BR212017014222Y1 - fast insertion structure and motor using the same - Google Patents

Abstract

QUICK INSERT STRUCTURE AND MOTOR USING THE SAME. The present utility model provides a quick insertion structure, which includes a plug and a gasket. The plug has a tangent plane that extends from an end of insertion of the plug in an axial direction, an inclined surface that extends from a tail end of the tangent plane and a clamping surface that extends from a tail end of the surface tilted in a radial direction. The joint has a clamping jaw provided with a clamping groove and an insertion groove, the clamping groove has a limiting surface. When the plug is inserted into the joint, the tangent plane is inserted into the insertion groove, the clamping surface cooperates with the limiting surface and the axial length from a starting end of the tangent plane to the clamping surface is greater than the axial length from an initial end of the insertion groove to the limiting surface. The utility model also provides a motor using the quick insertion structure. The quick insertion structure and the motor have the advantage of being stable in connection.

Description

FIELD OF APPLICATION OF THE INVENTION

[001] The current utility model relates to the field of pipe connections and, more particularly, to a fast insertion structure and a motor that uses the same.

TECHNICAL STATUS

[002], Quick insertion structures are widely applied to pipe connections due to the advantage of easy operation. A quick insertion structure of the prior art is shown in Fig. 1. A clamping jaw 3 is mounted on a joint 1 and is provided with a clamping groove 4. A clamping tongue 5 is provided on a plug 2. After the plug 2 It is inserted into the joint 1, the two are positioned in an axial direction completely through the cooperative between the clamping tongue 5 and the clamping groove 4. A sealing ring 6 also pushes the clamping tongue 5 to extend into the clamping groove 4 in a radial direction, in addition to playing a sealing role. The quick insertion structure in the prior art has the following defects when applied to an engine.

[003] 1. The motor operates with frequent vibrations in the cooperative position of plug 2 and joint 1. Since the clamping tongue 5 has a certain freedom of axial movement in the clamping groove 4, the plug 2 and the joint 1 they rotate around the center line of the cooperating interface of the plug 2 and the joint 1, so that the cooperating interface disengages, resulting in loss of assembly relationship and connection failure.

[004] 2. An O-ring seal 6 is used to seal a gas or liquid between the plug 2 and the gasket 1. The seal ring 6 is subjected to a shearing force from a cooperating surface in the cooperating position to result in relative slip AND deformation, so that it is likely to damage the seal ring and cause leakage in the cooperative position.

BRIEF DESCRIPTION OF THE INVENTION

[005] An objective of the present utility model is to overcome the above problems and provide a fast insertion structure that is more stable in connection.

[006] To achieve the objective, the forms of realization of the present utility model adopt the following technical scheme:

[007] A quick insertion structure, comprising a plug and a joint, in which the plug has a tangent plane that extends from an insertion end of the plug in an axial direction, an inclined surface that extends from a tail end of the tangent plane and a clamping surface extending from a tail end of the surface inclined in a radial direction; the joint having a clamping claw provided with a clamping groove and an insertion groove, the clamping groove has a limiting surface; when the plug is inserted into the joint, the tangent plane is inserted into the insertion groove, the clamping surface cooperates with the limiting surface and the axial length from a starting end of the tangent plane to the clamping surface is greater than the axial length from an initial length of the insertion groove to the limiting surface.

[008] Preferably, the quick-insert structure further comprises a sealing ring, in which a groove in the sealing ring is formed in a position, surrounded by the clamping jaw, in the joint, and the sealing ring being located in the groove of the corresponding sealing ring.

[009] Preferably, the seal ring has a plurality of points protruding in the circumferential direction of it, at intervals.

[010] Preferably, at least two o-ring grooves are provided, where one o-ring groove is opposite the clamping groove, and the other o-ring groove deviates from the clamping groove and is spaced apart the insertion slot.

[011] Preferably, the clamping jaw is in the form of an elliptical ring, the clamping groove being located on a short axis of the elliptical ring, the engagement portions of the clamping jaw being provided at both ends of a long axis of the elliptical ring and the clamping groove expand in the direction of the short axis when the engagement portions are compressed together.

[012] A motor is provided, comprising the motor pipes being connected using the quick insertion structure described above.

[013] According to the fast insertion structure and the motor provided by the present utility model, since the axial length from the starting end of the tangent plane to the clamping surface is greater than the axial length from the end of starting from the insertion groove to the limiting surface, the tangent plane will push the clamping surface against the limiting surface when the plug is inserted into the joint, so that the plug and the joint are not prone to relative rotation under the condition of vibration and therefore are more stable in the connection.

[014] In addition, through the saline points on the seal ring, the saline points on both sides of the seal ring come into contact with the two side surfaces of the seal ring groove to fix the position of the seal ring afterwards that the seal ring is mounted inside The groove of the seal ring. When the quick insertion frame is assembled, the seal ring is unlikely to slip, and the compression rate and fill rate of the seal ring are little affected by the protruding points, so the life of the seal ring is extended and cooperation is more reliable.

[015] In addition, when the locking portions are compressed together, expanding the clamping groove in the direction of the short axis of the elliptical ring can ensure that the limiting surface can disengage easily from the clamping surface, so that the quick insertion can be disassembled, allowing convenient operations.

BRIEF DESCRIPTION OF THE DRAWINGS

[016] The specific embodiments of the present utility model will be further described in detail with reference to the accompanying drawings, in which: Fig. 1 is a schematic structural view of the prior art quick insertion structure; Fig. 2 is a front view of the joint according to an embodiment of the present utility model; Fig. 3 is a view to the left of the joint in Fig. 2; Fig. 4 is a sectional view along line A-A in Fig. 3; Fig. 5 is a cross-sectional view of the joint according to an embodiment of the present utility model; Fig. 6 is a stereogram of the sealing ring according to an embodiment of the present utility model; Fig. 7 is a cross-sectional view of the quick insertion structure according to an embodiment of the present utility model; Fig. 8 is a schematic structural view of the secondary air injection system using the quick insertion structure in Fig. 7 according to an embodiment of the present utility model.

[017] Reference signs in the drawings: 100, joint; 0100, common pipe body; 110, clamping jaw; 111, surrounding portion; 112, clamping groove; 113, insertion slot; 114, end of the beginning; 115, limiting surface; 120, final interface; 130, first seal ring groove; 140, second sealing ring groove; 200, buffer; 210, insertion end; 220, tangent plane; 230, inclined surface; 231, initial end of the inclined surface; 232, tail end of the sloping surface; 240, clamping surface; 300, seal ring; 310, salient point; 400, hose; 500, secondary air injection pump; 600, secondary air combination valve.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE PRESENT INVENTION

[018] With reference to Fig. 2 and Fig. 3, joint 100 has a clamping grip 110 in the form of an elliptical ring. The center of the elliptical ring coincides with the center of a joint tube body 0100 of joint 100. A clamping groove 112 of clamp claw 110 is located in a position, closer to joint body 0100, of the ring elliptical (i.e., both ends of a short axis S of the elliptical ring) and a locking portion 111 of the clamping jaw 110 is located in a position, furthest from the joint tube body 0100, of the elliptical ring (i.e. ie, both ends of a long axis of the elliptical ring). The clamping grip 110 is made of a material with a certain elasticity such as plastic. Due to the elliptical ring structure of the clamping jaw 110, when the locking portions 111 are compressed together by a clamping force F as shown in Fig. 3, the elliptical ring tends to be annular. The clamping groove 112 expands in the direction of the short axis.

[019] With reference to Fig. 4, the clamping claw 110 of joint 100 is provided with a clamping groove 112 and an insertion groove 113, the clamping groove 112 having a limiting surface 115. The axial length from of a starting end 114 of the insertion groove 113 For the limiting surface 115 is w1. A first o-ring groove 130 and a second o-ring groove 140 are provided in positions, surrounded by clamping jaws 110, at joint 100. The first o-ring groove 130 is opposite to clamping groove 112, the second o-ring groove 140 deviates from clamping groove 112 and the second o-ring groove 140 is further away from insertion groove 113 than clamping groove 112, or the second o-ring groove 140 is more near an interface end 120 of joint 100.

[020] With reference to Fig. 5, the plug 200 has a tangent plane 220 that extends from an insertion end 210 of the plug in an axial direction, so that plug 210 is also the starting end of the plane tangent 220. An inclined surface 230 begins to extend from a tail end of tangent plane 220, i.e., a starting end 231 of the inclined surface. A clamping surface 240 begins to extend from a tail end 232 of the inclined surface 230 in a radial direction. The axial length from the starting end 210 of the tangent plane 220 to the clamping surface 240 is w2.

[021] With reference to Fig. 6, the seal ring 300 is provided with a plurality of protruding points 310 in its circumferential direction at intervals.

[022] With reference to Fig. 7, the plug 200 is inserted into the plug 100 to form the quick insertion structure and a hose 400 is connected to the joint 100. At this point, the tangent plane 220 is inserted into the insertion groove 113 and The clamping surface 240 cooperates with the limiting surface 115, so that the plug 200 cannot be disengaged from the inside of the joint 100. In addition, in this quick insertion structure, w2> w1 and therefore the tangent plane 220 will push o Clamping surface 240 against limiting surface 115, so that plug 200 and joint 100 are less prone to relative rotation under vibration conditions and are more stable in connection. The two seal rings 300 are located in the first seal ring groove 130 and the second seal ring groove 140, respectively. The sealing ring 300 in the first groove of the sealing ring 130, in addition to playing a sealing role, also pushes the inclined surface 230 against the clamping groove 112 in a radial direction, so that the plug 200 and the joint 100 are less likely to fall out. Meanwhile, the protruding points 310 on the seal ring 300 come into contact with the two side surfaces of the first seal ring groove 130 and the second seal ring groove 140, to secure the position of the seal ring 300. The ring seal 300 is not prone to relative slippage when the quick insert structure is assembled, so that the cooperation is more reliable, the seal ring life is extended and the compression ratio and the seal ring fill rate are least affected by protruding points.

[023] When it is necessary to disconnect the plug from the joint, the clamping force F as shown in Fig. 3 is applied to the engagement portions 111 and the clamping grooves 112 expand in the direction of the short axis of the elliptical ring, that is, in the radial direction in Fig. 7. The clamping surface 240 is disengaged from the limiting surface 115, and the plug 200 can be pulled easily, allowing for convenient operation.

[024] Referring to Fig. 8, the application of the aforementioned quick insertion structure to the engine piping is described using the secondary air injection system as an example, but the quick insertion structure can also be applied to other connections engine tubing. The secondary air injection system comprises a secondary air injection pump 500 and a secondary air combination valve 600 which are connected via a hose 400. The quick insertion structure shown in Fig. 7 and between the hose is adopted 400 and the secondary air combination valve 600.

[025] Although the present utility model is described in combination with the above embodiments, the present utility model is not limited to the above described embodiments, but is only limited by claims. Those skilled in the art in an ordinary way can easily make changes and variations in the embodiments, without departing from the substantial concept and scope of the present utility model.

Claims (6)

1. Quick insertion structure, comprising a plug (200) and a gasket (100), CHARACTERIZED by the fact that the plug (200) has a tangent plane (220) that extends from an insertion end (210) of the plug (200) in an axial direction, an inclined surface (230) extending from a tail end of the tangent plane (220) and a clamping surface (240) extending from a tail end ( 232) of the inclined surface (230) in a radial direction; the joint (100) having a clamping claw (110) provided with a clamping groove (112) and an insertion groove (113), the clamping groove (112) has a limiting surface (115); when the plug (200) is inserted into the joint (100), the tangent plane (220) is inserted into the insertion groove (113), the clamping surface (240) cooperates with the limiting surface (115) and the axial length a starting from a starting end of the tangent plane (220) towards the clamping surface (240) is greater than the axial length from an initial length of the insertion groove (113) towards the limiting surface (115). 2. Quick insertion structure according to claim 1, CHARACTERIZED by still comprising a sealing ring (300), in which a groove in the sealing ring is formed in one position, surrounded by the clamping claw (110), in the gasket (100), and the seal ring (300) being located in the groove of the corresponding seal ring. 3. Quick insertion structure according to claim 1, CHARACTERIZED in that the sealing ring (300) has a plurality of projecting points (310) in the circumferential direction of the same, at intervals. Quick insertion structure according to claim 1, CHARACTERIZED that at least two sealing ring grooves are provided, wherein a sealing ring groove (130) is opposite the clamping groove (112), and the another sealing ring groove (140) deviates from the clamping groove (112) and is spaced from the insertion groove (113). 5. Quick insertion structure according to claim 1, CHARACTERIZED in that the clamping claw (110) is in the form of an elliptical ring, the clamping groove (112) is located on a short axis of the elliptical ring, the engaged portions (111) of the clamping jaw (110) are provided at both ends of a long axis of the elliptical ring and the clamping groove (112) expands in the direction of the short axis when the engagement portions (111) are compressed together. 6. Engine, CHARACTERIZED by the fact that the engine pipes are connected using the quick insertion structure, as defined in claim 1.

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