WO2014016022A1

WO2014016022A1 - Rotary distributor for thick matter

Info

Publication number: WO2014016022A1
Application number: PCT/EP2013/061278
Authority: WO
Inventors: Karl Westermann; Michael BRIEM
Original assignee: Putzmeister Engineering Gmbh
Priority date: 2012-07-24
Filing date: 2013-05-31
Publication date: 2014-01-30
Also published as: EP2877651B1; US20150225970A1; CN104487638A; EP2877651A1; JP6134794B2; JP2015528076A; CN105839923A; DE102012212916A1; KR20150033636A

Abstract

The invention relates to a rotary distributor (10) for thick matter, in particular for fresh concrete, having a load-bearing framework (14), which can be set down on a set-down surface (18), having a first extension-arm tube (26), which is arranged on the load-bearing framework (14) such that it can be rotated about a framework-mounted vertical axis (24) in the region of its inlet end (22), and having a second extension-arm tube (30), which is arranged such that it can be pivoted about a horizontal pivot axis (28) in the region of the outlet end (25) of the first extension-arm tube (26) and communicates with the first extension-arm tube (26). The novelty claimed is the fact that the first extension-arm tube (26), in the region of its inlet end (22), can be pivoted, in addition, about a horizontal axis (32) in relation to the load-bearing framework (14), and that the second extension-arm tube (30) can be rotated, in addition, about an axis of rotation (34), which is perpendicular to the horizontal pivot axis (28), in relation to the outlet end (25) of the first extension-arm tube (26). Parallel-guidance means (36) are also provided between the first and the second extension-arm tubes (26, 30), and these ensure that the second extension-arm tube (30), in different pivoting positions of the first extension-arm tube (26), is maintained in an alignment substantially parallel to the set-down surface (18).

Description

The invention relates to a rotary distributor for thick materials, in particular for fresh concrete, with a support frame which can be erected on a mounting surface, having a first boom tube rotatably mounted on the support frame around a frame-fixed vertical axis in the region of its input-side end and pressurized there with the thick materials with a arranged in the region of the output-side end of the first boom tube about a horizontal pivot axis, pivotally communicating with the first boom tube second boom tube.

In large concrete construction projects, where large quantities of fresh concrete have to be applied in a short time, classic concreting methods, such as concreting with a crane bucket, are not efficient enough. If in concrete transport long distances or high altitudes have to be overcome, nowadays mostly stationary concrete pumps with delivery line system are used. Distributor masts and rotary distributors, for example, are considered as distributing devices at the end of a stationary conveying line. Rotary distributor of the type initially specified usually consist of a two-piece boom, a counter-jib with ballast and a usually designed as a base support frame. The two cantilever tubes of the two-piece cantilever are usually connected by a joint that only allows rotation about the vertical axis. Rotary distributor can thus move only in the horizontal plane. While the mast arm in distribution booms is always composed of a load-bearing construction and a connected delivery line for safety reasons due to the high working height, the second arm of a rotary distributor usually only consists of a self-supporting delivery pipe. Rotary distributors usually have no drive but are manually guided by the operator. Due to their simple structure and because of their low Range, they are relatively inexpensive. They are therefore preferred in simple concreting tasks use. The scissor-like mobility of the second boom tube relative to the first boom tube has the advantage that the rotary distributor, in contrast to distributor masts, are outstandingly suitable for surface concrete layers. With such a concreting task, even with little experience and training, an operator can easily deploy the concrete by manually moving the boom tubes to any location within the operating radius of the rotary distributor. The risk that objects or persons standing in the area of action will be damaged or injured thereby is relatively small. On the other hand, round distributors have a concept-related disadvantage compared to a stationary distributor boom. They are unable to overcome obstacles in the work area. However, vertical reinforcements for columns or wall connections, formwork, transport and storage containers or the like can often be found on the surfaces to be concreted on the construction sites. These parts form obstacles that limit the mobility of the rotary distributor and require a repeated and thus uneconomical relocation of the rotary distributor. In the worst case one must even refrain entirely from the use of the rotary distributor, so that alternatively only the expensive stationary boom comes into consideration.

Proceeding from this, the present invention seeks to improve a rotary distributor of the type specified in that his work area expanded and any obstacles on the site can be avoided easier.

To solve this problem, the feature combinations specified in the claims 1 and 2 are proposed. Advantageous embodiments and further developments of the invention will become apparent from the dependent claims. The solution according to the invention is based primarily on the idea that a rotary distributor with liftable first boom tube of the entire boom can be easily pivoted across obstacles and a laborious changeover of the rotary distributor is eliminated. In order to enable a lifting of the first boom tube, it is proposed according to the invention that the first boom tube in the region of its input-side end in addition to the vertical axis of rotation is additionally pivotable about a horizontal axis relative to the support frame. If, in this case, the joint between the two cantilever tubes was, as usual, equipped with only one horizontal axis, then the second cantilever tube would likewise tilt when lifting the first one. As a result, the axis of rotation between the two cantilever tubes would no longer be vertical. The second boom tube would pivot to the side automatically. To avoid this disadvantage, it is also proposed according to the invention that the second boom tube is additionally rotatable about a pivot axis perpendicular to the horizontal pivot axis relative to the output side end of the first boom tube, and that between the first and the second boom tube parallel guide means are provided to are determined and suitable - to keep the second boom tube in different pivotal positions of the first boom tube in a substantially parallel to the footprint alignment, and / or the horizontal axis of rotation perpendicular axis of rotation of the second boom tube in different pivotal positions of the first boom tube in parallel to the frame-fixed vertical axis alignment to keep.

With these measures it is achieved that the second boom tube is always kept level, regardless of the angle of attack of the first boom tube via the parallel guide. The guide of the second boom tube parallel to the footprint can be realized for example by means of two clamping elements which connect the joint of the first boom tube with the joint of the second boom tube. This is a coupling gear, in which the parallel guide means comprise a web aligned parallel to the frame-fixed vertical axis and a parallel to the arranged at the output end of the first boom tube axis of rotation of the second boom tube coupling a four-bar linkage in the manner of a double crank, and in which the second Boom tube is aligned substantially perpendicular to the coupling of the four-bar linkage.

When using self-supporting cantilever tubes, it is advantageous if the first cantilever tube is connected via at least two pipe elbows and a corresponding number of pipe couplings to a frame-fixed pipe piece, wherein two of the pipe couplings are formed as rotary couplings with mutually perpendicularly oriented axes of rotation. Advantageously, one of the rotary couplings forms the vertical axis and the other rotary coupling the horizontal axis of the first boom tube relative to the support frame.

A similar construction can be used in the connection of the first and the second boom tube. Here, the second boom pipe is connected at its input end via at least two pipe elbows and a corresponding number pipe couplings to the output side end of the first boom tube, wherein two of the pipe couplings are formed as rotary joints with mutually perpendicularly oriented axes of rotation. Advantageously, one of the rotary couplings forms the horizontal pivot axis, while the other rotary coupling forms the axis of rotation perpendicular thereto between the first and the second boom tube. In order to ensure a sufficient stability of the rotary distributor, it is advantageous if in the region of the input-side end of the first boom tube with this to the frame-fixed vertical axis co-rotating ballast boom is arranged.

To raise and lower the boom many possibilities are conceivable. A preferred embodiment provides for this purpose that the first boom tube by means of a lifting device about its input-side horizontal axis under raising or lowering of the second boom tube relative to the support frame is pivotable. The lifting device may have a clamped or tensioned between the boom tube and the ballast boom, under pivoting of the first boom tube about its horizontal axis mechanically actuated tension or tension member. For this purpose, the lifting device advantageously has a lever which is articulated on the ballast arm or on the web of the four-link transmission and can be moved by means of a drive mechanism, the free lever end of which is connected to the first boom tube via the tensioning or tension member. According to an advantageous development of this principle, the lifting device has a two-armed lever arranged on the ballast arm whose load arm is connected via the tensioning or tension member to the first boom tube and whose power arm is coupled to a drive mechanism supported on the ballast boom and preferably designed as a hydraulic cylinder. For a uniform distribution of the concrete on a concreting or in a formwork, it may also be advantageous if the second boom tube carries at its example equipped with a 90 ° elbow free end down a hanging end hose.

In the following the invention will be explained in more detail with reference to the embodiments schematically illustrated in the drawing. Show it:

Fig. 1 a round distributor with a two-armed boom and a

end hose; Figure 2 shows the boom of the rotary distributor with its interconnected via elbows boom arms. Fig. 3 is a schematic diagram of the rotary distributor with support frame, two

Boom pipes and a parallel guide.

The illustrated in the drawing rotary distributor 10 is used for the introduction of fresh concrete on construction sites where the direct distribution with stationary distribution booms reaches technical or economic limits. The rotary distributor 10 can overcome with its exit point 12 both large concreting and a certain height and yet is simple and easy to handle. As can be seen from FIGS. 1 and 3, the rotary distributor has a support frame 14, which can be set up with four star-shaped pivot legs 16 on a mounting surface 18. The four pivoting legs 16 can be folded in pairs up and to the side, so that the rotary distributor 10 can be transported without disassembly on a truck or a container to save space.

The rotary distributor 10 includes a two-armed boom 20, which is arranged around a frame-fixed horizontal axis 24 rotatably mounted on the support frame 14 in the region of its input end end 22 and a pivotable about a horizontal pivot axis 28 in the region of the output side end 25 of its first boom tube 26, with the first boom tube 26 communicating second boom tube 30 summarizes. A special feature of the invention is that the first boom tube 26 in the region of its input end 22 is additionally pivotable about a horizontal axis 32 relative to the support frame 14 and that the second boom tube 30 in addition to a horizontal pivot axis 28 perpendicular axis of rotation 34 opposite the output side. gene end 25 of the first boom tube 26 is rotatable. Parallel guide means 36 are provided between the first and second jib tubes 26, 30, which ensure that the second jib tube 30 is always held in different pivotal positions of the first jib tube 26 in a direction substantially parallel to the setting surface 18. At the same time this means that under the action of the parallel guide means 36 which is perpendicular to the horizontal pivot axis 28 axis of rotation 34 of the second boom tube 30 is held in different pivotal positions of the first boom tube 26 in the frame-fixed vertical axis 24 parallel alignment. The parallel guide means 36 thus form a coupling mechanism in the manner of a parallelogram guide or a double crank, which aligns a web 38 aligned parallel to the frame-fixed vertical axis 24 and a rotation axis 34 of the second cantilever tube 30 arranged parallel to the axis of rotation 34 of the first cantilever tube 26 Coupling 40 have. The second boom tube 30 is aligned substantially perpendicular to the coupling 40, and describes with its tip 42 a coupling curve, which results from the always horizontal alignment during pivoting of the first boom tube 26. For directional stabilization of the second boom tube 30 in its parallel to the footprint 18 position, a clamping member 70 is additionally provided in the embodiments of FIGS. 1 and 3 extending from the free end of the coupling 40 obliquely to the second boom tube 30 and is fixed thereto , The second boom tube 30 can also be connected to a further reinforcement with a support bar 72, which ensures that the second boom tube 30 is not bent under the load of fresh concrete flowing through.

At its free tip 42, the second boom tube 30 opens via a 90 ° bend 44 in a downwardly hanging end hose 46, through which the concrete can be conveniently applied to the concreting. In Fig. 2 it can be seen that the boom 20 is composed of self-supporting boom tubes 26,30. In this case, the first boom pipe 26 is connected via a total of four pipe bend 48 and five pipe couplings 50 to a frame-fixed pipe section 52. Two of the pipe couplings are in this case designed as rotary couplings 50 ', 50 "with mutually perpendicularly oriented axes of rotation 24, 32. One of the rotary couplings 50' forms the vertical axis 24, while the other rotary coupling 50" forms the horizontal axis 32 of the first boom pipe 26 relative to the supporting frame 14 forms. Further, in the embodiment shown in Fig. 2, the second boom tube 30 is connected at its input end 54 via five elbow 56 and six pipe couplings 58 to the output side end 25 of the first boom tube 26, wherein the pipe coupling 58 'as a rotary coupling the horizontal pivot axis 28 and another rotary coupling (not shown) form the rotation axis 34 perpendicular thereto between the first and the second boom tube 26,30.

In the area of the input-side end 22 of the first boom tube 26 there is a ballast boom 60, which rotates about the frame-fixed vertical axis 24 and is necessary for the stability of the rotary distributor 10 on the mounting surface 18.

Another special feature of the invention is that the first boom tube 26 by means of a lifting device 62 about its input-side horizontal axis 32 under raising or lowering of the second boom tube 30 relative to the support frame 14 is pivotable. In the exemplary embodiment shown in FIGS. 1 and 3, the lifting device 62 has a tensioning or tensioning element 64 clamped between the first boom tube 26 and the ballast arm 60 and pivotable about the horizontal axis 32 by pivoting the first boom tube 26. In this exemplary embodiment, the lifting device 62 consists of a two-armed lever 66 which is articulated on the ballast arm 60 and whose load arm 66 'is connected to the first boom tube 26 via the tension or tension member 64 and the latter Power arm 66 "is coupled to a supported on the ballast arm 60, designed as a hydraulic cylinder drive mechanism 68. This is only a special embodiment for the operation of the boom 10. The lifting of the first boom tube 26 can also be done otherwise Lifting device 62 comprises a lever which is articulated on the ballast arm 60 or on the web 38 of the four-bar mechanism and which is movable by means of a drive mechanism 68, the free end of which is connected to the first boom tube 26 via the tension or tension member 64. Basically, the lifting and lowering of the first Auslegerarms 26 also be made by hand.

In summary, the following is to be stated: The invention relates to a rotary distributor 10 for thick materials, in particular for fresh concrete, with a mountable on a support surface 18 support frame 14, arranged with a in the region of its input end 22 to a frame-fixed vertical axis 24 rotatably mounted on the support frame 14 and there with the thickers under pressure acted upon first boom tube 26, and arranged in the region of the output side end 25 of the first boom tube 26 pivotable about a horizontal pivot axis 28, communicating with the first boom tube 26 second boom tube 30. As new is claimed that the first boom tube 26 in the region of its input-side end 22 is additionally pivotable about a horizontal axis 32 relative to the support frame 14, that the second boom tube 30 in addition to a horizontal pivot axis 28 perpendicular axis of rotation 34 against the output side end 25 of the first Ausl egerrohrs 26 is rotatable. Furthermore, parallel guide means 36 are provided between the first and the second jib tube 26, 30, which ensure that the second jib tube 30 is held in different pivotal positions of the first jib tube 26 in a direction substantially parallel to the set-up surface 18. LIST OF REFERENCE NUMBERS

10 round distributors

12 exit point

14 support frame

16 pivot legs

18 footprint

20 two-armed outrigger

22 input end

24 horizontal axis / axis of rotation / vertical axis

25 output end

26 first boom tube

28 horizontal pivot axis

30 second boom tube

32 horizontal axis / axis of rotation

34 vertical axis of rotation

36 parallel guidance means

38 footbridge

40 paddock

42 tip

44 90 ° -Krü always

46 end hose

48 pipe elbows

50 pipe coupling

50 \ 50 "rotary joint

52 pipe piece

54 input end

56 pipe elbows

58 pipe coupling

58 'rotary joint

60 ballast boom

62 Lifting device Clamping or tension member two-armed lever 'load arm

"Poor in strength

Drive mechanism tendon

supporting strip

Claims

claims

1 . Rotary distributor for thick materials, in particular for fresh concrete, with one on a footprint (18) erectable support frame (14) with a in the region of its input side end (22) about a frame-fixed vertical axis (24) rotatably mounted on the support frame (14) and there with the Thick materials under pressure can be acted upon first cantilever tube (26), and with a in the region of the output-side end (25) of the first cantilever tube (26) about a horizontal pivot axis (28) pivotally arranged, with the first cantilever tube (26) communicating second cantilever tube ( 30), characterized in that the first boom tube (26) in the region of its input-side end (22) in addition to a horizontal axis (32) relative to the support frame (14) is pivotable that the second boom tube (30) additional borrowed by a for horizontal pivot axis (28) vertical axis of rotation (34) relative to the output side end (25) of the first boom tube (26) is rotatable, and that between d Parallel to the first and the second boom tube (26,30) parallel guide means (36) are provided, which are adapted, the second boom tube (30) in different pivotal positions of the first boom tube (26) in one to the footprint (18) substantially parallel To keep alignment.

2. Rotary distributor for thick materials, especially for fresh concrete, with one on a footprint (10) can be set up support frame (14), with an im

Region of its input-side end (22) about a frame-fixed vertical axis (24) rotatably mounted on the support frame (14) and there pressurized with the thickers first boom tube (26), and one in the region of the output-side end (25) of the first boom tube ( 26) pivotable about a horizontal pivot axis (28), communicating with the first boom tube (26). decorating second boom tube (30), in particular according to claim 1, characterized in that the first boom tube (26) in the region of its input end (22) in addition to a horizontal axis (32) relative to the support frame (14) is pivotable that the second boom tube (30) is additionally rotatable relative to the output-side end (25) of the first cantilever tube (26) about an axis of rotation (34) perpendicular to the horizontal pivot axis (28), and that parallel guidance means is provided between the first and second cantilever tubes (26, 30) (36) are provided, which are intended and suitable for the horizontal pivot axis (28) perpendicular axis of rotation (34) of the second boom tube (30) in different pivotal positions of the first boom tube (26) in the frame-fixed vertical axis (24) parallel alignment hold. 3. Rotary distributor according to claim 1 or 2, characterized in that the parallel guide means (36) parallel to the frame-fixed vertical axis (24) aligned web (38) and a parallel to the at the output end (25) of the first boom tube (26) arranged axis of rotation (34) of the second boom tube (30) aligned coupling (40) of a four-bar mechanism in the manner of a double crank, and that the second boom tube (30) is aligned substantially perpendicular to the coupling (40) of the four-bar mechanism.

Rotary distributor according to one of claims 1 to 3, characterized in that the first boom tube (26) via at least two elbows (48) and a corresponding number pipe couplings (50) to a frame-fixed pipe section (52) is connected, wherein two of the pipe couplings (50 ) are formed as rotary joints (50 ', 50 ") with mutually perpendicularly oriented axes of rotation (24,32).

5. Rotary distributor according to claim 4, characterized in that one of the rotary couplings (50 ') the vertical axis (24) and the other rotary coupling (50 ") forms the horizontal axis (32) of the first boom tube (26) relative to the support frame (14).

6. Rotary distributor according to one of claims 1 to 5, characterized in that the second boom tube (30) at its input-side end (54) via at least two elbows (56) and a corresponding number of pipe couplings (58) to the output end ( 25) of the first boom tube (26) is connected, wherein two of the pipe couplings as rotary couplings (58 ') are formed with mutually perpendicularly aligned axes of rotation (28,34).

7. Rotary distributor according to claim 6, characterized in that one of the rotary couplings (58 '), the horizontal pivot axis (28) and the other rotary coupling form the perpendicular thereto rotation axis (34) between the first and the second boom tube (26,30).

8. Rotary distributor according to one of claims 1 to 7, characterized in that in the region of the input-side end (22) of the first

Boom tube (26) with this around the frame-fixed vertical axis (24) co-rotating ballast arm (60) is arranged.

9. Rotary distributor according to one of claims 1 to 8, characterized in that the first boom tube (26) by means of a lifting device

(62) is pivotable about its input side horizontal axis (32) with raising or lowering of the second boom tube (30) relative to the support frame (14). 10. Rotary distributor according to claim 9, characterized in that the lifting device (62) between the first boom tube (26) and the Ballast boom (60) clamped, under pivoting of the first boom tube (26) about its horizontal axis (32) mechanically actuated tension or tension member (64). 1 1. Rotary distributor according to Claim 10, characterized in that the lifting device (62) has a lever (66), which is articulated on the ballast arm (60) or on the web (38) of the four-bar linkage and has a drive mechanism (68) whose free lever end extends beyond the clamping device. or tension member (64) with the first boom tube (26) is connected.

Rotary distributor according to Claim 10 or 11, characterized in that the lifting device (62) has a two-armed lever (66) arranged on the ballast arm (60), the load arm (66 ') of which is connected to the first arm tube via the tensioning or tension member (64) (26) is connected and whose power arm (66 ") with a ballast on the boom (60) supported, preferably designed as a hydraulic cylinder drive mechanism (68) is coupled.