CN218325597U - Lightweight hydraulic manifold block structure - Google Patents

Abstract

The utility model discloses a lightweight hydraulic manifold block structure, which comprises a main input pipeline, wherein a plurality of output pipelines are arranged outside the main input pipeline, and a plurality of support plates are arranged on the output pipelines; the inlet sides of the plurality of output pipelines are communicated with the main input pipeline; supporting plates are arranged below the output pipelines; a sliding insertion part is arranged between the supporting plate and the output pipeline, a trapezoidal protrusion is arranged on the output pipeline, and a trapezoidal sliding groove is arranged on the supporting plate. The supporting block on the utility model can improve the structural strength of the hydraulic manifold block when in use; in addition, when the hydraulic manifold block is produced, the support bars can be prevented from being repeatedly arranged, so that the production of the hydraulic manifold block is more efficient; be provided with in the backup pad with trapezoidal protruding complex trapezoidal spout for the backup pad can be followed and dismantled on the hydraulic pressure manifold block, the hydraulic pressure manifold block when using, can be according to using the place, dismantles the backup pad of installing different positions, makes the hydraulic pressure manifold block possess better structural strength.

Description

Lightweight hydraulic manifold block structure

Technical Field

The utility model relates to a hydraulic system field, concretely relates to lightweight hydraulic manifold block structure.

Background

The hydraulic manifold block is usually a necessary part for realizing integration of a hydraulic system, simplifies pipeline connection and avoids a large number of pipe joints and complex pipeline connection. The traditional hydraulic manifold block takes forged steel as a material, and utilizes the traditional machining processes of drilling, boring and the like, so that the manufacturing process is complex, and the machining period is long. But also has some disadvantages as follows:

1. traditional hydraulic manifold piece is including main input pipeline and a plurality of output pipeline, and the great structural strength of main input pipeline diameter is better, but the less structural strength of output pipeline diameter is more weak, and the output pipeline during operation takes place to rock easily, and at the junction of main input pipeline and a plurality of input pipeline very much, the swing of output pipeline causes the junction to take place to tear or split very easily for hydraulic manifold piece takes place to damage easily and scrap.

2. The traditional hydraulic manifold block is large in size and heavy in mass, but the effective size is small, and along with the trend of light weight and high efficiency of a hydraulic system, the traditional hydraulic manifold block cannot meet the requirement of improving the performance of a flow channel; and abrupt corners are formed between adjacent flow channels, so that the structural strength is poor, the liquid flow is not smooth or stopped, and the pressure loss of the flow channels is large. Therefore, there is a need for a hydraulic manifold block structure with better structural strength and better flow passage performance.

SUMMERY OF THE UTILITY MODEL

Not enough to the above-mentioned of prior art, the utility model provides a hydraulic manifold block structure that structural strength is better, the runner performance is better.

In order to achieve the purpose of the invention, the technical scheme adopted by the utility model is as follows: the device comprises a main input pipeline, wherein a plurality of output pipelines are arranged outside the main input pipeline, and a plurality of supporting plates are arranged on the output pipelines; the inlet sides of the plurality of output pipelines are communicated with the main input pipeline, the outlet sides of the plurality of output pipelines are provided with internal threads for connecting the pipelines, and the upper end and the lower end of the main input pipeline are also provided with the internal threads for connecting the pipelines; supporting plates are arranged below the output pipelines; a sliding insertion part is arranged between the supporting plate and the output pipeline, a trapezoidal bulge is arranged on the output pipeline, and a trapezoidal sliding groove is arranged on the supporting plate.

Furthermore, the pipe outlet pipeline comprises a first output pipeline, a second output pipeline, a third output pipeline, a fourth output pipeline, a fifth output pipeline, a sixth output pipeline, a seventh output pipeline and an eighth output pipeline, and the seventh output pipeline is communicated with the eighth output pipeline through a connecting pipeline; the first support plate is arranged below the first output pipeline, the second support plate is arranged between the first output pipeline and the second output pipeline, the third support plate is arranged between the second output pipeline and the third output pipeline, the fourth support plate is arranged below the fourth output pipeline, the fifth support plate is arranged below the eighth output pipeline, the sixth support plate is arranged between the connecting pipeline and the fifth support plate, and the seventh support plate is arranged below the seventh output pipeline. The support plates are arranged in the direction of flow of the medium in the main supply line, and the main supply line is fixed vertically, so that the production is carried out by means of a material production technique.

Further, the first output pipeline, the second output pipeline, the third output pipeline, the fourth output pipeline and the fifth output pipeline are located in the same plane.

Further, the outlet sides of the fifth output pipeline and the sixth output pipeline are vertically upward; the seventh output pipeline is L-shaped, and the outlet side of the seventh output pipeline is vertically downward; the eighth output duct is perpendicular to the main input duct.

Further, the seventh output duct is a T-shaped duct.

Further, a first support plate; the second support plate, the third support plate, the fourth support plate, the fifth support plate, the sixth support plate and the seventh support plate are provided with a plurality of lightening holes. The lightening holes can lighten the weight of the support plates, and the lightening holes have certain shock absorption and buffering functions when the hydraulic manifold block vibrates.

Furthermore, a plurality of uniformly distributed lightening holes are arranged on the supporting plate, and the lightening holes are triangular or polygonal. The triangular or polygonal lightening holes can enable the hydraulic manifold block to have better molding supporting effect when being produced by an additive manufacturing technology.

Further, the fourth support plate is in an inverted trapezoid shape; the sixth supporting plate is triangular. The connecting pipeline is fixed with the seventh output pipeline and the eighth output pipeline in a triangular manner, so that the structural strength of the connecting pipeline, the seventh output pipeline and the eighth output pipeline is improved; the triangular sixth supporting plate can further improve the strength of the connecting pipeline.

The utility model has the advantages that: the hydraulic manifold block of the utility model is provided with the supporting block, the supporting block can improve the structural strength of the output pipeline, indirectly enhance the structural strength of the joint, and the supporting block can also reduce the shaking of the output pipeline during working; the hydraulic manifold block is provided with the trapezoidal bulge, so that the external strength of the output pipeline can be improved; when the additive manufacturing technology is used for producing the hydraulic manifold block, the support bars can be prevented from being repeatedly arranged, so that the production of the hydraulic manifold block is more efficient; be provided with in the backup pad with trapezoidal protruding complex trapezoidal spout for the backup pad can be followed and is dismantled on the hydraulic pressure manifold block, and the hydraulic pressure manifold block can be according to the use place, dismantles the backup pad of installing different positions, makes the hydraulic pressure manifold block possess better structural strength. The hydraulic manifold block structure of the utility model is manufactured by matching with the additive manufacturing technology, does not need complex procedures, and has short manufacturing time and high production efficiency; expensive moulds do not need to be designed and manufactured, and the manufacturing cost is low; the utility model discloses when utilizing the additive manufacturing technique production, do not need design or manufacturing mould, the material reduces by a wide margin during production moreover, and additive manufacturing technique adopts range upon range of mode to make output pipeline's corner, can reduce the resistance of corner to the fluid, reduces the runner loss of pressure to the fluid.

Drawings

Fig. 1 is a first schematic view of the present invention;

FIG. 2 is a schematic view showing the appearance in another direction of the present invention;

wherein the symbols of the components are as follows;

1. a main input pipe; 11. a first output conduit; 12. a second output duct; 13. a third output conduit; 14. a fourth output conduit; 15. a fifth output conduit; 16. a sixth output conduit; 17. a seventh output conduit; 18. an eighth output conduit; 19. connecting a pipeline;

21. a first support plate; 22. a second support plate; 23. a third support plate; 24. a fourth support plate; 25. A fifth support plate; 26. a sixth support plate; 27. and a seventh support plate.

Detailed Description

The following description of the embodiments of the present invention is provided to enable those skilled in the art to understand the invention, and it is to be understood that the invention is not limited to the details of the embodiments, but rather, the invention is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined and defined by the appended claims.

As shown in fig. 1 and 2, the lightweight hydraulic manifold block structure includes a main input pipeline 1, a plurality of output pipelines are arranged outside the main input pipeline 1, and a plurality of support plates are arranged on the output pipelines; the inlet sides of the output pipelines are communicated with the main input pipeline 1, the outlet sides of the output pipelines are provided with internal threads for connecting the pipelines, and the upper end and the lower end of the main input pipeline 1 are also provided with the internal threads for connecting the pipelines; supporting plates are arranged below the output pipelines; a sliding insertion part is arranged between the supporting plate and the output pipeline, a trapezoidal bulge is arranged on the output pipeline, and a trapezoidal sliding groove is arranged on the supporting plate.

The output pipelines comprise a first output pipeline 11, a second output pipeline 12, a third output pipeline 13, a fourth output pipeline 14, a fifth output pipeline 15, a sixth output pipeline 16, a seventh output pipeline 17 and an eighth output pipeline 18, and the seventh output pipeline 17 is communicated with the eighth output pipeline 18 through a connecting pipeline 19;

a first supporting plate 21 is arranged below the first output pipeline 11, a second supporting plate 22 is arranged between the first output pipeline 11 and the second output pipeline 12, a third supporting plate 23 is arranged between the second output pipeline 12 and the third output pipeline 13, a fourth supporting plate 24 is arranged below the fourth output pipeline 14, a fifth supporting plate 25 is arranged below the eighth output pipeline 18, a sixth supporting plate 26 is arranged between the connecting pipeline 19 and the fifth supporting plate 25, and a seventh supporting plate 27 is arranged below the seventh output pipeline 17. Several support plates are arranged in the direction of flow of the medium in the main supply line 1, and the main supply line 1 is fixed vertically, so that it is produced by means of material production technology.

In the present embodiment, the first output duct 11, the second output duct 12, the third output duct 13, the fourth output duct 14, and the fifth output duct 15 are located in the same plane.

In the present embodiment, the outlet sides of the fifth and sixth outlet ducts 15 and 16 are directed vertically upward; the seventh output pipeline 17 is L-shaped, and the outlet side of the seventh output pipeline 17 is vertically downward; the eighth outlet duct 18 is perpendicular to the main inlet duct 1.

In the present embodiment, the seventh output duct 17 is a T-shaped duct.

In the present embodiment, the first support plate 21; a plurality of lightening holes are formed on the second support plate 22, the third support plate 23, the fourth support plate 24, the fifth support plate 25, the sixth support plate 26 and the seventh support plate 27. The lightening holes can lighten the weight of the support plates, and the lightening holes have certain shock absorption and buffering functions when the hydraulic manifold block vibrates.

In the implementation, a plurality of lightening holes are uniformly distributed on the supporting plate, and the lightening holes are triangular or polygonal. The triangular or polygonal lightening holes can enable the hydraulic manifold block to have better molding supporting effect when being produced by an additive manufacturing technology.

In the present embodiment, the fourth support plate 24 has an inverted trapezoidal shape; the sixth support plate 26 has a triangular shape. The connecting pipeline 19, the seventh output pipeline 17 and the eighth output pipeline 18 form triangular fixation, which is beneficial to improving the structural strength of the connecting pipeline 19, the seventh output pipeline 17 and the eighth output pipeline 18; the triangular sixth supporting plate 26 can further improve the strength of the connecting duct 19.

Claims (8)

1. The lightweight hydraulic manifold block structure is characterized by comprising a main input pipeline (1), wherein a plurality of output pipelines are arranged outside the main input pipeline (1), and a plurality of support plates are arranged on the output pipelines; the inlet sides of the output pipelines are communicated with the main input pipeline (1), the outlet sides of the output pipelines are provided with internal threads for connecting pipelines, and the upper end and the lower end of the main input pipeline (1) are also provided with the internal threads for connecting pipelines;

supporting plates are arranged below the output pipelines; the support plate with be provided with the smooth portion of inserting between the output pipeline, be provided with trapezoidal arch on the output pipeline, be provided with trapezoidal spout in the support plate.

2. The hydraulic manifold block structure with reduced weight according to claim 1, wherein the output conduits include a first output conduit (11), a second output conduit (12), a third output conduit (13), a fourth output conduit (14), a fifth output conduit (15), a sixth output conduit (16), a seventh output conduit (17), and an eighth output conduit (18), and the seventh output conduit (17) and the eighth output conduit (18) are communicated through a connecting conduit (19); first output pipeline (11) below is provided with first backup pad (21), first output pipeline (11) with be provided with second backup pad (22) between second output pipeline (12), second output pipeline (12) with be provided with third backup pad (23) between third output pipeline (13), the below of fourth output pipeline (14) is provided with fourth backup pad (24), the below of eighth output pipeline (18) is provided with fifth backup pad (25), connecting tube (19) with be provided with sixth backup pad (26) between fifth backup pad (25), the below of seventh output pipeline (17) is provided with seventh backup pad (27).

3. The lightweight hydraulic manifold block structure according to claim 2, wherein the first output conduit (11), the second output conduit (12), the third output conduit (13), the fourth output conduit (14) and the fifth output conduit (15) are located in the same plane.

4. The hydraulic manifold block structure, according to claim 2, characterized in that the outlet sides of the fifth (15) and sixth (16) output ducts are directed vertically upwards; the seventh output pipeline (17) is L-shaped, and the outlet side of the seventh output pipeline (17) is vertically downward; the eighth outlet duct (18) is perpendicular to the main inlet duct (1).

5. The hydraulic manifold block structure, as set forth in claim 2, characterized in that the seventh output duct (17) is a T-shaped duct.

6. The lightweight hydraulic manifold block structure according to claim 2, wherein the first support plate (21); a plurality of lightening holes are formed in the second supporting plate (22), the third supporting plate (23), the fourth supporting plate (24), the fifth supporting plate (25), the sixth supporting plate (26) and the seventh supporting plate (27).

7. The lightweight hydraulic manifold block structure of claim 1, wherein the support plate is provided with a plurality of weight-reducing holes which are uniformly distributed, and the weight-reducing holes are triangular or polygonal.

8. The hydraulic manifold block structure, as set forth in claim 2, characterized in that the fourth support plate (24) is an inverted trapezoid; the sixth supporting plate (26) is triangular.

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