CN113276043A - Device for assembling cam position sensor - Google Patents

Abstract

The invention provides a device for assembling a cam position sensor, which comprises a base, a right positioning plate, a left positioning plate, an upper support frame group, a synchronous telescopic driving frame, an outer side fixing clamp plate, an upper driving piece and a clamping cylinder, wherein the upper support frame group is arranged on the base; two sides of the base are respectively and fixedly connected with an outer positioning seat; the right positioning plate is connected above the base in a sliding manner; the left positioning plate is also connected above the base in a sliding manner, and the left positioning plate is movably connected with the right positioning plate through a guide rod; the lower end of the synchronous telescopic driving frame is rotatably connected to the upper surface of the base through a bearing, and the synchronous telescopic driving frame is meshed with a right sensor clamping strip and a left sensor clamping strip of the right positioning plate and the left positioning plate; the outer side fixing splint is fixedly connected above the outer positioning seat through welding; the sensor is clamped and positioned through the sensor clamping strip and the outer side fixing clamp plate, the sensor is convenient to mount, and the left positioning plate and the right positioning plate synchronously position the sensor.

Description

Device for assembling cam position sensor

Technical Field

The invention belongs to the technical field of sensor assembling equipment, and particularly relates to a device for assembling a cam position sensor.

Background

The camshaft position sensor is a sensing device, also called synchronous signal sensor, and is a cylinder distinguishing and positioning device, and inputs camshaft position signals to an electronic control unit, and the camshaft position sensors are main control signals for ignition control. And the camshaft position sensor is used for acquiring a camshaft dynamic angle signal and inputting the camshaft dynamic angle signal into the electronic control unit so as to determine the ignition and oil injection time. For example, when the electronic control unit calculates the number of revolutions of the crankshaft of the engine based on the number of pulses per minute received from the crankshaft position sensor, the accuracy required when installing the cam position sensor is high.

For example, application No.: CN201820712637.7 discloses device of cam position sensor equipment, including position sensor installation body, shift knob, position sensor installation position, slide rail, platform support, supporting seat, shift knob locates the external surface of position sensor installation body, position sensor installation position passes through sliding rail connection position sensor installation body, position sensor installation body with the platform support place in on the supporting seat, a platform support's an upper surface mounting moving platform, the left side edge and the upside edge of platform support are carved with the scale, and moving platform's left side edge and upside edge connect the pointer, pass through a fix with screw cam mould on the moving platform.

Based on the search of the above patent and the structure discovery in combination with the prior art, when the sensor assembling equipment similar to that in the above patent is used for positioning the sensor, the positioning with the cam is not fast and firm enough, the production efficiency is low when the unilateral positioning and clamping are used for production, the bidirectional positioning operation is not convenient, and the operability requirement is high.

Disclosure of Invention

In order to solve the technical problems, the invention provides a device for assembling a cam position sensor, which is used for solving the problems that when sensor assembling equipment similar to the sensor assembling equipment in the patent is used for positioning a sensor, the positioning between the sensor and the cam is not fast and firm enough, the production efficiency is low when one-side positioning and clamping are carried out for production, bidirectional positioning operation is inconvenient, and the requirement on operability is high.

The invention relates to a device for assembling a cam position sensor, which has the purpose and the effect and is achieved by the following specific technical means:

a cam position sensor assembling device comprises a base, a right positioning plate, a left positioning plate, an upper support frame group, a synchronous telescopic driving frame, an outer side fixing clamp plate, an upper driving piece and a clamping cylinder; two sides of the base are respectively and fixedly connected with an outer positioning seat; the right positioning plate is connected above the base in a sliding manner; the left positioning plate is also connected above the base in a sliding manner, and the left positioning plate is movably connected with the right positioning plate through a guide rod; the lower end of the synchronous telescopic driving frame is rotatably connected to the upper surface of the base through a bearing, and the synchronous telescopic driving frame is meshed with a right sensor clamping strip and a left sensor clamping strip of the right positioning plate and the left positioning plate; the upper support frame group is rotatably connected to the upper end of the synchronous telescopic driving frame through a bearing; the outer side fixing splint is fixedly connected above the outer positioning seat through welding; the upper driving part is fixedly connected to the upper surface of the upper support frame group, and an output shaft of the upper driving part is meshed and connected with the upper end of a rear shaft of the synchronous telescopic driving frame through a gear; the clamping cylinder is fixedly connected to the outer positioning seat, and the outer end of a piston rod of the clamping cylinder is fixedly connected with the cam clamping plate.

Furthermore, the front end and the rear end of the upper surface of the base are respectively connected with a side guide frame through welding, and the inner side surface of the side guide frame is provided with a guide slide rail.

Furthermore, there are two right leading brackets through welded connection on the surface of right locating plate, and the terminal fixedly connected with of right leading bracket spring one, and the inboard of right locating plate is on the surface fixedly connected with two right telescopic rack, and on the internal surface of right telescopic rack perpendicular to right locating plate, the tooth piece of right telescopic rack forward, fixedly connected with right sensor clamping strip on the lateral surface of right locating plate, and there is a right side guide bar in both sides respectively through welded connection around the right locating plate.

Furthermore, there are two left leading truck of welding connection on the surface of left locating plate, and the outer end fixedly connected with spring two of left leading truck, and the inboard side of left locating plate is on the surface fixedly connected with two left telescopic rack, and the surface of the left sensor clamp strip perpendicular to left locating plate, and there is a left side guide bar in both sides around the left locating plate through welding connection respectively.

Further, go up the carriage group including last frame plate and lower frame plate, and the both ends of carriage group are gone up to the both ends fixedly connected with of lower frame plate, go up the frame plate and lie in the top of lower frame plate.

Furthermore, the synchronous telescopic driving frame is provided with two mutually parallel shafts, the lower side of the synchronous telescopic driving frame is fixedly connected with a synchronous rack drum of a drum structure, a synchronous belt wheel is fixedly connected above the synchronous rack drum, the two synchronous belt wheels are connected through a synchronous belt, and the upper end of the shaft of the synchronous telescopic driving frame at the rear side is fixedly connected with a driven gear.

Further, outside solid fixed splint are domes's support body, and outside solid fixed splint's inward flange is equipped with splint, and outside solid fixed splint's both ends are equipped with the folded plate, and the lower surface of the outside solid fixed splint of both sides is spring two and the spring one of right leading truck of left leading truck of fixed connection respectively to the outside solid fixed splint of both sides is sliding connection respectively on right leading truck and left leading truck.

Compared with the prior art, the invention has the following beneficial effects:

through the cooperation of the base of this structure and outside solid fixed splint, can see out, the effect of direction can be played with the right side guide bar of right locating plate and the left side guide bar sliding connection of left locating plate to the side guide frame of base, makes the directional sliding connection of right locating plate and left locating plate at the upper surface of base, and outside solid fixed splint plays the effect of supporting left locating plate and right locating plate, can cooperate left locating plate and right locating plate to press from both sides tight location to the sensor simultaneously.

Through the cooperation of the upper support frame group and the synchronous telescopic driving frame of the structure, an upper driving piece is arranged on the upper surface of the upper support frame group, the upper driving piece transmits torque to the rear shaft of the synchronous telescopic driving frame through gear transmission, the rear shaft of the synchronous telescopic driving frame drives the two shaft bodies to rotate towards the same rotation direction through belt transmission, and the upper support frame group also plays a role in positioning the synchronous telescopic driving frame.

Through the matching of the right positioning plate and the left positioning plate of the structure, when the synchronous telescopic driving frame rotates, the synchronous rack cylinder and the right telescopic rack form rack and pinion transmission to drive the right positioning plate to move towards the outer side or towards the inner side, the right positioning plate is also connected to the outer side fixing splint in a sliding way, self-guiding action is kept through two right guiding frames, when the sensor is clamped, the right positioning plate is moved outwards, clamping and positioning of the sensor are realized through the right sensor clamping strip and the outer side fixing splint, the sensor is convenient to install, when the synchronous telescopic driving frame rotates, the synchronous rack cylinder and the left telescopic rack form rack and pinion transmission to drive the left positioning plate to move towards the outer side or towards the inner side, the left positioning plate is also connected to the outer side fixing splint in a sliding way, self-guiding action is kept through two left guiding frames, when the sensor is clamped, the left positioning plate is moved outwards, the sensor is clamped and positioned through the left sensor clamping strip and the outer side fixing clamp plate, the sensor is convenient to mount, and the left positioning plate and the right positioning plate are used for positioning the sensor synchronously.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a front view of the present invention.

Fig. 3 is a right side view of the present invention.

FIG. 4 is a schematic view of the left positioning plate of the present invention.

FIG. 5 is a top view of the left positioning plate of the present invention.

Fig. 6 is a schematic structural view of the synchronous telescopic driving frame of the present invention.

Fig. 7 is a schematic view of the structure of the external fixation splint of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a base; 101. a side guide frame; 2. an outer positioning seat; 3. a right positioning plate; 301. a right guide frame; 3011. a first spring; 302. a right telescoping rack; 303. a right sensor clamping bar; 304. a right guide bar; 4. a left positioning plate; 401. a left guide frame; 4011. a second spring; 402. a left telescoping rack; 403. a left sensor clamping bar; 404. a left guide bar; 5. an upper support frame set; 501. an upper frame plate; 502. a lower frame plate; 6. the driving frame is synchronously telescopic; 601. a synchronous pulley; 602. a synchronous rack drum; 603. a synchronous belt; 604. a driven gear; 7. a splint is fixed on the outer side; 8. an upper drive member; 9. a clamping cylinder; 10. a cam cleat.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

As shown in figures 1 to 7:

the invention provides a device for assembling a cam position sensor, which comprises a base 1, a right positioning plate 3, a left positioning plate 4, an upper support frame group 5, a synchronous telescopic driving frame 6, an outer side fixing clamping plate 7, an upper driving piece 8 and a clamping cylinder 9, wherein the upper supporting frame group is fixedly arranged on the base; two sides of the base 1 are respectively fixedly connected with an outer positioning seat 2; the right positioning plate 3 is connected above the base 1 in a sliding manner; the left positioning plate 4 is also connected above the base 1 in a sliding way, and the left positioning plate 4 is movably connected with the right positioning plate 3 through a guide rod; the lower end of the synchronous telescopic driving frame 6 is rotatably connected to the upper surface of the base 1 through a bearing, and the synchronous telescopic driving frame 6 is meshed with the right sensor clamping strip 303 and the left sensor clamping strip 403 of the right positioning plate 3 and the left positioning plate 4; the upper support frame group 5 is rotatably connected to the upper end of the synchronous telescopic driving frame 6 through a bearing; the outer side fixing splint 7 is fixedly connected above the outer positioning seat 2 through welding; the upper driving part 8 is fixedly connected on the upper surface of the upper support frame group 5, and an output shaft of the upper driving part 8 is connected with the upper end of a rear shaft of the synchronous telescopic driving frame 6 through gear engagement; the clamping cylinder 9 is fixedly connected to the outer positioning seat 2, and the outer end of a piston rod of the clamping cylinder 9 is fixedly connected with a cam clamping plate 10.

The front end and the rear end of the upper surface of the base 1 are respectively connected with a side guide frame 101 through welding, and the inner side surface of the side guide frame 101 is provided with a guide slide rail, the base 1 of the structure is shown in fig. 1, the side guide frame 101 of the base 1 is connected with the right side guide rod 304 of the right positioning plate 3 and the left side guide rod 404 of the left positioning plate 4 in a sliding manner, so that the guide effect can be achieved, and the right positioning plate 3 and the left positioning plate 4 are connected to the upper surface of the base 1 in a directional sliding manner.

Wherein, the upper supporting frame set 5 comprises an upper frame plate 501 and a lower frame plate 502, and two ends of the lower frame plate 502 are fixedly connected with two ends of the upper supporting frame set 5, the upper frame plate 501 is positioned above the lower frame plate 502, the upper supporting frame set 5 of the structure is shown in fig. 6, the synchronous telescopic driving frame 6 has two parallel shafts, the lower side of the synchronous telescopic driving frame 6 is fixedly connected with a synchronous rack drum 602 with a cylindrical structure, the upper side of the synchronous rack drum 602 is fixedly connected with a synchronous pulley 601, the two synchronous pulleys 601 are connected through a synchronous belt 603, the upper end of the shaft of the synchronous telescopic driving frame 6 at the rear side is fixedly connected with a driven gear 604, the synchronous telescopic driving frame 6 of the structure is shown in fig. 6, an upper driving member 8 is arranged on the upper surface of the upper supporting frame set 5, the upper driving member 8 transmits torque to the rear side shaft of the synchronous telescopic driving frame 6 through gear transmission, the rear side shaft of the synchronous telescopic driving frame 6 drives the two shaft bodies to rotate towards the same rotation direction through belt transmission, the upper support frame group 5 also plays a role in positioning the synchronous telescopic driving frame 6.

Wherein, the outer surface of the right positioning plate 3 is connected with two right guide frames 301 through welding, the tail end of the right guide frame 301 is fixedly connected with a spring I3011, the inner surface of the right positioning plate 3 is fixedly connected with two right telescopic racks 302, the right telescopic racks 302 are vertical to the inner surface of the right positioning plate 3, the tooth block of the right telescopic racks 302 faces forwards, the outer side surface of the right positioning plate 3 is fixedly connected with a right sensor clamping strip 303, the front side and the back side of the right positioning plate 3 are respectively connected with a right guide rod 304 through welding, the right positioning plate 3 of the structure is shown in figure 4, when the synchronous telescopic driving frame 6 rotates, the synchronous rack tube 602 and the right telescopic racks 302 form gear rack transmission to drive the right positioning plate 3 to move towards the outside or towards the inside, the right positioning plate 3 is also connected with the outside fixing clamping plate 7 in a sliding way, the self-guiding function is kept through the two right guide frames 301, when clamping the sensor, through moving right locating plate 3 outward, press from both sides tight location through right sensor clamp strip 303 and outside solid fixed splint 7 realization to the sensor, be convenient for install the sensor.

Wherein, the outer surface of the left positioning plate 4 is connected with two left guide frames 401 by welding, the outer end of the left guide frame 401 is fixedly connected with a second spring 4011, the inner side surface of the left positioning plate 4 is fixedly connected with two left telescopic racks 402, the left sensor clamping strip 403 is vertical to the surface of the left positioning plate 4, the front and back sides of the left positioning plate 4 are respectively connected with a left guide rod 404 by welding, the left positioning plate 4 of the structure is as shown in figure 4, when the synchronous telescopic driving frame 6 rotates, the synchronous rack barrel 602 and the left telescopic rack 402 form gear rack transmission to drive the left positioning plate 4 to move outwards or inwards, the left positioning plate 4 is also connected with the outer side fixing clamp plate 7 in a sliding way, the self-guiding function is kept by the two left guide frames 401, when clamping the sensor, the clamping positioning of the sensor is realized by moving the left positioning plate 4 outwards, the left sensor clamping strip 403 and the outer side fixing clamp plate 7, be convenient for install the sensor, left locating plate 4 fixes a position the sensor with right locating plate 3 is synchronous.

Wherein, outside solid fixed splint 7 is domes's support body, and outside solid fixed splint 7's inward flange is equipped with splint, outside solid fixed splint 7's both ends are equipped with the folded plate, the lower surface of the outside solid fixed splint 7 of both sides is spring two 4011 of left leading truck 401 and spring one 3011 of right leading truck 301 of fixed connection respectively, and outside solid fixed splint 7 of both sides is sliding connection respectively on right leading truck 301 and left leading truck 401, the outside solid fixed splint 7 of this structure is shown in fig. 6, outside solid fixed splint 7 plays the effect of supporting left locating plate 4 and right locating plate 3, can cooperate left locating plate 4 and right locating plate 3 to press from both sides tight location to the sensor simultaneously.

When in use: firstly, an upper driving member 8 is arranged on the upper surface of an upper support frame group 5, the upper driving member 8 transmits torque to a rear shaft of a synchronous telescopic driving frame 6 through gear transmission, the rear shaft of the synchronous telescopic driving frame 6 drives two shaft bodies to rotate towards the same rotation direction through belt transmission, the upper support frame group 5 also plays a role in positioning the synchronous telescopic driving frame 6, when the synchronous telescopic driving frame 6 rotates, a synchronous rack cylinder 602 and a right telescopic rack 302 form gear rack transmission to drive a right positioning plate 3 to move towards the outer side or the inner side, the right positioning plate 3 is also connected on an outer side fixing clamp plate 7 in a sliding way, self-guiding function is kept through two right guide frames 301, when a sensor is clamped, the sensor is clamped and positioned through the outer right positioning plate 3 and the outer side fixing clamp plate 7 through a right sensor clamping strip 303, and the sensor is convenient to install, when the synchronous telescopic driving frame 6 rotates, the synchronous rack drum 602 and the left telescopic rack 402 form rack-and-pinion transmission to drive the left positioning plate 4 to move towards the outside or towards the inside, the left positioning plate 4 is also connected with the outside fixing clamp plate 7 in a sliding manner, the sensor is positioned by keeping self-guiding function through the two left guide frames 401, when the sensor is clamped, the sensor is clamped and positioned by moving the left positioning plate 4 outwards and the sensor clamping strip 403 and the outside fixing clamp plate 7, so that the sensor is convenient to install, the sensor is positioned by synchronously positioning the left positioning plate 4 and the right positioning plate 3, the side guide frame 101 of the base 1 is connected with the right guide rod 304 of the right positioning plate 3 and the left guide rod 404 of the left positioning plate 4 in a sliding manner, so that the right positioning plate 3 and the left positioning plate 4 are directionally and slidably connected on the upper surface of the base 1, and the outside fixing clamp plate 7 plays a role of supporting the left positioning plate 4 and the right positioning plate 3, and meanwhile, the sensor can be clamped and positioned by matching with the left positioning plate 4 and the right positioning plate 3.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (7)

1. A cam position sensor assembly apparatus, comprising: the device comprises a base (1), a right positioning plate (3), a left positioning plate (4), an upper support frame group (5), a synchronous telescopic driving frame (6), an outer side fixing clamp plate (7), an upper driving piece (8) and a clamping cylinder (9); two sides of the base (1) are respectively fixedly connected with an outer positioning seat (2); the right positioning plate (3) is connected above the base (1) in a sliding manner; the left positioning plate (4) is also connected above the base (1) in a sliding manner, and the left positioning plate (4) is movably connected with the right positioning plate (3) through a guide rod; the lower end of the synchronous telescopic driving frame (6) is rotatably connected to the upper surface of the base (1) through a bearing, and the synchronous telescopic driving frame (6) is meshed with a right sensor clamping strip (303) and a left sensor clamping strip (403) of the right positioning plate (3) and the left positioning plate (4); the upper support frame group (5) is rotatably connected to the upper end of the synchronous telescopic driving frame (6) through a bearing; the outer side fixing splint (7) is fixedly connected above the outer positioning seat (2) through welding; the upper driving part (8) is fixedly connected to the upper surface of the upper support frame group (5), and an output shaft of the upper driving part (8) is connected with the upper end of a rear shaft of the synchronous telescopic driving frame (6) through gear engagement; the clamping cylinder (9) is fixedly connected to the outer positioning seat (2), and the outer end of a piston rod of the clamping cylinder (9) is fixedly connected with a cam clamping plate (10).

2. A cam position sensor assembly apparatus as set forth in claim 1 wherein: the front end and the rear end of the upper surface of the base (1) are respectively connected with a side guide frame (101) through welding, and a guide sliding rail is arranged on the inner side surface of the side guide frame (101).

3. A cam position sensor assembly apparatus as set forth in claim 1 wherein: the utility model discloses a sensor fixing device, including right side locating plate (3), there are two right leading truck (301) on the surface of right side locating plate (3) through welded connection, and the terminal fixedly connected with of right leading truck (301) one spring (3011), the inboard of right side locating plate (3) is on the surface fixedly connected with two right telescopic rack (302), and on the internal surface of right telescopic rack (302) perpendicular to right locating plate (3), the tooth piece of right telescopic rack (302) is forward, the lateral surface of right side locating plate (3) is on fixedly connected with one right sensor of department and presss from both sides tight strip (303), there is a right side guide bar (304) both sides respectively through welded connection in the front and back of right side locating plate (3).

4. A cam position sensor assembly apparatus as set forth in claim 1 wherein: there are two left leading truck (401) on the surface of left side locating plate (4) through welded connection, and the outer end fixedly connected with spring two (4011) of left leading truck (401), and the inboard surface of left side locating plate (4) goes up fixedly connected with two left telescopic rack (402), and the surface of left sensor clamp strip (403) perpendicular to left locating plate (4), both sides are respectively through welded connection with left side guide bar (404) around left side locating plate (4).

5. A cam position sensor assembly apparatus as set forth in claim 1 wherein: go up the carriage group (5) including last frame plate (501) and lower frame plate (502), and the both ends of lower frame plate (502) fixedly connected with go up the both ends of carriage group (5), go up frame plate (501) and be located the top of lower frame plate (502).

6. A cam position sensor assembly apparatus as set forth in claim 1 wherein: the synchronous telescopic driving frame (6) is provided with two parallel shafts, a synchronous rack drum (602) with a cylindrical structure is fixedly connected to the lower side of the synchronous telescopic driving frame (6), a synchronous belt wheel (601) is fixedly connected to the upper side of the synchronous rack drum (602), the two synchronous belt wheels (601) are connected through a synchronous belt (603), and a driven gear (604) is fixedly connected to the upper end of the shaft of the synchronous telescopic driving frame (6) on the rear side.

7. A cam position sensor assembly apparatus as set forth in claim 1 wherein: outside solid fixed splint (7) are domes's support body, and the inward flange of outside solid fixed splint (7) is equipped with splint, and the both ends of outside solid fixed splint (7) are equipped with the folded plate, and the lower surface of the outside solid fixed splint (7) of both sides is spring two (4011) of left leading truck (401) of fixed connection respectively and spring one (3011) of right leading truck (301) to outside solid fixed splint (7) of both sides are sliding connection respectively on right leading truck (301) and left leading truck (401).

Images