CN217178115U - Low-temperature oxidation electrolysis device for automobile piston oil pump - Google Patents

Abstract

The utility model discloses a car piston oil pump low temperature oxidation electrolytic device, including base and device body, the base top is equipped with the movable groove, a plurality of spring groove has been seted up on the inner wall of movable groove bottom, the bottom of device body run through to the movable groove is connected with the fly leaf, the bottom of fly leaf is equipped with a plurality of bracing piece, the bottom of bracing piece is equipped with the supporting seat, the bottom center department of supporting seat is equipped with the stripper bar, the bottom of stripper bar run through to link together with the stripper plate in the spring groove, the bottom of stripper plate is equipped with spring one, the both sides of supporting seat are equipped with a movable rod one respectively, the other end swing joint of movable rod one has movable rod two. Has the beneficial effects that: through the interaction of the extrusion rod, the extrusion plate and the spring, the movable plate and the device body are jacked up, and power is provided for supporting the device body.

Description

Low-temperature oxidation electrolysis device for automobile piston oil pump

Technical Field

The utility model relates to the technical field of auto-parts, particularly, relate to an automobile piston oil pump low temperature oxidation electrolytic device.

Background

The oxidation electrolysis device of current car oil pump can cause the rocking of electrolysis device because jolting in the use, and then causes the damage of electrolysis device structure, and then influences electrolysis device's normal use, shortens electrolysis device's life.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

To the problem in the correlation technique, the utility model provides an automobile piston oil pump low temperature oxidation electrolytic device to overcome the above-mentioned technical problem that current correlation technique exists.

Therefore, the utility model discloses a specific technical scheme as follows:

a low-temperature oxidation electrolysis device for an automobile piston oil pump comprises a base and a device body, wherein a movable groove is formed in the top of the base, a plurality of spring grooves are formed in the inner wall of the bottom of the movable groove, the bottom end of the device body penetrates into the movable groove and is connected with a movable plate, a plurality of supporting rods are arranged at the bottom of the movable plate, a supporting seat is arranged at the bottom of each supporting rod, an extrusion rod is arranged at the center of the bottom of each supporting seat, the bottom end of each extrusion rod penetrates into the spring grooves and is connected with the extrusion plates, a first spring is arranged at the bottom of each extrusion plate, a first movable rod is arranged on each of two sides of each supporting seat, a second movable rod is movably connected to the other end of each first movable rod, the bottom end of each second movable rod is movably connected with the inner bottom of the corresponding movable groove, and a first-level damping mechanism is arranged between each first movable rod and the second movable rods, and a secondary damping mechanism is arranged between the second movable rod and the inner wall of the movable groove.

Preferably, the primary damping mechanism comprises a first groove located on the first movable rod, a first guide rod is arranged in the middle of the first groove, and a first movable block and a second spring are sleeved on the first guide rod.

Preferably, the first movable block and the second spring are extruded together, a first push rod is sleeved on the first movable block, the other end of the first push rod is connected with a first connecting seat, and the first connecting seat is arranged on the outer surface of the first movable rod.

Preferably, the second-stage damping mechanism comprises a second connecting seat located on the second movable rod and a second groove located on the inner wall of the movable groove, a second pushing rod is sleeved on the second connecting seat, and a second guide rod is arranged in the second groove.

Preferably, the second guide rod is sleeved with a second movable block and a third spring, the second movable block and the third spring are extruded together, and the other end of the second push rod is movably connected with the second movable block.

Preferably, the first spring, the second spring and the third spring are all compression springs, and spring washers are arranged at the end parts of the first spring, the second spring and the third spring.

The beneficial effects of the utility model are that: the movable plate and the device body are jacked up through the interaction of the extrusion rod, the extrusion plate and the spring, and power is provided for the support of the device body;

through the design of the primary damping mechanism and the secondary damping mechanism, a supporting force is provided for the first movable rod and the second movable rod, so that when the device body is under pressure, the movable plate is helped to absorb the pressure brought by the device body;

through the design of the first guide rod and the second guide rod, the stability and the reliability of the movement of the first movable block and the second movable block are improved, meanwhile, the second spring and the third spring are stressed uniformly, and the service life of the second spring and the third spring is prolonged.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic diagram of the general structure of an automotive piston oil pump low-temperature oxidation electrolysis device according to an embodiment of the present invention;

FIG. 2 is a schematic view of the internal structure of a base of a low-temperature oxidation electrolysis device for an automotive piston oil pump according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a primary damping mechanism of a low-temperature oxidation electrolysis device of an automobile piston oil pump according to an embodiment of the present invention;

fig. 4 is a structural schematic diagram of a secondary damping mechanism of a low-temperature oxidation electrolysis device of an automobile piston oil pump according to an embodiment of the utility model.

In the figure:

1. a base; 2. a device body; 3. a movable groove; 4. a movable plate; 5. a support bar; 6. a supporting seat; 7. A first movable rod; 8. a second movable rod; 9. an extrusion stem; 10. a spring slot; 11. a pressing plate; 12. a first spring; 13. a first groove; 14. a first guide rod; 15. a first movable block; 16. a second spring; 17. a first push rod; 18. A first connecting seat; 19. a second connecting seat; 20. a second push rod; 21. a second groove; 22. a second guide rod; 23. a second movable block; 24. and a third spring.

Detailed Description

For further explanation of the embodiments, the drawings are provided as part of the disclosure and serve primarily to illustrate the embodiments and, together with the description, to explain the principles of operation of the embodiments, and to provide further explanation of the invention and advantages thereof, it will be understood by those skilled in the art that various other embodiments and advantages of the invention are possible, and that elements in the drawings are not to scale and that like reference numerals are generally used to designate like elements.

According to the embodiment of the utility model, a car piston oil pump low temperature oxidation electrolytic device is provided.

Embodiment one, as shown in fig. 1 to 4, a low-temperature oxidation electrolysis device for an automotive piston oil pump according to an embodiment of the present invention includes a base 1 and a device body 2, wherein a movable groove 3 is disposed at the top of the base 1, a plurality of spring grooves 10 are disposed on an inner wall of the bottom of the movable groove 3, the bottom of the device body 2 penetrates into the movable groove 3 and is connected with a movable plate 4, a plurality of support rods 5 are disposed at the bottom of the movable plate 4, a support base 6 is disposed at the bottom of each support rod 5, a squeeze rod 9 is disposed at the center of the bottom of the support base 6, the bottom of the squeeze rod 9 penetrates into the spring grooves 10 and is connected with a squeeze plate 11, a first spring 12 is disposed at the bottom of the squeeze plate 11, a first movable rod 7 is disposed at each of two sides of the support base 6, and a second movable rod 8 is movably connected to the other end of the first movable rod 7, the bottom of the second movable rod 8 is movably connected with the inner bottom of the movable groove 3, a first damping mechanism is arranged between the first movable rod 7 and the second movable rod 8, and a second damping mechanism is arranged between the second movable rod 8 and the inner wall of the movable groove 3.

Embodiment two, as shown in fig. 1-4, a low-temperature oxidation electrolysis device for an automotive piston oil pump according to an embodiment of the present invention includes a base 1 and a device body 2, wherein a movable groove 3 is disposed on a top of the base 1, a plurality of spring grooves 10 are disposed on an inner wall of a bottom of the movable groove 3, a bottom end of the device body 2 penetrates into the movable groove 3 and is connected to a movable plate 4, a plurality of support rods 5 are disposed at a bottom of the movable plate 4, a support base 6 is disposed at a bottom of each support rod 5, a squeeze rod 9 is disposed at a center of a bottom of the support base 6, a bottom end of the squeeze rod 9 penetrates into the spring grooves 10 and is connected to a squeeze plate 11, a first spring 12 is disposed at a bottom of the squeeze plate 11, a first movable rod 7 is disposed on each of two sides of the support base 6, and a second movable rod 8 is movably connected to another end of the first movable rod 7, the bottom of movable rod two 8 with the interior bottom swing joint of activity groove 3, movable rod one 7 with be equipped with one-level damper between the movable rod two 8, movable rod two 8 with be equipped with second grade damper between the 3 inner walls of activity groove, one-level damper is including being located recess one 13 on the movable rod one 7, the middle part of recess one 13 is equipped with guide arm one 14, the cover is equipped with movable block one 15 and spring two 16 on the guide arm one 14, movable block one 15 with both extrudees together of spring two 16, the cover is equipped with catch bar one 17 on the movable block one 15, the other end and connecting seat one 18 of catch bar one 17 are connected, connecting seat one 18 sets up two 8 surfaces of movable rod. As can be seen from the above design, the primary damping mechanism provides a supporting force to the first and second movable rods 7 and 8, so as to help the movable plate 4 absorb the pressure from the device body 2 when the device body 2 is under pressure.

Embodiment three, as shown in fig. 1 to 4, a low-temperature oxidation electrolysis device for an automotive piston oil pump according to an embodiment of the present invention includes a base 1 and a device body 2, wherein a movable groove 3 is disposed at the top of the base 1, a plurality of spring grooves 10 are disposed on an inner wall of the bottom of the movable groove 3, the bottom of the device body 2 penetrates into the movable groove 3 and is connected to a movable plate 4, a plurality of support rods 5 are disposed at the bottom of the movable plate 4, a support base 6 is disposed at the bottom of each support rod 5, a squeeze rod 9 is disposed at the center of the bottom of the support base 6, the bottom of the squeeze rod 9 penetrates into the spring grooves 10 and is connected to a squeeze plate 11, a first spring 12 is disposed at the bottom of the squeeze plate 11, a first movable rod 7 is disposed at each of two sides of the support base 6, and a second movable rod 8 is movably connected to the other end of the first movable rod 7, the bottom of movable rod two 8 with the interior bottom swing joint of movable groove 3, movable rod one 7 with be equipped with one-level damper between the movable rod two 8, movable rod two 8 with be equipped with second grade damper between the 3 inner walls of movable groove, second grade damper is including being located connecting seat two 19 on the movable rod two 8 and recess two 21 on the 3 inner walls of movable groove, the cover is equipped with catch bar two 20 on connecting seat two 19, be equipped with guide arm two 22 in the recess two 21, the cover is equipped with two 23 and three 24 of spring of movable block on the guide arm two 22, two 23 of movable block with three 24 of spring are together extruded, the other end of catch bar two 20 with two 23 swing joint of movable block. As can be seen from the above design, through the design of the primary damping mechanism and the secondary damping mechanism, a supporting force is provided for the first movable rod and the second movable rod, and a supporting force is provided for the first movable rod 7 and the second movable rod 8, so as to help the movable plate 4 absorb the pressure from the device body 2 when the device body 2 is under pressure.

Fourth embodiment, as shown in fig. 1 to 4, a low-temperature oxidation electrolysis apparatus for an automotive piston oil pump according to an embodiment of the present invention includes a base 1 and an apparatus body 2, wherein a movable groove 3 is disposed at a top of the base 1, a plurality of spring grooves 10 are disposed on an inner wall of a bottom of the movable groove 3, a bottom end of the apparatus body 2 penetrates into the movable groove 3 and is connected to a movable plate 4, a plurality of support rods 5 are disposed at a bottom of the movable plate 4, a support base 6 is disposed at a bottom of each support rod 5, a squeeze rod 9 is disposed at a center of a bottom of the support base 6, a bottom end of the squeeze rod 9 penetrates into the spring grooves 10 and is connected to a squeeze plate 11, a first spring 12 is disposed at a bottom of the squeeze plate 11, a first movable rod 7 is disposed at each of two sides of the support base 6, and a second movable rod 8 is movably connected to another end of the first movable rod 7, the bottom of movable rod two 8 with the interior bottom swing joint of activity groove 3, movable rod one 7 with be equipped with one-level damper between the movable rod two 8, movable rod two 8 with be equipped with second grade damper between the 3 inner walls of activity groove, spring one 12 spring two 16 and spring three 24 three is compression spring, spring one 12 spring two 16 and spring three 24 three's tip all is equipped with spring washer. It can be seen from the above design that the service life of both the first spring 12 and the second spring 16 is improved by the design of the spring washer.

For the convenience of understanding the technical solution of the present invention, the following detailed description is made on the working principle or the operation mode of the present invention in the practical process.

In summary, with the above technical solution of the present invention, when the device body 2 is vibrated, the device body 2 can perform a small-scale damping movement on the base 1 to counteract the pressure caused by the vibration, the base 1 drives the movable plate 4 to move up and down in the movable groove 3, the movable plate 4 drives the supporting rod 5 to move synchronously, the supporting rod 5 drives the movable rod one 7 and the extruding rod 9 to move synchronously through the supporting seat 6, the extruding rod 9 drives the extruding plate 11 to descend to extrude the first spring 12, the movable rod one 7 drives the movable rod two 8 to move, the movable rod one 7 and the movable rod two 8 move relatively to extrude the first-stage damping mechanism and the second-stage damping mechanism, the first pushing rod 17 in the first-stage damping mechanism pushes the first moving block 15 to move the second synchronous extruding spring 16 on the first guide rod 14, and the second pushing rod 20 in the second-stage damping mechanism pushes the second moving block 23 to move the third extruding spring 24 on the second guide rod 22, the telescopic movement of the first spring 12, the second spring 16 and the third spring 24 helps the device body 2 to absorb the external pressure.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The low-temperature oxidation electrolysis device for the automobile piston oil pump is characterized by comprising a base (1) and a device body (2), wherein a movable groove (3) is formed in the top of the base (1), a plurality of spring grooves (10) are formed in the inner wall of the bottom of the movable groove (3), the bottom end of the device body (2) penetrates into the movable groove (3) and is connected with a movable plate (4), a plurality of supporting rods (5) are arranged at the bottom of the movable plate (4), a supporting seat (6) is arranged at the bottom of each supporting rod (5), an extrusion rod (9) is arranged at the center of the bottom of each supporting seat (6), the bottom end of each extrusion rod (9) penetrates into the corresponding spring groove (10) and is connected with an extrusion plate (11), a first spring (12) is arranged at the bottom of each extrusion plate (11), a first movable rod (7) is arranged on each of two sides of each supporting seat (6), the other end swing joint of movable rod one (7) has movable rod two (8), the bottom of movable rod two (8) with the interior bottom swing joint of activity groove (3), movable rod one (7) with be equipped with one-level damper between movable rod two (8), movable rod two (8) with be equipped with second grade damper between activity groove (3) inner wall.

2. The low-temperature oxidation electrolysis device for the automobile piston oil pump according to claim 1, wherein the primary damping mechanism comprises a first groove (13) located on the first movable rod (7), a first guide rod (14) is arranged in the middle of the first groove (13), and a first movable block (15) and a second spring (16) are sleeved on the first guide rod (14).

3. The low-temperature oxidation electrolysis device for the automobile piston oil pump according to claim 2, wherein the first movable block (15) and the second spring (16) are extruded together, a first pushing rod (17) is sleeved on the first movable block (15), the other end of the first pushing rod (17) is connected with a first connecting seat (18), and the first connecting seat (18) is arranged on the outer surface of the second movable rod (8).

4. The low-temperature oxidation electrolysis device for the automobile piston oil pump according to claim 3, wherein the secondary damping mechanism comprises a second connecting seat (19) located on the second movable rod (8) and a second groove (21) located on the inner wall of the movable groove (3), the second connecting seat (19) is sleeved with a second pushing rod (20), and a second guide rod (22) is arranged in the second groove (21).

5. The low-temperature oxidation electrolysis device for the automobile piston oil pump according to claim 4, wherein a second movable block (23) and a third spring (24) are sleeved on the second guide rod (22), the second movable block (23) and the third spring (24) are extruded together, and the other end of the second push rod (20) is movably connected with the second movable block (23).

6. The low-temperature oxidation electrolysis device for the automobile piston oil pump according to claim 5, wherein the first spring (12), the second spring (16) and the third spring (24) are compression springs, and spring washers are arranged at the end parts of the first spring (12), the second spring (16) and the third spring (24).

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