CN114542767A

CN114542767A - Gas circuit control multi-way block structure

Info

Publication number: CN114542767A
Application number: CN202210274446.8A
Authority: CN
Inventors: 张伟
Original assignee: Shanxi Zhidian Technology Co ltd
Current assignee: Shanxi Zhidian Technology Co ltd
Priority date: 2022-03-21
Filing date: 2022-03-21
Publication date: 2022-05-27
Anticipated expiration: 2042-03-21
Also published as: CN114542767B

Abstract

The invention discloses a gas path control multi-joint block structure, which comprises an upper module (4) and a lower module (8); a pre-designed air path duct is processed in the upper module (4), a plurality of electromagnetic valves (2) for controlling the on-off of the air path are regularly installed on the front surface of the upper module (4), and the corresponding air inlet and air outlet of each electromagnetic valve (2) are correspondingly and hermetically communicated with the corresponding reserved air holes on the front surface of the upper module (4) after installation; the side surface of the upper module (4) is provided with a plurality of gas path connecting nozzles (6); the gas circuit pore passage area corresponding to the back of the upper module (4) is provided with a corresponding reserved orifice (10), the reserved orifice (10) for completing the same designed gas circuit is positioned in one sealing groove (11), and the periphery of each sealing groove (11) is provided with a corresponding sealing ring (9). The invention has reasonable design and good practical application value.

Description

Gas circuit control multi-way block structure

Technical Field

The invention relates to the technical field of gas circuit control for aerospace application, in particular to a novel designed gas circuit control multi-pass block structure.

Background

The existing gas circuit control multi-way block has many problems, including that the internal pipelines and cables are various and complicated in connection, so that the whole air tightness is poor, the faults are many, the size is large, the structure is heavy and the like, and due to the complicated gas circuit control principle, the light weight, the miniaturization and the good reliability of the multi-way block cannot be realized by the traditional design method.

Disclosure of Invention

In order to solve the problems of the existing gas circuit control multi-way block, the invention adopts a novel design method and a novel process to redesign the gas circuit of the control multi-way block, uses a fine long hole deep hole processing technology, adopts a novel material sealing ring for sealing, and utilizes a die structure for layout optimization to realize cable-free connection and pipeline-free connection.

The invention is realized by adopting the following technical scheme:

a gas path control multi-joint block structure comprises an upper module and a lower module.

A pre-designed air path duct is processed in the upper module, a plurality of electromagnetic valves for controlling the on-off of the air path are regularly installed on the front surface of the upper module, and the corresponding air inlet and air outlet of each electromagnetic valve are correspondingly and hermetically communicated with the corresponding reserved air holes on the front surface of the upper module after installation; the side surface of the upper module is provided with a plurality of gas path connecting nozzles; the corresponding gas circuit pore passage area of the back of the upper module is provided with a corresponding reserved orifice, the reserved orifice completing the same designed gas circuit is positioned in one sealing groove, and the periphery of each sealing groove is provided with a corresponding sealing ring.

The circuit board I is arranged on the lower module, and the lower module is arranged on the back surface of the upper module and then seals each sealing groove through a sealing ring; the circuit board I is correspondingly provided with a plurality of solenoid valve inserting ends, and the circuit slot of each solenoid valve is inserted into the corresponding solenoid valve inserting end.

The front side of the upper module is provided with a circuit board II, and a pin row on the circuit board II is spliced with a circuit board slot on the circuit board I; and an electric connector is arranged on the side surface of the circuit board II.

According to the invention, the design of the multi-way block is carried out according to the mold design principle, the multi-way block is divided into an upper module and a lower module, and the middle of the module is sealed by a novel material customized sealing ring, so that the product design requirement is finally met. The gas circuit control multi-way block completes a complex gas circuit by using a non-pipeline connection mode, and the circuit adopts a plug-in mode to realize light weight and miniaturization design.

The invention has the advantages of reasonable design, ingenious design of the air path control multi-way block, convenient and quick use, reliable performance and good practical application value.

Drawings

FIG. 1 is a front view of the air passage control manifold block structure.

Fig. 2 shows a rear elevation view of the upper module.

Fig. 3 shows an exploded view of the gas path control manifold block structure.

In the figure: the method comprises the following steps of 1-screw, 2-electromagnetic valve, 3-circuit board I, 4-upper module, 5-circuit board II, 6-gas path connector, 7-electric connector, 8-lower module, 9-sealing ring, 10-reserved hole opening, 11-sealing groove, 12-electromagnetic valve plug end, 13-circuit slot, 14-circuit board slot and 15-pin row.

Detailed Description

The following detailed description of specific embodiments of the invention refers to the accompanying drawings.

The utility model provides a block structure is led to gas circuit control more, has solved the control and has led to the block pipeline, line connection complicacy problem more, wholly realizes miniaturization, lightweight.

The concrete structure comprises an upper module 4 and a lower module 8.

The upper module 4 is internally provided with a pre-designed air passage hole, as shown in fig. 1 and 3, the front surface of the upper module 4 is regularly provided with a plurality of electromagnetic valves 2 for controlling the on-off of the air passage, each electromagnetic valve 2 is arranged at a preset position on the front surface of the upper module 4 through a screw 1, and the corresponding air inlet and air outlet of each electromagnetic valve are correspondingly and hermetically communicated with the corresponding reserved air hole on the front surface of the upper module 4 after being arranged. The side surface of the upper module 4 is provided with a plurality of air path connecting nozzles 6 for externally connecting air inlet and air outlet. The corresponding gas circuit pore passage area on the back of the upper module 4 is provided with a corresponding reserved orifice 10, the reserved orifice 10 completing the same designed gas circuit is positioned in one sealing groove 11, and the periphery of each sealing groove 11 is provided with a corresponding sealing ring 9, as shown in fig. 2. In the embodiment, two rows of electromagnetic valves are arranged on the front surface of the upper module, wherein the upper row comprises 5 electromagnetic valves, and the lower row comprises 6 electromagnetic valves; the back of the upper module is provided with 9 sealing grooves, the reserved orifices are positioned in the areas of the respective designed sealing grooves, 9 gas paths are correspondingly designed in the upper module, and the on-off of the gas paths is controlled by 11 electromagnetic valves.

As shown in fig. 3, a circuit board i 3 is mounted on the lower module 8 through a screw 1, and the lower module 8 is also mounted on the back surface of the upper module 4 through the screw 1 and then sealed by sealing rings 9 in respective sealing grooves 11, that is, each sealing groove is an independent space. Circuit board I3 is trilateral frame type, goes up module 4 design and makes and is located circuit board I3, is convenient for go up the connection assembly between module 4 and the lower module 8. The circuit board I3 is correspondingly provided with a plurality of solenoid valve plug-in ends 12, in the embodiment, the upper frame of the circuit board I3 is correspondingly provided with 5 solenoid valve plug-in ends 12, and the lower frame thereof is correspondingly provided with 6 solenoid valve plug-in ends 12, so that the circuit slot 13 of each solenoid valve 2 is plugged with the corresponding solenoid valve plug-in end 12. The upper end and the lower end of the frame of the circuit board I3 are respectively provided with a circuit board slot 14 (the length of the circuit board slot 14 is basically the same as the thickness of the upper module 4), the circuit board slot at the upper end is corresponding to the circuit connection of the 5 electromagnetic valve inserting ends of the upper frame, and the circuit board slot at the lower end is corresponding to the circuit connection of the 6 electromagnetic valve inserting ends of the lower frame. The circuit board II 5 is positioned on the front surface of the upper module 4, and the pin rows 15 at the upper end and the lower end of the circuit board II 5 are respectively spliced with the circuit board slots 14 at the upper end and the lower end of the circuit board I3. Further, the circuit board i 3 and the circuit board ii 5 are connected by screws 1. And an electric connector 7 is arranged on the side surface of the circuit board II 5.

In this embodiment, the upper module 4 is an L-shaped plate. The thickness of the electromagnetic valve 2 is basically the same as the length of the L-shaped end plate of the upper module 4, and the electric connector 7 penetrates through a reserved opening of the L-shaped end plate.

During specific work, this control is led to the inside gas circuit integrated design that adopts of the piece that leads to more, use fine slot hole BTA technique, realize the gas circuit control principle, structural configuration optimizes, apply mould design principle to lead to more in the piece, divide into module and lower module with original more to lead to the piece, the gas circuit is arranged in last module and lower module, with accurate lathe processing air flue and locating hole, it is integrative at last, adopt novel material sealing washer to seal, inside realizes no pipe connection, it is good to lead to the piece structural rigidity more, the gas circuit is durable reliable, the inner line is integrated through a customization board, cut straightly on the circuit board through the connector, realize wireless cable junction.

The gas path control multi-way block has the advantages of simple structure, convenient assembly, good sealing effect, reliable performance, high production and assembly efficiency and labor saving; the test method is simple, the performance is reliable, repeated troubleshooting is not needed, and extra cost is not needed to be added; the volume and the weight are reduced, and the device can be widely installed in narrow products.

Finally, it should be noted that the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the detailed description is made with reference to the embodiments of the present invention, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which shall be covered by the claims of the present invention.

Claims

1. The utility model provides a many terminal blocks of gas circuit control structure which characterized in that: comprises an upper module (4) and a lower module (8);

a pre-designed air path duct is processed in the upper module (4), a plurality of electromagnetic valves (2) for controlling the on-off of the air path are regularly installed on the front surface of the upper module (4), and the corresponding air inlet and air outlet of each electromagnetic valve (2) are correspondingly and hermetically communicated with the corresponding reserved air holes on the front surface of the upper module (4) after installation; the side surface of the upper module (4) is provided with a plurality of gas path connecting nozzles (6); corresponding reserved orifices (10) are arranged in the corresponding gas path pore passage area on the back of the upper module (4), the reserved orifices (10) completing the same designed gas path are positioned in one sealing groove (11), and a corresponding sealing ring (9) is assembled on the periphery of each sealing groove (11);

a circuit board I (3) is mounted on the lower module (8), and the lower module (8) is mounted on the back surface of the upper module (4) and then seals each sealing groove (11) through a sealing ring (9); a plurality of solenoid valve inserting ends (12) are correspondingly arranged on the circuit board I (3), and a circuit slot (13) of each solenoid valve (2) is inserted into the corresponding solenoid valve inserting end (12);

a circuit board II (5) is arranged on the front surface of the upper module (4), and a pin row (15) on the circuit board II (5) is inserted into a circuit board slot (14) on the circuit board I (3); and an electric connector (7) is arranged on the side surface of the circuit board II (5).

2. The air path control multi-pass block structure of claim 1, wherein: the lower module (8) and the upper module (4) are connected through screws (1).

3. The air path control multi-pass block structure according to claim 1 or 2, wherein: the circuit board I (3) is connected with the circuit board II (5) through a screw (1).

4. The air path control multi-pass block structure according to claim 1 or 2, wherein: the lower module (8) is connected with the circuit board I (3) through a screw (1).

5. The air path control multi-pass block structure of claim 1, wherein: the electromagnetic valve (2) is installed on the front face of the upper module (4) through a screw (1).

6. The air path control multi-pass block structure of claim 1, wherein: the upper module (4) is an L-shaped plate.