CN114473438A - Mounting device for components in a heat exchanger of a motor vehicle - Google Patents

Abstract

The invention provides a mounting device for parts in a heat exchanger of a motor vehicle, which comprises a picking mechanism, a mounting mechanism and a control mechanism, wherein the picking mechanism is used for picking the parts and moving the parts into a pipe orifice on a flow passage plate in the heat exchanger; the turnover mechanism is used for turning over the runner plate so that the reverse side of the runner plate corresponds to the picking mechanism; the pressing mechanism comprises a press module and a first conveying module, the press module is arranged on the first conveying module and is positioned above the turnover mechanism, and the press module is matched with the pipe orifice under the conveying of the first conveying module and presses the part into the pipe orifice; the device utilizes tilting mechanism to overturn the runner plate to pick up the mechanism and install spare part in the mouth of pipe of runner plate with pushing down the mechanism, improve this installation device's installation effectiveness.

Description

Mounting device for components in a heat exchanger of a motor vehicle

Technical Field

The invention relates to the field of assembly of motor vehicles, in particular to a mounting device for parts in a heat exchanger of a motor vehicle.

Background

In the field of motor vehicle assembly, it is becoming more and more popular to assemble its parts through mechanical automation, for example: in a heat exchanger in a motor vehicle, a flow channel plate is used as a base plate, and various components such as valves are mounted on the flow channel plate. The two media flow separately in the flow passage plate, wherein the heat of one medium is transferred to the other medium to realize heat exchange.

In the process of installing various valves on the runner plate, the valves are required to be installed on the front surface and the back surface of the runner plate, when the valves are installed on the front surface of the runner plate, the valves can be directly installed in the pipe orifices of the runner plate, but when the valves are required to be installed on the back surface of the runner plate, how to efficiently install the valves is urgent.

Disclosure of Invention

In view of the above, the present invention provides a mounting apparatus for components in a heat exchanger of a motor vehicle, which uses the mutual cooperation among a pickup mechanism, a turnover mechanism, and a hold-down mechanism to efficiently perform the mounting of the components.

In order to solve the technical problems, the invention adopts the following technical scheme:

the mounting device for the parts in the heat exchanger of the motor vehicle according to the embodiment of the invention comprises:

a pick-up mechanism for picking up the parts and moving them into the ports on the flow passage plate in the heat exchanger;

the runner plate is positioned on the turnover mechanism, and the turnover mechanism is used for overturning the runner plate so that the reverse side of the runner plate corresponds to the picking mechanism;

the pressing mechanism comprises a pressing module and a first conveying module, the pressing module is installed on the first conveying module and is located above the turnover mechanism, and the pressing module is matched with the pipe orifice under the conveying of the first conveying module and presses the part into the pipe orifice.

Preferably, the pick-up mechanism comprises:

a pick head module for picking up the parts;

and the second conveying module is used for conveying the pick head module, and the pick head module moves the parts into the pipe orifice under the conveying of the second conveying module.

Preferably, the turnover mechanism includes:

a support frame;

the first driving module is fixedly arranged on the support frame;

the first carrier plate is connected with the first driving module and movably mounted on the support frame, the first carrier plate is used for bearing the runner plate, and a hollow area is arranged on the first carrier plate and used for avoiding the pipe orifice on the back surface of the runner plate;

the fixing module is used for fixing the runner plate on the first carrier plate, and the fixing module is installed on the first carrier plate so that the runner plate can rotate along with the first carrier plate under the driving force of the first driving module.

Preferably, the method further comprises the following steps:

the adjusting mechanism is used for adjusting the position of the first carrier plate, the adjusting mechanism is located below the supporting frame, the supporting frame is installed on the adjusting mechanism, and the runner plate is adjusted in multiple directions under the action of the adjusting mechanism so as to be matched with the press module.

Preferably, the adjusting mechanism comprises a first direction module, a second direction module and a third direction module, the support frame is installed on the first direction module, the first direction module is installed on the second direction module, the second direction module is installed on the third direction module, and the support frame moves along three different directions under the adjustment of the first direction module, the second direction module and the third direction module.

Preferably, the first direction module comprises:

a second carrier plate;

and one end of the lifting assembly is mounted on the second carrier plate, the other end of the lifting assembly is connected with the support frame, and the runner plate moves up and down along with the support frame under the action of the lifting assembly so as to be matched with the press module.

Preferably, the second direction module comprises a third carrier, a second driving assembly, a first slide rail and a first slide block, the first slide block is connected with the first slide rail in a sliding manner, the second driving assembly and the first slide rail are fixedly mounted on the third carrier, the first slide block is fixedly connected with the first direction module, and the first direction module reciprocates along the first slide rail direction along with the first slide block under the driving force of the second driving assembly; and

the third direction module comprises a third driving assembly, a second sliding rail and a second sliding block, the second sliding rail is connected with the second sliding block in a sliding mode, the second sliding block is fixedly connected with the third carrier plate, and the third carrier plate moves back and forth along the direction of the second sliding rail along with the second sliding block under the driving force of the third driving assembly.

Preferably, the method further comprises the following steps:

and the supporting mechanism is used for supporting the pressure generated when the pressing module presses the part, and is positioned below the supporting frame.

Preferably, the support mechanism includes a fourth driving assembly, a support rod, and a push-pull rod, the fourth driving assembly is fixedly mounted on the adjustment mechanism, the push-pull rod is connected to the fourth driving assembly, one end of the support rod is connected to the push-pull rod, and the support rod moves to the first support plate along with the push-pull rod under the driving force of the fourth driving assembly, so that the other end of the support rod is connected to the front surface of the runner plate.

Preferably, one end of the support rod, which is close to the first carrier plate, is provided with a positioning element, and when the support rod is connected to the front surface of the runner plate, the positioning element is structurally matched with the surface structure of the runner plate.

The technical scheme of the invention at least has one of the following beneficial effects:

the invention discloses an installation device for parts in a heat exchanger of a motor vehicle, which utilizes a turnover mechanism to turn a runner plate so as to enable a pickup mechanism to move the parts into a pipe orifice of the runner plate for pre-installation, and then utilizes a pressing mechanism to press the parts in the pipe orifice so as to complete the installation of the parts in the pipe orifice of the runner plate; the device utilizes tilting mechanism to overturn the runner plate to pick up mechanism and push down the mechanism and install spare part in the mouth of pipe of runner plate, improve this installation device's installation effectiveness.

Drawings

FIG. 1 is a schematic diagram of a prior art structure according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a pick-up mechanism for use in a mounting apparatus for a component in a heat exchanger of a motor vehicle according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a turnover mechanism, a support mechanism and an adjustment mechanism in a mounting device for components in a heat exchanger of a motor vehicle according to an embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3;

fig. 5 is a schematic structural diagram of a pressing mechanism in a mounting device for a component in a heat exchanger of a motor vehicle according to an embodiment of the present invention.

Reference numerals:

a. a runner plate; a1, nozzle;

10. a carrying mechanism; 20. a main transmission line; 30. a carrier; 40. a pickup mechanism; 410. a second transmission module; 420. a pickup head module;

50. a turnover mechanism; 510. a support frame; 511. a fourth carrier plate; 520. a first driving module; 530. a first carrier plate; 531. a hollowed-out area; 540. fixing the module;

60. a pressing mechanism; 611. a press assembly; 612. a pressure head; 620. a first transmission module; 630. a third transmission module; 640. a camera module;

70. an adjustment mechanism; 711. a second carrier plate; 712. a lifting assembly; 721. a first slide rail; 722. a third carrier plate; 731. a second slide rail; 732. a second slider; 810. a push-pull rod; 820. a support bar; 821. a positioning member.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the drawings of the embodiments of the present invention. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the description of the embodiments of the invention given above, are within the scope of protection of the invention.

In the assembly process of the heat exchanger of the motor vehicle, as shown in fig. 1, the carriers 30 are generally conveyed by a main conveyor line 20, the flow channel plate is mounted on the carriers 30, a plurality of assembly stations are provided on the main conveyor line 20, and an assembly device for assembling parts on the flow channel plate is provided at each assembly station. Typically, when it is desired to assemble the components to the front of the flow field plate, the components are mounted by moving the components directly to the flow field plate on the main conveyor line 20 using the handling mechanism 10. When the components are to be mounted on the reverse surface of the flow path plate, the flow path plate needs to be removed from the main transfer line 20.

The embodiment of the invention provides a mounting device for parts in a heat exchanger of a motor vehicle, which utilizes a turnover mechanism 50 to turn a runner plate moved away from a main transmission line 20 so that a picking mechanism 40 can move the picked parts to a pipe orifice a1 on the runner plate to pre-mount the parts, and then utilizes a press module to compress the parts positioned in a pipe orifice a 1.

First, a mounting device for components in a heat exchanger of a motor vehicle according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Specifically, as shown in fig. 2 to 5, the mounting device for components in a heat exchanger of a motor vehicle according to an embodiment of the present invention includes a picking mechanism 40, a turnover mechanism 50 and a pressing mechanism 60, wherein the picking mechanism 40 is used for picking up the components and moving the components into a nozzle a1 on a flow passage plate in the heat exchanger; the runner plate is positioned on the turnover mechanism 50, and the turnover mechanism 50 is used for turning over the runner plate so that the reverse side of the runner plate corresponds to the picking mechanism 40; the pressing mechanism 60 includes a press module mounted on the first transfer module 620 and a first transfer module 620, the press module is located above the turnover mechanism 50, and the press module matches the nozzle a1 under the transfer of the first transfer module 620 and presses the component into the nozzle a 1.

That is to say, the runner plate on the main conveying line 20 is moved onto the turnover mechanism 50, and is turned over by the turnover mechanism 50, so that the picking mechanism 40 moves the component to be mounted into the pipe orifice a1 of the runner plate, and the press module compresses the component in the pipe orifice a1, thereby completing the mounting of the component.

In one embodiment, as shown in fig. 2, the picking mechanism 40 includes a pick head module 420 and a second transfer module 410, the pick head module 420 is used for picking up the parts; the second transfer module 410 is used for transferring the pick head module 420, and the pick head module 420 moves the parts into the nozzle a1 under the transfer of the second transfer module 410. The pick-up mechanism 40 is preferably a multi-axis robot, although not limited thereto. The pick head module 420 is preferably a cylinder gripper module, although not limited thereto, such as: the parts can be picked up in an adsorption mode according to the structure of the product.

It should be noted that: when the parts picked up by the pick-up head module 420 are moved into the nozzle a1 of the runner plate, the parts can be pre-mounted by the pick-up head module 420 and the second transfer module 410, that is, an external force is applied to the parts, and the pre-mounting enables the parts to have a high matching degree with the nozzle a 1. Of course, when the component parts do not need to be pre-assembled, so that the component parts and the nozzle a1 have high matching degree, the pre-assembly is not needed. Whether or not the pre-installation is performed can be set according to the specific structure of the component and the nozzle a1, and the embodiment of the invention is not limited.

In an embodiment, as shown in fig. 3 and 4, the turnover mechanism 50 includes a supporting frame 510, a first driving module 520, a first carrier 530 and a fixing module 540, wherein the first driving module 520 is fixedly mounted on the supporting frame 510; a first carrier 530 is connected to the first driving module 520 and movably mounted on the supporting frame 510, the first carrier 530 is used for carrying the runner plate, a hollow area 531 is disposed on the first carrier 530, and the hollow area 531 is used for avoiding the pipe orifice a1 on the reverse side of the runner plate; the fixing module 540 is used to fix the runner plate on the first carrier 530, and the fixing module 540 is installed on the first carrier 530, so that the runner plate rotates along with the first carrier 530 under the driving force of the first driving module 520.

That is, after the flow channel plate is moved onto the first carrier 530, the flow channel plate is fixed on the first carrier 530 by the fixing module 540, and the fixing module 540 is preferably a cylinder clamp, but not limited thereto. The first driving module 520 is preferably a rotating motor module, but is not limited thereto.

The turnover mechanism 50 includes two support frames 510, the first carrier 530 is located between the two support frames 510, and the first carrier 530 performs a rotation motion under the driving force of the first driving module 520, so that the runner plate on the first carrier 530 is turned over. After the first carrier 530 is turned over as shown in fig. 4, the runner plate is located under the first carrier 530, and the pick head module 420 moves the picked component through the hollow area 531 to the nozzle a 1.

Further, as shown in fig. 3 and 4, the device further includes an adjusting mechanism 70, the adjusting mechanism 70 is used for adjusting the position of the first carrier plate 530, the adjusting mechanism 70 is located below the supporting frame 510, the supporting frame 510 is mounted on the adjusting mechanism 70, and the runner plate is adjusted in multiple directions under the action of the adjusting mechanism 70, so that the runner plate matches with the press module.

That is, after the pick-up head module 420 moves the components into the nozzle a1 of the runner plate, the position of the first carrier plate 530 is adjusted by the adjusting mechanism 70, so that the press module can precisely press the components into the nozzle a 1.

Further, as shown in fig. 3, the adjusting mechanism 70 includes a first direction module, a second direction module and a third direction module, the supporting frame 510 is installed on the first direction module, the first direction module is installed on the second direction module, the second direction module is installed on the third direction module, and the supporting frame 510 moves along three different directions under the adjustment of the first direction module, the second direction module and the third direction module.

That is, the position of the runner plate on the first carrier 530 is adjusted along the Z axis, the X axis and the Y axis in the coordinate system shown in fig. 3 under the transmission of the first direction module, the second direction module and the third direction module, so as to improve the matching degree between the components on the runner plate and the press module and further improve the mounting accuracy of the components.

Further, as shown in fig. 3 and 4, the first direction module includes a second carrier plate 711 and a lifting assembly 712, one end of the lifting assembly 712 is mounted on the second carrier plate 711, the other end of the lifting assembly 712 is connected to the supporting frame 510, and the runner plate moves up and down along with the supporting frame 510 under the action of the lifting assembly 712, so that the runner plate matches with the press module.

That is, the runner plate on the first carrier 530 moves along the Z-axis direction in the coordinate system shown in fig. 3 under the action of the lifting assembly 712, so as to reduce the distance between the runner plate and the press module, reduce the pressing distance of the press module, and further improve the press-fitting precision during the component mounting process.

The lifting assembly 712 is preferably a cylinder assembly, and a plurality of cylinder assemblies are uniformly distributed on the second carrier plate 711 to improve the stability of the first carrier plate 530 during movement.

Further, as shown in fig. 3, the second direction module includes a third carrier 722, a second driving assembly, a first sliding rail 721 and a first sliding block, the first sliding block is slidably connected to the first sliding rail 721, the second driving assembly and the first sliding rail 721 are fixedly mounted on the third carrier 722, the first sliding block is fixedly connected to the first direction module, and the first direction module reciprocates along the direction of the first sliding rail 721 along with the first sliding block under the driving force of the second driving assembly; and

the third direction module comprises a third driving assembly, a second slide rail 731 and a second slider 732, the second slide rail 731 is slidably connected to the second slider 732, the second slider 732 is fixedly connected to the third carrier 722, and the third carrier 722 reciprocates along the second slide rail 731 along with the second slider 732 under the driving force of the third driving assembly.

Because the first carrier 530 needs to rotate, there is a space for the first carrier 530 to rotate under it, and when the press module presses down on the components on the runner plate of the first carrier 530, only two ends of the first carrier 530 connected to the supporting frame 510 are stressed, which increases the pressure between the first carrier 530 and the supporting frame 510 and even reduces the mounting accuracy of the components.

In view of the above technical problem, as shown in fig. 3 and 4, a supporting mechanism is used to relieve the pressure generated by the first carrier plate 530 and the supporting frame 510 during the process of mounting the component, the supporting mechanism is used to support the pressure generated when the press module presses down the component, and the supporting mechanism is located below the supporting frame 510.

That is, before the press module presses down on the component on the flow channel plate, the support mechanism is moved to the lower side of the flow channel plate to support the component.

Further, as shown in fig. 3 and 4, the supporting mechanism includes a fourth driving assembly (not shown), a supporting rod 820 and a push-pull rod 810, the fourth driving assembly is fixedly mounted on the adjusting mechanism 70, the push-pull rod 810 is connected to the fourth driving assembly, one end of the supporting rod 820 is connected to the push-pull rod 810, the supporting rod 820 moves to the first carrier plate 530 along with the push-pull rod 810 under the driving force of the fourth driving assembly, so that the other end of the supporting rod 820 is connected to the front surface of the runner plate. The fourth drive assembly is preferably, but not limited to, a pneumatic cylinder drive assembly.

The fourth driving assembly is fixedly mounted on the second carrier plate 711, and the push-pull rod 810 reciprocates along the X-axis direction in the coordinate system shown in fig. 3 under the driving force of the fourth driving assembly to move the support rod 820 below the runner plate. When the press module presses down the parts on the flow channel plate, the support rod 820 and the support frame 510 bear the pressing force together, so that the stability of the press-fitting process is improved, and the press-fitting precision is further improved.

Furthermore, a positioning element 821 is disposed at one end of the support rod 820 close to the first carrier 530, and when the support rod 820 is connected to the front surface of the runner plate, the positioning element 821 is structurally matched with the surface structure of the runner plate.

That is, the positioning member 821 is configured to match the configuration of the position where it contacts the front surface of the flow path plate. Generally, the press module presses down only one part at a time, and the position of the support bar 820 contacting the front surface of the runner plate is opposite to the position of the pipe orifice a1 installed on the part, so as to improve the bearing pressure of the support bar 820 and further improve the stability of the press-fitting process.

In order to improve the stability of the first carrier 530 during the rotation process, the fourth carrier 511 is fixedly connected to the two supporting frames 510, and the fourth carrier 511 is located below the first carrier 530. A gap is formed on the fourth carrier 511 to prevent the fourth carrier 511 from blocking the movement of the supporting rod 820.

In one embodiment, as shown in fig. 5, the press module includes a press assembly 611 and a press head 612, the press head 612 is connected to the press assembly 611, and the press head 612 moves downward under the driving force of the press assembly 611, so that the press head 612 presses down on the component on the runner plate to press the component into the nozzle a 1. Press assembly 611 is preferably an electric press, although not limited thereto, which provides improved stability during press-fitting.

The pressing mechanism 60 further includes a third conveying module 630, and the pressing head 612 moves in different directions under the action of the first conveying module 620 and the third conveying module 630, so as to adjust the position of the pressing head 612, and further improve the matching accuracy of the pressing head 612 and the parts.

The pressing mechanism 60 further comprises a camera module 640, the camera module 640 is fixedly connected with the pressing head 612, the position of the pressing head 612 is adjusted by the first conveying module 620 and the third conveying module 630 based on the position of the part on the runner plate acquired by the camera, the matching precision of the pressing head 612 and the part is further improved, and the installation precision of the part is further improved. The first and third transfer modules 620, 630 are preferably linear motor modules, but are not limited thereto.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (10)

1. A mounting device for a component in a heat exchanger of a motor vehicle, comprising:

a pick-up mechanism (40) for picking up the parts and moving them into nozzles (a1) on a flow field plate (a) in the heat exchanger;

a turnover mechanism (50), wherein the runner plate (a) is positioned on the turnover mechanism (50), and the turnover mechanism (50) is used for turning over the runner plate (a) so that the reverse side of the runner plate (a) corresponds to the picking mechanism (40);

the pressing mechanism (60) comprises a pressing module and a first conveying module (620), the pressing module is mounted on the first conveying module (620), the pressing module is located above the turnover mechanism (50), and the pressing module is matched with the nozzle (a1) under the conveying of the first conveying module (620) and presses the part into the nozzle (a 1).

2. The mounting device for components inside a heat exchanger of a motor vehicle according to claim 1, wherein said pick-up mechanism (40) comprises:

a pick head module (420) for picking up the parts;

a second transfer module (410) for transferring the pick head module (420), the pick head module (420) moving the parts into the nozzle (a1) under transfer by the second transfer module (410).

3. The mounting device for components inside a heat exchanger of a motor vehicle according to claim 1 or 2, characterized in that said turnover mechanism (50) comprises:

a support frame (510);

the first driving module (520) is fixedly arranged on the supporting frame (510);

a first carrier (530) connected to the first driving module (520) and movably mounted on the support frame (510), wherein the first carrier (530) is used for carrying the runner plate (a), a hollow area (531) is arranged on the first carrier (530), and the hollow area (531) is used for avoiding the pipe orifice (a1) on the reverse side of the runner plate (a);

the fixing module (540) is used for fixing the runner plate (a) on the first carrier plate (530), and the fixing module (540) is installed on the first carrier plate (530) so that the runner plate (a) rotates along with the first carrier plate (530) under the driving force of the first driving module (520).

4. A mounting arrangement for a component in a heat exchanger of a motor vehicle as claimed in claim 3, further comprising:

the adjusting mechanism (70) is used for adjusting the position of the first carrier plate (530), the adjusting mechanism (70) is located below the supporting frame (510), the supporting frame (510) is installed on the adjusting mechanism (70), and the runner plate (a) is adjusted in multiple directions under the action of the adjusting mechanism (70) so as to enable the runner plate (a) to be matched with the press module.

5. The mounting device for the component in the heat exchanger of the motor vehicle as claimed in claim 4, wherein the adjusting mechanism (70) comprises a first direction module, a second direction module and a third direction module, the support frame (510) is mounted on the first direction module, the first direction module is mounted on the second direction module, the second direction module is mounted on the third direction module, and the support frame (510) moves in three different directions under the adjustment of the first direction module, the second direction module and the third direction module.

6. The mounting device for a component in a heat exchanger of a motor vehicle as set forth in claim 5, wherein said first direction module comprises:

a second carrier plate (711);

and one end of the lifting component (712) is mounted on the second carrier plate (711), the other end of the lifting component is connected with the support frame (510), and the runner plate (a) moves up and down along with the support frame (510) under the action of the lifting component (712), so that the runner plate (a) is matched with the press module.

7. The mounting device for the components in the heat exchanger of the motor vehicle as claimed in claim 5, wherein the second direction module comprises a third carrier plate (722), a second driving assembly, a first sliding rail (721) and a first sliding block, the first sliding block is slidably connected with the first sliding rail (721), the second driving assembly and the first sliding rail (721) are fixedly mounted on the third carrier plate (722), the first sliding block is fixedly connected with the first direction module, and the first direction module reciprocates along the first sliding rail (721) along the first sliding rail under the driving force of the second driving assembly; and

the third direction module comprises a third driving assembly, a second sliding rail (731) and a second sliding block (732), the second sliding rail (731) is connected with the second sliding block (732) in a sliding mode, the second sliding block (732) is fixedly connected with the third carrier plate (722), and the third carrier plate (722) reciprocates along the direction of the second sliding rail (731) along with the second sliding block (732) under the driving force of the third driving assembly.

8. The mounting device for a component in a heat exchanger of a motor vehicle as claimed in claim 4, further comprising:

a support mechanism for supporting a pressure generated when the press module presses down the component, the support mechanism being located below the support frame (510).

9. The mounting device for the components in the heat exchanger of the motor vehicle as claimed in claim 8, wherein the supporting mechanism comprises a fourth driving assembly, a supporting rod (820) and a push-pull rod (810), the fourth driving assembly is fixedly mounted on the adjusting mechanism (70), the push-pull rod (810) is connected with the fourth driving assembly, one end of the supporting rod (820) is connected with the push-pull rod (810), the supporting rod (820) moves to the first carrier plate (530) along with the push-pull rod (810) under the driving force of the fourth driving assembly, so that the other end of the supporting rod (820) is connected to the front surface of the flow passage plate (a).

10. The mounting device for components in a heat exchanger of a motor vehicle as claimed in claim 9, wherein an end of the support rod (820) near the first carrier plate (530) is provided with a positioning member (821), and the positioning member (821) is configured to match a surface structure of the flow channel plate (a) when the support rod (820) is coupled to the front surface of the flow channel plate (a).

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