DE865694C - Hydraulic power transmission device - Google Patents

Description

Hydraulic power transmission device The invention relates to a hydraulic force transmission device, which consists of a pump on the one hand and a Working body on the other hand exists.

It is well known that every pump tends to operate with the help of a rotating shaft is driven to rotate around the axis of this shaft when: the outlet for the liquid is blocked and a hydraulic lock inlet. purpose of the invention is, in the case of hydraulic power transmission, this process in the manner take advantage of the fact that the direction of flow of the moving liquid changes automatically @reversed when such a hydraulic lock @ occurs. The invention now has Legs hydraulic power transmission device to the subject, the working organs, like hydraulic cylinders, diaphragm pumps or the like. ; contains a periodic reversal the direction of flow of the liquid, the reversal being automatic he follows. For this purpose a pump is provided, the links of which are uninterrupted are driven by a rotating drive member or a drive shaft. Here the pump elements are in linen, rotor o: d. @dgl. housed ,. the one with Interruptions around the axis of this drive member can rotate. Through a Pressure increase in the moving fluid becomes the rotation of the rotor automatically iajuf reason brought about by a hydraulic lock, whereby that The direction of flow of the liquid movement is reversed.

adorn the Punnpe containing rotor is through in its working position. releasable coupling links held ltnd Ans.cliläge, and the switching operation is triggered by: amf pressure responsive means when the hydraulic lock entry. ornamental, intermittently rotating rotor is in your stationary Housing stored, which is provided with inlet and outlet openings, which in turn anit rator bores for; see axial or radial flow in connection.

The pump housed in the rotor is preferably a gear pump. However, any other pump can also be used.

In the drawings are some embodiments of the invention shown.

Fig. I is a longitudinal section through legs flat or invention-designed "for axial flow arranged force transmitting device; Fig. 2 is a cross-section on 2-2 of Fig. I; Fig. 3 is a cross-section on 3-3 of Fig. 1; 4 is a section along 4-4 of FIG. 2; FIG. 5 is a section along 5-5 of FIG Force transmission device according to the invention; Fig.7 is its schematic representation on an enlarged scale, which shows the connection of the `gate direction to the blocking or control valve; Fig.8 is a section through the Sfieuervenitgj Fig. 9 is a longitudinal section through a diaphragm pump which eats connected to a pure power transmission device; 3 Fig. 10 is a longitudinal section according to io-io of Fig. 9; Fig. ii is a longitudinal section of Fig. 9; Fig. 12 is a longitudinal section of the other embodiment Power transmission device tung; Figure 13 is a cross section taken through the housing hollows; Figures 14 and 15 are cross-sections showing the location of certain fluid passages associated with the locking pin of the rotor; 16 and 17 are illustrations of certain modifications of the Kraftübiertragungsvorrichtung, the Üazu isolllen, z. B. a Reibre of Rannmböcken in ie, a predetermined cycle. to control; FIGS. 18, 19 and 20, respectively, show various modifications which are necessary when: the device is used; For example, to defeat two rammers, put them in the working position engages the casing and with 6 - attached eats. The cap 5 has a recess 7 in the middle for a bearing bush 8 which receives the rear end of the corrugation 4. On its inside, the cap 5 has two bores 9 and io, which are opposite one another at the same distance from the shaft. The holes 9 and io continue in threaded holes 9a and ioa, which are used to connect suitable pipelines.

In the chamber i i there is a rotor body 12, which is the housing a tooth nose # dpumge forms. ornamental rotor 12 eats freely mounted on the axis ¢; ier has its sleeve 13 and has a cylindrical cross-section with ample clearance opposite the inner wall of the chamber i i. On the back, the rotor 12 is through Screws 15 attached cap 14 provided. The outside of the cap 14 rests against the inner surface of the cap 5 to the housing. The rotor cap 14 has one another opposite holes 16 and 17, which mixes the holes 9 and io the Housing cap 5 match. At 21, the rotor 12 is recessed to receive the Gears 18 and i 9 of a gear pump; gear 1 $ is keyed on shaft 4 or, otherwise attached; that other gear i @ 9 sits loosely on one Pin 20.

Channels z2 and 23 close to the recess 21 on both sides, which establish the connection to the bores 16 and 17 and thereby to the bores 9 and io. The channels 22 and 23 together with the recess 21 form the suction and pressure chamber of the gear pump. The pressure chamber 23 is in communication with the rear face of the rotor through an opening 24; so that the rotor is pressed against the housing cap 5 by the pressure of the liquid.

Opposite recesses are provided in the rotor body 12 25, 26 are provided, in which locking pins 27, 28 are slidably: mounted; these Pins are under stretched pressure from coil springs 29 and: are arranged so that you through your service. Fluid pressure pushed inward when. the pressure high becomes enough to overcome the force of the springs.

The locking pins 27, 28 are arranged so that they finitely two stop pieces 30, 31 come into engagement on the inner end wall of the fixed housing i, whereby the rotor 12 is held until the locking pins by the rise of the Diruckes. be pushed back. The inner ends of the recesses 25, 26 are through a pressure compensation groove 32 in the rotor body 12 with each other and with, the Channel 22 connected and are closed by the rotor cap.

The shaft 4 is provided with its pulley 33.

When the power transmission device to the device to be driven by lines to the connections 9a and ioa; connected with a suitable Liquid, e.g. B. Oil, is filled and is in action, so will be Rotation of the shaft 4 set the gear pump in motion, around Oil from the suction side 22 and .dem channel 9 to the pressure side 23 and the channel io lead, which drives the apparatus. When the pressure; on the outlet side as a result of a hydraulic lock in the line between the gears 18, i 9 and the implement or the control valve increases, the Sp: errstift: e 27, 28 against the force of the springs 29 inwardly from the stops 30, 31 pushed away. The rotor 12 can now rotate freely when the gearbox is fixed, as a result of which the outlet channel 123 and the inlet channel 22 via the rotor bores 17 i and 16 be brought with the Bohrungeng or io iil connection, so that on this Way the outlet openings are interchanged. In this way: the Pressure on the outlet side of the pump is decreased, and the sp-errs, pins 27 and 28 will be pushed back by the springs 29 so that they engage with the stops 30, 31 come. Such a partial rotation: of the rotor and interchanging the bores occurs every time a hydraulic lock occurs, @d. H. during each cycle, which the apparatus executes.

To reduce the friction between the rotor cap 14 and the housing cap 5 to reduce, one can adjoin the bores 9, io, 16 and 17 surfaces der: make one or both caps slightly conical to create a wedge-shaped one To create a gap that is filled by the liquid flowing in under high pressure will.

If you work with very high pressures, it can hit the rotor 12 pressure exerted on the side can be reduced by reducing the cross-section of the Housing bores matched to those of the drive shaft and a device attaches, at which the pressure generated by the pump, to the end of the drive shaft can counteract the thrust. That way you can get the side thrust on decrease any desired degree.

The following is an application of the power transmission device, like in Feg. 6 to 8 is shown, in a mixer for concrete od., Like. described with its pivoting hopper.

The mixer designed in a known manner for concrete or the like. has its mixing drum 40, which is mounted on a movable frame 41 Rotates transverse axis. The comminuted mass is conveyed by means of a filling container 42 entered into the drum 4o; the container 42 is on one in the chassis 41 attached swing shaft 43 articulated. The shaft 43 has its lever arm 44, which coupled with the Kolhe @ n rod of a hydraulic cylinder 45 pivotably mounted at 46 is.

The power transmission device 47 designed according to the invention is mounted on a bracket 48, with the drive shaft of the pump through a over the pulley 5o running drive belt 49 is driven; the disc 5o sits on the shaft: of the gearbox, which: moves the drum 4o. It can The drive shaft of the pump can also be set in rotation in other ways.

At bores 5 i, 52 in the housing 47 are pipes 53, 54 connected, which to the hydraulic cylinder 45 or to a bore 55 of the housing 56 of a control valve 57 lead.

The valve housing 56 has two further bores 58, 59, which are open towards chamber 6o. The bore 58 eats through a pipe 61 with your Reservoir 62 connected, which is used to supply oil. The hole 59 is through a pipe 63 with the line 53 in connection. Dias valve 64 of the line 63 is a non-return valve that only circulates the liquid from right to left in Fig. 7 lets through.

The valve 57 is preferably a so-called throttle valve; It is operated by hand by means of a button 65 which is seated on a rod 66 connected to the valve stem 67. The valve 57 is held in the open position by the spring 68 (FIG. 8I. During this valve position, the bores 55, 58 and 59 are connected to one another through the chamber 6o and the oil flows through the gear pump in an open circuit 8, the hydraulic closure is brought about and the loading container, coupled via the hydraulic cylinder 53, is raised.

The loading container can be lowered at any time during the upward movement by a corresponding valve connected upstream of the control valve 17 in the pipeline.

According to a further embodiment of the invention designed power transmission device, this is used to drive a Membranpump.e used (Fig. i o and i i).

The pump housing consists of two parts 70, 74 between which a membrane 72 is arranged. The housing parts are also through transverse walls 73, 74 divided, whereby on one side of the membrane pump chambers 75, 76 'and on the other side of the membrane chambers 77, 78 arise. .

The chambers 75, 76 are through bores 79, 8o, which through valves 8 i, 82 are controlled, connected to the suction chamber 83. Chamber 83 is with a threaded connector 84 controlled by the valve 85, which the chamber connects to its pipeline for the liquid to be pumped.

Through channels 86, 86t, which are controlled by valves 87, 88, the chambers 75, 76 are also connected to the pressure chamber 89.

Below the pump: the chambers 77, 78 open into the valve chambers 9o, 9i, which for their part are connected to the bores of the power transmission device 92 through pipes 93, 94. The valve chamber 9o is connected to the chamber 77 through a bore 95, while a similar bore 96 connects the chamber 78 to the valve chamber 91. The bores 95, 96 are with seats for the valve body 97; 98 provided; which in turn are attached to the membranes 72a, 72b .

If the device is in operation, the liquid is in one of the chambers, e.g. B. 77 (Fig. 1o), conveyed and by the action of the gear pump of the device out of the chamber 78 .: sucked. As a result, the membrane 72a is stretched and the membrane 72b is relaxed, so that the liquid is conveyed from the pump chamber 75 into the pump chamber 76.

When the voltage limit of the membrane 72a eating reached, then -the valve closes 97. The liquid supply is blocked by the valve 97; This takes place at a hydraulic closure "and the fluid pressure rises. As a result, the rotor or device is free and rotates through 180 °; whereby the position of the suction and pressure bores of the rotor is reversed. The pump chamber 75 turns around to the suction chamber, The pump channel 76 to the pressure chamber until! valve 98 closes and! a hydraulic block with further reversal of the passages. This process continues - automatically, as long as # the pump is active.

In the embodiment of the invention shown in Figs is the housing 99 with radial bores arranged opposite one another i oo, i o i provided with screw threads for connecting pipes are. The rotor io2 has an inlet channel 103 and an outlet channel 1o [which make the connection with the pump chamber io5 and extend to the cylindrical Outer surface of the rotor extend to with the bores ioo; cooperate red. The rotor io2 is fitted into the chamber of the housing 99.

The rotor io2 is provided with its only locking drift i o6, which comes into engagement with opposing stops that are in a annular recess 107 are provided in the housing cap, iö8.

As a result of the different pressure on the periphery and on the End faces of the rotor io2, which is located at; , this embodiment of the invention resulting from the need for smaller gaps, is in the inner surface of the Rotor cap i i o; a channel i o9 provided, which the four-bond mi, t of the annular Contact surface i i i of the locking pin .produces and the pressure fluid from the Bore 104 leads out.

Liquid residues over the locking pin io6, d. H. in the hole z 12 verbli, eb, en .sind are guided through the bores 113 to the suction line 103.

D0.e Working method of the device! And the automatic reversal of the rotor are similar to those described in the first embodiment of the invention will.

In -the in Figures 16 and 17 gezeigten.A; usführungsform, of the invention. Are two pairs of suction and pressure lines 1 14 and i 15 are disposed (Fig. 17), which face one another in pairs. Accordingly, two pairs of stop pieces i 16 and 117 are provided for the locking pins.

With this arrangement, the Kiaftüberra.gungsvorri: rhtung two hydraulic rams are used in a specific order to operate. Of course, other pairs of holes can be used. -and stop pieces be attached, which then allow the control of additional battering rams.

Slurry of a further embodiment of the invention (Fig. 18 to 20), with which z. B. two battering rams operated, held in place and then withdrawn at the same time can be, there is in the housing an oval bore 120; which one Outlet bore 121 diametrically opposite. A second outlet bore 122 is open the same circular arc, opposite to the expansion of the rotor, arranged. Farther -are locking pin stops 124, 125 for the bores 121, 122, and a stop 126 provided for the bore 12o.

There is a single outlet in the rotor. bore 127; the Inlet 128 is extended by groove 129 which extends evenly to both Directions. D0.e full length core slot 129 is twice as large like the arc between the bores 121, 122.

In this device, the liquid from the bore i 2o in flow through the elongated bore 128, 129, and through the plump the Biohrung 127 exit again. In the case of a hydraulic lock, a Partial rotation, of the rotor, instead of where; du rch, bore 127 with bore 122 in Communicated while, the elongated bore 128, 129 with the bore 120 stays in touch.

When the hydraulic lock has been reached, it completes Rotor rotates i8o °; so that the elongated bore 129 with the two Bores 121 and 122 is connected and the liquid through this; both holes outflow: can to flow through the gear pump into the bore i 2o; through this both battering rams are withdrawn at the same time.

Claims (1)

PATENT CLAIMS: i. Hydraulic power transmission device; which working organs, such as hydraulic cylinders, diaphragm pumps @od: the like. Contains the leine periodic reversal of the direction of flow of the liquid, characterized in that a plump is provided to generate the liquid movement, whose. Members are continuously all-driven by its rotating drive member ior its drive shaft and in which the pump members in its rotor @odAgl. are provided, which rides interruptions around the axis of this drive member; can rotate, the rotation of the rotor being triggered automatically by an increase in pressure in the fluid being moved due to a hydraulic closure of the pump members, so that the direction of the fluid; movement reverses. a. Device according to claim i, characterized in that the rotor containing the pump is held in its working position by releasable coupling members and stops and the switching operation is triggered by pressure-responsive means when this hydraulic lock enters. 3. Apparatus according to claim i and a, characterized in that: the intermittently rotating rotor is mounted in a stationary housing which has measuring and discharge openings for the liquid; which in turn with rotor bores for axial: or radial. Flow in connection. 4. Apparatus according to claim i to 3, characterized in that the pump housed in: the rotor is a gear pump. 5. Apparatus according to claim i to 4, characterized in that: that the Eznl; aß- and outflow opening of the fixed housing with: a hydraulic cylinder: the (45) and a storage container (6z) are in connection, wherein, a control valve (56 ) in the line leading to the storage tank for arbitrary generation, a hydraulic lock is provided in this line and a connecting line (63) with its check valve (64) is located between the line (53) to the hydraulic cylinder and the storage tank or control valve. 6. Apparatus according to claim i to 5, characterized in that d: when using diaphragm pumps, each diaphragm is connected to a valve (97, 98) which, towards the end of the stroke movement, extends the space in front of: the diaphragm (77, 78) of the Inflow line (9o, 9i) closes. 7. Apparatus according to claim i to 5, characterized in that for the alternating actuation of two or more hydraulic cylinders in a predetermined sequence of the rotor housing, two or more sets of inlet and outlet openings (114, 115) with corresponding locking pins and stops (i 16, 11 7) work together.