one land of the solenoid is applied and held by this until it is either by turning off the solenoid or by applying manual force to the The slide piston is released, whereupon the spring assembly moves the slide piston into the neutral position.

Embodiments of the invention are described below with reference to FIG attached drawing. In this, Fig. 1 shows in view one with two Reversing spool provided with spool.

Fig. 2 and) show on a larger scale in cross section along the Line 2-2 and 3-3 in Fig. 1 each have an electromagnetic locking device.

The one in sig. 1 shown reversing slide 1 has a housing 2, in which two slide pistons 3 and 4 can be moved back and forth, the z.3. for controlling the piston drives 5 and 6 are used for the A @ sleger or the shovel of a front loader. The housing 2 has an entry opening 7, which is connected to the pump P, a tick flow opening 9 connected to the container 10 and two pairs of Piston drive openings 11 and 12 which are connected to the piston drives 5 and 6, respectively.

The spool 3 is a four-way spool that has a relief position can take. When used to control the boom piston drive 5 the spool 3 has a neutral position N, on one side of the neutral Position N a lifting position R and on the other side of the neutral position no N a lowering position L and a relief position. The spool 4 is a Four-way slide valve. nei its use to control the paddle-piston drive 6, the spool 4 has a neutral position N, on one side of the neutral position 1 a dump position KIPP and on the other side the neutral Position a Rückkippschtstellung BACK. Exemplary embodiments of such reversing piston valves are in U.S. Patents 3,195,559, 3,251,277, 3,000,397, 3,132,668, 3,160 174, 3,262,467, and 3,299,903.

The one shown in Fig. 2, the four-way slide piston 3 with relief position associated electromagnetic locking and return spring assembly 13 has a housing 15, which is connected to the housing 2 is screwed that Circlips 16 and 17 used for guiding and sealing a slide piston are clamped. A rod 18 is screwed into the end of the spool 3, which clamps a washer 19 against the end of the piston 3. On the Rod 18 is an annular disk 20 for a shoulder provided on rod 18 21 and can be moved away from this. With the help of a screw 23 and a sleeve 24 a nisenplatte 25 is attached to the end of the rod 1, which is on the sleeve 24 has a radial and axial play of 0.1-0.3 mm, for example, so that the plate 25 is self-adjusting.

In the area of a locking ring disk arranged in the housing 15 26, a first electromagnet 27 is arranged, on which in its excited state the iron plate 25 is held when the spool 3 by hand to the right has been moved to the raised position R.

A second electromagnet 28 is supported by a spacer sleeve 29 held at the axial distance from the electromagnet 27, on which in its excited state the iron plate 25 is held when the spool 3 to the left in the Relief position F has been moved. Electrical lines not shown lead from the two electromagnets 27 and 28 to the left and through a radial one Opening in a retaining member 30 and through openings in a sealing ring washer 31. The holding member 30 is held in place by a snap ring 32 and is against a Rotation determined by a clamping screw 34, which is in a selected one of the in the housing 15 provided holes 35 extends.

If you push the holding member 30 into the housing 15, then it can be rotated so that the leads are stretched taut. Then you can Fix the holding member by inserting the screw 34. Between the ring 17 and the Ring washer 26 are two of each other opposite spring stop and guide sleeves 40 and 41 are provided, between their outer flanges a main compression spring 42 is clamped. The sleeve 41 has an inner flange that holds the washer 20 overlaps radially. Between an inner flange of the sleeve 40 and the washer 2G another compression spring 43 is clamped.

When the spool 3 moves into the lifting position R, the two springs 42 and 43 are compressed more strongly. When the spool moves 3 in the benkstellung L only the main spring 42 is compressed more. at an attempt to move the spool 3 beyond the lowering position L also the relaxation position E, the attack causes aer iing disc 20 on the electromagnet 27 a considerable increase in resistance to continued movement of the spool 3 to the left, because both fibers 42 and 43 are more strongly compressed and oppose this movement with a stronger resistance. At the increasing Spring force of the spring 4, the operator can therefore recognize that the slide piston 3 is in the lowered position L.

When the spool 3 is moved into a position in which the iron plate 25 engages the Zlektromagneten 28, hit this if it is excited is, the spool 3 in its relief position F fixed, either until the solenoid 28 is turned off or until the operator clicks on the Slide piston 3 exerts a manual force, which together with the restoring force of the two springs 42 and 43 overcomes the holding force of the magnet. Once the plate 25 moved away from the electromagnet 28 by manual force or the electromagnet 28 has been switched off, the two springs 42 and 43 make the slide piston 3 in the lowered position L return. LancY sets the spring 42 to the spool 3 back from the lowered position L to the neutral position ii.

When using the Federanordnuné shown in Fig. 2 aie Spring forces in the lifting position R and the relief position F are approximately the same while the spring force in the zenkstellune X experiences a considerable inderunc, at which the sedation person recognizes that the upper piston 3 is in the lowered position L has been occupied. For example, the main spring 42 can be in the neutral position N have a spring force of 14 kp, which increases to 17 kp when the spool 3 is moved from the neutral position N to the lifting position R. As with a movement of the slide piston 3 from the neutral position N into the lifting position R also the Spring 43 is compressed more strongly, this spring can initially be a spring force of 7 kp, which increases to 9 kp up to the lifting position R. When there is a shift of the spool 3 from the neutral position N to the lifting position R therefore takes the spring force of both springs 42 and 43 from 21 kp to 26 kp. When moving of the spool 3 from the neutral position N to the lowering position L only takes the spring force of the main spring 42 from 14 kp to 17 kp. Since in the lowered position L the spring 43 has a spring force of 7 kp, the operator recognizes the Attempt to move the spool 3 beyond the lowering position @ that in this Position the spring force suddenly increases to 24 kp, which is the sum of the spring force the main spring 42 of 17 kp and the spring force of the spring 43 of 7 kp corresponds. When moving the spool from the lowering position L into the relaxed position F, the main spring 42 is compressed more strongly, so that its spring force of 17 kp increases to 19 kp. At the same time, the spring force of the spring 43 takes up 7 kp 9 kp, so that in the relief position F the total spring force 28 kp. Therefore, when the electromagnets 27 and 28 have a holding force of 54 kp a force of about 27 kp (26-28 kp) must be exerted on the piston valve 3 so that the iron plate 25 is withdrawn from the electromagnet 27 or 28.

In general, the spool 3 is operated by a lever, which has a gear ratio of e.g.

6: 1, so that the operator has to press the lever to operate the Slide piston needs to exert a pulling or pushing force of only about 4.5 kp, to overcome the resulting magnetic holding force. After the magnetic Holding force has been overcome, the springs 42 and 43 adjust the spool 3 further back to the neutral position N without the operator having to do another Need to exercise strength.

The electromagnetic locking device shown in FIG 14 is similar to that according to Fig. 2, but the four-way slide piston 4 has only two working positions, which are each on one side of the neutral position I, so that a common return spring 50 can be used between two spring stop and guide sleeves 51 and 52 is clamped and therefore in the neutral position a bias and in each of the working positions of tipping (KIPP) and tipping back (BACK) a desired one Has spring force. If an electromagnetic lock is only in one working position de spool is desired, an electromagnet can be omitted and through replace a support body 53. Also in the locking device 13 for the four-way slide piston 3 with relief position can one of the electromagnets 27 and 28 by a such support body 53 are replaced. So with the description of the locking device 14 repetitions that can be avoided are shown in Fig. 3 for similar parts the same Reference numbers used as in @ ig. 2.

As a result of the coarse fit of the plate 25 on the sleeve 24, the Set plate 25 yourself or

tilt in all directions so that they are on the flat face of the Electromagnet 27 or 28 is also aann full when this end face to the The axis of the spool 3 or 4 is not right-angled.

Claims (7)

Patent claims: 1. Reversing valve with a housing that has an entry opening for connection to a fluid pressure source, a return flow port for connection to a pressure medium tank and a piston drive opening for connection to a piston drive has, further with a slide piston, which is in the housing from nand to the control the pressurization of the piston drive from a neutral position in which the Flow connection between the inlet opening and the piston drive opening blocked is, can be moved into working positions in which the piston drive opening can be selected with the inlet or return flow opening in connection, gekenr; characterized by a spring arrangement (42, 43) which the slide piston (3, 4) in the neutral position seeks to move, and by means of an electromagnetic locking device, which holds the spool in one of its working positions when excited and a body (15) fastened to the housing (L), one arranged in the body, with the spool (3, 4) coaxial solenoid (27, 28) and one that can be magnetized Member (25) which is connected to one end of the spool and can move with it until it rests on one end of the magnet coil and is held by this until it is either turned off by switching off the solenoid or released by exerting a manual force on the spool, whereupon the spring arrangement returns the valve piston to the neutral position. 2. Reversing valve with a housing that has an inlet opening for connection to a pressure medium pressure source, a return flow opening for connection to a pressure medium tank and two piston drive openings for connection at has a double-acting piston drive, furthermore with a slide piston which in the housing by hand to control the pressurization of the piston drive from a neutral position, in which the flow connection between the zin inlet opening and the piston drive port is blocked, a first and a. second working position is movable, in each of which one of the piston drive openings with the inlet opening and the respective other piston drive opening in connection with the return flow opening stands, the spool being a relief position beyond the second working position possesses, in which the piston drive openings iteinanaer and with the return flow opening in connection, characterized by a spring arrangement (41, 42) which seeks to move the spool (3, 4) into the neutral position, and through an electromagnetic locking device, which in the energized state the slide piston stops in the first working position or the relief position and some of them stop the body (15) fixed to the housing (2), two in the body at an axial distance from one another arranged magnetic coils (27, 28) and one arranged between the magnetic coils, has a magnetizable member (25) that connects to one mouth of the spool is connected and can move with it until it gets tired of one of the ends Magnet coils is applied and is held by this until it is either switched off the solenoid or by applying manual force to the spool is released, whereupon the spring arrangement moves the spool into the neutral position resets, the spring arrangement of the movement of the spool in the relief position from the second working position onwards there is a significantly stronger resistance and thereby indicates that the spool is moving from the neutral Position aie has reached the second working position. 3. reversing slide according to claim 2, characterized in that the spring arrangement has at least two prestressed compression springs (41, 42) that each of the springs during the movement of the spool (3, 4) from the neutral In the first working position, one of the springs is compressed more strongly both during the movement of the spool from the neutral position to the second working position as well as during the movement of the spool out of the second working position is more strongly compressed into the relief position and the other spring only during the movement of the spool out of the second Working position is more compressed in the relief position, so that reaching the second working position can be seen from the resistance suddenly against the movement of the spool in the second working position increases. 4. reversing slide according to claim 3, characterized in that the spring types of the springs (41, 42) are chosen so that those exerted by them Restoring forces in the first working position and in the relief position ann.herna are the same. 5. reversing slide according to claim 4, characterized in that the magnetic coils (27, 28) on the magnetizable member (25) essentially the same Exercise strong magnetic holding forces, so as to snap off the magnetizable Link from the solenoid coils to the slide piston (3, 4) by hand approximately the same strong forces have to be exerted, whereupon the spool is actuated by spring force is returned to the neutral position. 6. reversing spool according to one of the preceding claims, characterized marked because the magnetizable member (25) can be tilted so that it feels full can apply to the end of the magnetic coil or the inden of the magnetic coils (27, 26). 7. reversing slide according to one of the preceding claims, characterized characterized in that the magnetizable member is an iron plate (25).