DE1198266B - Concrete mixer arranged on the frame of a transport vehicle - Google Patents

Description

Concrete mixer arranged on the frame of a transport vehicle The invention relates to one arranged on the frame of a transport vehicle Concrete mixer with a mixing drum rotatably mounted at both axial ends and an independent drive motor for the mixing drum.

In known devices of this type are the mixing drum and drive motor stored separately from each other on the chassis, and the power transmission takes place via a cardan shaft to a gearbox and from here via a complicated articulated connection on the mixing drum. In this known arrangement, all shocks that occur when Driving occur, transmitted to the shaft and the drive organs. This results in an uneven engagement of the interacting parts with a correspondingly increased Wear and tear.

The purpose of the invention is to provide a device of the type mentioned at the beginning Art to create in the twisting movements of the vehicle frame without influence on the transmission of the motor power to the mixing drum.

To solve this problem it is proposed that the drive motor and the mixing drum are arranged on a common shaft that the motor-side The end of the mixing drum is supported by the drive motor and that the drive motor with the motor housing by means of an articulated joint on the frame of the Transport vehicle is stored. This ensures that when driving through in rough terrain none of the inevitable twisting of the Transfer the vehicle frame to the drive connection between the engine and drum will. This is therefore of particular importance in devices of the present type, because the drum mixer while driving and thus during the occurrence of shocks and torsion is driven.

It is known to have a mixer drum and motor in the concrete mixers Way to connect with each other that a common support is sufficient for both. However, these known designs have a different purpose, namely to accommodate the drive motor so that it is encapsulated to protect against dust and stones can be.

According to a further advantageous proposal of the invention, it is provided that the engine is a hydraulic radial engine with a plane perpendicular to the shaft arranged cylinders is. Such a drive motor is characterized by a few moving parts, good control options and compact design.

Further features of the invention are the subject of claims 3 to 13. In the drawings, the invention is explained in more detail in an exemplary embodiment. It shows F i g. 1 a side view of a concrete mixer arranged on a vehicle, F i g. 2 is a front view of the drive motor for the mixer, seen in the direction of the arrows 2-2 in FIG. 1, FIG. 3 shows a vertical section through the motor in level 3-3 in FIG. 2, fig. 4 a partial section through the hydraulic motor, F i g. 5 shows a section through the valve control of the engine and FIG. 6 a scheme of the hydraulic drive devices.

According to FIG. 1 is in the rear part of a vehicle frame 2 of a truck 3 of a conventional type, a mixing drum 1 is rotatably arranged. The vehicle is used for both transporting and mixing concrete.

As can be seen in particular from FIGS. 1 to 3, a bridge part 23 is fastened between two end plates 24. The plates 24 run directly downwards on the outer sides of the frame 2. The plates 24 are attached to the frame 2 and take the weight of the drum l on. A triangular foot piece 26 is welded under the bridge part 23 and to the plate 24 lying next to it and rests on the frame 2 of the vehicle. This foot piece 26 serves to better distribute the load. The plates 24 are welded to the front end of the Z-shaped rods 16 in order to produce a connection between the front support 14 and a rear bearing 15 of the drum 1 in this way.

A support part 28 for: a two-part pan 29 is provided with a downwardly extending tab 30 which is welded to the top and the rear wall of the bridge part 23 in the middle between the plates 24. An upper holding part 31 is detachably connected to the lower support part 28 with the aid of the screws 32 which are arranged opposite one another and which pass through corresponding openings in the part 28 and are screwed tightly with holding part 31 in openings provided with threads. The support part 28 is provided with a hemispherical recess which is open to the rear and upwards in the direction of the mixing drum 1. In the hemispherical recess, a bearing ball 33 is arranged, which is movably supported by the holding part 31, which is provided with a correspondingly shaped recess. ; .

A pin 34 is formed on the bearing ball 33, which protrudes upwards and whose axis is perpendicular to the axis of the mixing drum 1. The pin 34 is fastened in a corresponding opening in the front support 14. In the vicinity of the bearing ball 33, a flange 35 is welded to the pin 34, which is screwed with the aid of the bolts 36 to the drive and support device, which in this way is movably supported with respect to the vehicle frame 2. The bearing ball 33 , in conjunction with the rollers 19, forms a three-point bearing for the mixing drum 1 and prevents the twisting of the vehicle frame from being transmitted to the front support 14. As a result, no stresses can occur in the front support 14.

In the illustrated embodiment, the front support 14 is designed as a multi-cylinder, hydraulic radial motor which forms the front rotary bearing of the mixing drum and the rotary drive of the drum.

The support 14 consists of an annular motor housing 37, with which the bearing ball 33 is rigidly connected via the flange 35 and the bolts 36 is. A front bearing plate 38 is attached to the housing 37 with the aid of the screws 39 removably attached, which covers the front opening of the housing. One continuous Closing and bearing plate 40 closes the side of the housing facing the drum 37.

A shaft 41 is in the center of the front bearing plate 38 and a bearing 42 or 43 arranged in the middle of the rear bearing plate 40 rotatably mounted. The front bearing 42 is a conventional double cylinder roller bearing, while the rear bearing 43 is a self-adjusting double cylindrical roller bearing is trained. Since the bearings are of conventional construction, there is no other one Description required.

The shaft 41 goes backwards through the bearing plate 40 and is aligned with the axis of the drum 1. The shaft 41 is firmly connected to the front end of the mixing drum 1 and forms the front bearing journal of the drum. As in particular from FIG. 3, a hub 44 is attached to the end wall 45 of the mixing drum 1. An annular plate 46 is welded to the inner surface of the wall 45 and the inner portions of the hub 44 so as to secure the hub to the drum. The hub 44 and the rearwardly protruding part of the shaft 41 are grooved at 47 so that a non-rotatable connection between the shaft 41 and the mixing drum 1 is created. Appropriate ring nuts 48 are screwed onto the appropriately threaded outermost end of the shaft 41 to connect the hub 44 to the extended end of the shaft 41. As a result, the rotary movement of the shaft 41 is transmitted to the mixing drum 1, so that the concrete in the mixing drum is mixed accordingly.

The shaft 41 is provided with a central longitudinal bore 49 which extends over the entire length of the shaft and with a not shown Water tank can be connected, which in turn in any suitable way Can be attached to the vehicle, the front support 14 or the like. With the one shown Embodiment of the invention are the opposite ends of the Bore 49 - closed by suitable caps 50 and 51, which are from the shaft 41 can be removed. A particularly suitable version of a water connection, which can be conveniently attached to the illustrated shaft 41 is already known.

The socket 29 for the joint is attached to the motor housing 37 via the pin 34 formed on the ball 33 at a point which is approximately offset forwards with respect to the main plane through the housing 37, so that the rear bearing 43 is essentially in the vertical direction above the ball 33 lies. The forces transmitted to the frame 2 via the pan 29, in particular when braking the vehicle, consist of a horizontal and a vertical component, which together produce a resultant that runs forward and downward at an angle. Since the movement of the socket 29 brings the ball 33 forward, as shown, the connecting line between the bearing 43 and the ball 33 moves closer to the resulting force and thereby improves the transmission of the horizontal and vertical forces to the frame 2.

As in particular the F i g. 3 and 4 show is with the shaft 41 a disk-shaped eccentric 52 made of one piece with the shaft. When the shaft 41 and thus the disc-shaped eccentric 52 rotate, the migrates true center of the disc on a circle around the axis of rotation. The eccentric 52 is on the outer circumference with a flange 53 protruding in the axial direction provided, which forms a relatively wide annular surface in the Distance of the inner wall of the motor housing 37 is opposite. The disc-shaped eccentric 52 is rotated by a number of pistons 54 actuated with pressure fluid offset, the pistons movable in cylinders 55 arranged radially to the eccentric 52 are.

The fluid motor shown consists of five interacting Pistons 54 and cylinders 55, which are acted upon by hydraulic fluid 63 one after the other to drive the shaft 41 in this way. Though any number from Zyliridenn can be used, it is still necessary more than three cylinders must be provided so that the engine can start itself.

The opposite end of the piston rod 65 is designed as a triangular shoe 71, the part 72 of which corresponds essentially to the width of the flange 53 on the eccentric and which rests against the eccentric 52 in the circumferential direction. On one side of the outer circumference of the part 72, a radial projection 73 is formed, over which a snap ring 74 engages with an inwardly protruding nose, so that the piston rod 65 is firmly connected to the eccentric 52 in the radial direction.

In Fig. 4, the hydraulic motor is connected with its cylinders 55 at the top and to the right of it with a pressure fluid supplying source, so that the inflowing fluid 63 moves the pistons 54 and thus the parts 72 of the shoes 71 inward. The direction of the force exerted on the eccentric 52 does not pass through the axis of the shaft 41 , so that the eccentric rotates counterclockwise. The upper left cylinder 55 lies with its center line, which passes through the axis of the shaft 41 and the true center of the eccentric 52, in the dead center. The lower left and right cylinders are connected to the low pressure side of the pressure medium source, as will be described below, so that the liquid 63 can flow out and the corresponding pistons 54 move outward. The cylinders that receive and deliver the hydraulic fluid work in mutually offset phases, with the work cycles overlapping.

As in particular the F i g. 2 and 3 show, two rigid links 79 and 80 are rotatably attached to one end of the housing 37 and at their other end to one of the end plates 24 by means of suitable articulated connections 81. This articulated connection 81 consists of two inwardly running pins 82 which are arranged at the end of the links 79 and 80 and are connected to a support ball 83 . For the purpose of mobility on all sides, the support balls 83 are arranged in correspondingly spherical openings which are provided in two matching lugs 84. The lugs 84 are welded to the housing 37 and the plate 24. The links 79 and 80 prevent lateral vibrations of the drum and stabilize the pan 29.

As in particular the F i g. 1, 3 and 6 will show the cylinders 55 of the hydraulic motor is preferably one flowing at low speed High pressure fluid 63 is supplied, which is supplied by a suitable pressure medium source 85 is delivered. The pressure medium source 85 is driven by the drive motor 6.

A valve control 87 mounted on the housing 37 is connected to the Pressure medium source 85 via two flexible lines 88 and 89 in connection. The lines 88 and 89 are alternately selected with the high-pressure and low-pressure side of the Pressure medium source 85 for forward or reverse rotation of the mixing drum 1 is connected.

As in particular the F i g. 3 and 5 show, the valve control 87 consists of a valve housing 90 which is accommodated in an opening in the motor housing 37. In the outer wall of the valve housing 90 two measuring and outlet openings 91 and 92 are arranged at a distance from one another and from which the lines 88 and 89 extend. There are also a number of distribution openings 93 which are in communication with the cylinders 55 via the various liquid lines 62. A rotary slide valve 94 is mounted in the valve housing 90 between the openings 91 and 92 and the openings 93. The rotary valve 94 is provided with a number of distribution openings 95 which successively connect the inlet and outlet openings 91 and 92 with the individual distribution openings 93 and thus with the cylinders 55. A drive shaft 96, which passes through the valve housing 90 and projects into the motor housing 37, is arranged on the rotary slide valve 94. At the extended end of the drive shaft 96 a gear 97 is attached, which is connected via a suitable intermediate gear 98 to a drive gear 99 on the shaft 41 of the hydraulic motor. The gear wheel 98 provides the timed synchronous movement of the rotary valve 94 with the shaft 41. As a result, the rotary valve 94 rotates slowly as soon as the shaft 41 rotates and successively connects the inlet and outlet ports 91 and 92 with the distribution ports 93, see above that corresponding pressure fluid 63 reaches certain cylinders 55, while fluid flows back from other cylinders.

The rotary slide valve shown is very simply built and works bumpless compared to conventional rotary valves.

The drive motor according to the present invention, which also serves as a bearing Invention allows an extremely advantageous weight distribution of the vehicle, the mixing device and the concrete located in it on the vehicle wheels, so that the proportion of the total weight that rests on the rear wheels, to a minimum value is lowered. It is therefore possible to transport a higher total load.

The mixing drum according to the invention can easily be attached to any conventional one Load vehicle mounted and also easily dismantled from a vehicle if necessary and be placed on top of another.

The design of the hydraulic motor as a front bearing of the drum has a change in the various parts to be attached to the vehicle result. In addition, the device is maintained by the close connection of the drive motor and drum a more modern appearance.

Claims (1)

Claims: 1. Concrete mixer arranged on the frame of a transport vehicle with a mixing drum rotatably mounted at both axial ends and an independent drive motor for the mixing drum, characterized in that the drive motor and the mixing drum (1) are arranged on a common shaft (41) that the motor-side end of the mixing drum (1) is supported by the drive motor and that the drive motor with the motor housing (37) is mounted on the frame (2) of the transport vehicle by means of an all-round movable joint (29, 33). z. Concrete mixer according to Claim 1, characterized in that the motor is a hydraulic radial motor with cylinders (55) arranged in a plane perpendicular to the shaft (41). 3. Concrete mixer according to claim 1 and 2; characterized in that the shaft (41) is non-rotatably connected to the mixing drum (1) . 4. Concrete mixer according to claim 3, characterized in that for connecting the mixing drum (1) to the shaft (41) the end wall (45) of the mixing drum (1) has an internally grooved hub (44) which is provided with an outer groove (47 ) the shaft (41) cooperates. 5. Concrete mixer according to one of claims 2 to 4, characterized in that the shaft (41) carries an eccentric (52) around the circumference of which the cylinders (55) connected to a pressure medium source (85) are arranged. 6. Concrete mixer according to claim 5, characterized in that a shoe (71) is attached to the free end of each piston rod (65) of the hydraulic radial engine and slides on the eccentric circumference. 7. Concrete mixer according to one of claims 1 to 6, characterized in that a rotary slide valve (94) of a valve control (87) is coupled to the shaft (41). B. concrete mixer according to claim 7, characterized in that the rotary slide valve (94) has a drive shaft (96) which is coupled directly to the shaft (41) via a spur gear (97, 98). 9. Concrete mixer according to one of claims 1 to 8, characterized in that the mutually movable joint consists of a ball (33) mounted in a pan (29), which by means of a pin (34) with the shaft (41) perpendicular to the axis Motor housing (37) is attached. 10. Concrete mixer according to claim 9, characterized in that the ball (33) relative to the plane of the hydraulic radial engine is offset so far forward that the ball and the rear, drum-side bearing (43) of the shaft (41) on an approximately vertical Lie level. 11. Concrete mixer according to one of claims 1 to 10, characterized in that the shaft (41) is designed as a hollow shaft, the bore (49) of which is used to supply water to the inside of the drum. 12. Concrete mixer according to one of claims 1 to 11, characterized in that the motor housing (37) is stabilized via a rigid link arrangement (79, 80) relative to the frame (2) of the vehicle. 13. Concrete mixer according to claim 12, characterized in that the links (79, 80) on the one hand pivotably on the motor housing (37) and on the other hand are hingedly attached to the frame (2) of the vehicle. Documents considered: German Patent No. 816 670; USA. Patent Nos: 1734 980, 1828 343, 2669131, 2676003.