CN112775385A

CN112775385A - Upper die changing mechanism of double-station riveting press

Info

Publication number: CN112775385A
Application number: CN202110157752.9A
Authority: CN
Inventors: 李冰; 刘勇
Original assignee: Rate Precision Tooling Co ltd
Current assignee: Rate Precision Tooling Co ltd
Priority date: 2021-02-04
Filing date: 2021-02-04
Publication date: 2021-05-11

Abstract

The invention provides an upper die changing mechanism of a double-station riveting press, which comprises a first station feeding main body, a second station feeding main body, a front and back mounting base plate, a left and right translation mechanism, a front and back translation mechanism and a connecting assembly connected with the riveting press, wherein the first station feeding main body and the second station feeding main body are respectively and fixedly connected with the front and back mounting base plate, the front and back mounting base plate is connected with the left and right mounting base plate through a front and back guide rail slider mechanism, the front and back translation mechanism is connected with the front and back mounting base plate, the left and right translation mechanism is respectively connected with the left and right mounting base plate and the connecting assembly, and the left and right mounting base plate is connected with the connecting assembly through. The invention has the beneficial effects that: the double-station switching is realized, the riveting press of two rivets with different specifications can be compatible, the efficiency is improved, and the universality is improved.

Description

Upper die changing mechanism of double-station riveting press

Technical Field

The invention relates to a squeeze riveter, in particular to an upper die changing mechanism of a double-station squeeze riveter.

Background

The traditional squeeze riveter is of a single-station structure, can only be suitable for squeeze riveting of rivets of one specification, needs to adapt to rivets of another specification by replacing an upper die, and is low in squeeze riveting efficiency and low in universality.

Disclosure of Invention

In order to solve the problems in the prior art, the invention provides an upper die changing mechanism of a double-station riveting press.

The invention provides an upper die changing mechanism of a double-station riveting press, which comprises a first station feeding main body, a second station feeding main body, a front and back mounting base plate, a left and right translation mechanism, a front and back translation mechanism and a connecting assembly connected with the riveting press, wherein the first station feeding main body and the second station feeding main body are respectively and fixedly connected with the front and back mounting base plate, the front and back mounting base plate is connected with the left and right mounting base plate through a front and back guide rail slider mechanism, the front and back translation mechanism is connected with the front and back mounting base plate, the left and right translation mechanism is respectively connected with the left and right mounting base plate and the connecting assembly, the left and right mounting base plate is connected with the connecting assembly through a left and right guide rail slider mechanism, the front and back translation mechanism drives the first station feeding main body and the second feeding main body, the riveting station comprises an execution station collinear with a Z-axis pressure head of the riveting press and an non-execution station not collinear with the Z-axis pressure head of the riveting press, and the left-right translation mechanism drives the first station feeding main body or the second station feeding main body located at the riveting press to reach the execution station.

As a further improvement of the present invention, the left-right translation mechanism includes a left-right cylinder and a left-right cylinder connecting plate, the cylinder bodies of the left-right cylinder are fixed on the left-right mounting base plate, and the piston rods of the left-right cylinder are connected with the connecting assembly through the left-right cylinder connecting plate.

As a further improvement of the present invention, the left and right cylinders are biaxial cylinders.

As a further improvement of the invention, the connecting assembly comprises a feeder adjusting plate, a feeder adjusting block and a connector, wherein an adjusting groove is formed in the feeder adjusting block, the feeder adjusting plate is arranged in the adjusting groove and is in sliding fit with the adjusting groove, the feeder adjusting plate is connected with the feeder adjusting block through an adjusting bolt in a locking mode, the feeder adjusting block is connected with the connector, and the bottom of the feeder adjusting plate is fixedly connected with the left and right cylinder connecting plates.

As a further improvement of the invention, the bottom of the feeder adjusting plate is connected with the left and right mounting base plates through a left and right guide rail slide block mechanism.

As a further improvement of the invention, the front-back translation mechanism comprises a front-back air cylinder, a front-back air cylinder connecting block and a front-back air cylinder mounting plate, the front-back air cylinder mounting plate is fixed on the left-right mounting base plate, the cylinder body of the front-back air cylinder is fixedly connected with the front-back air cylinder mounting plate through the front-back air cylinder connecting block, and the piston rod of the front-back air cylinder is fixedly connected with the front-back mounting base plate.

As a further improvement of the present invention, left and right limiting protrusions are respectively disposed at left and right ends above the left and right mounting substrates, the connecting assembly is located between the left and right limiting protrusions, a front and rear limiting groove is disposed below the left and right mounting substrates, and the front and rear mounting substrates are disposed within the front and rear limiting groove.

As a further improvement of the invention, the first station feeding main body and the second station feeding main body are arranged in parallel left and right, and the first station feeding main body and the second station feeding main body are respectively installed on the front and rear installation substrates through positioning pins and positioning holes.

As a further improvement of the invention, the front end of the first station feeding main body is provided with a first station placing groove, a second station placing groove is arranged at the front end of the second station feeding main body, a first station feeding pipe and a second station feeding pipe are arranged at the front ends of the left and right mounting base plates, the first station feeding pipe is matched with the first station placing groove of the first station feeding main body, the second station feeding pipe is matched with a second station placing groove of the second station feeding main body, when the front-back translation mechanism drives the first station feeding main body and the second station feeding main body to be positioned at the feeding station, the first station feeding pipe is communicated with a first station placing groove of the first station feeding main body, the second station feeding pipe is communicated with a second station placing groove of the second station feeding main body.

As a further improvement of the invention, the first station feeding pipe is connected with the first tray through a first hose, and the second station feeding pipe is connected with the second tray through a second hose.

The invention has the beneficial effects that: by the scheme, double-station switching is realized, the riveting press of two rivets with different specifications can be compatible, the efficiency is improved, and the universality is improved.

Drawings

Fig. 1 is an exploded schematic view of an upper die changing mechanism of a double-station squeeze riveter.

Fig. 2 is a schematic diagram of an upper die changing mechanism of the double-station squeeze riveter in the feeding process.

Fig. 3 is a schematic diagram of the first station feeding main body of the upper die changing mechanism of the double-station squeeze riveter during squeeze riveting.

Fig. 4 is a schematic diagram of the second station feeding main body of the upper die changing mechanism of the double-station squeeze riveter during squeeze riveting.

Fig. 5 is a schematic view of an upper die changing mechanism of the double-station squeeze riveter in the feeding process.

Fig. 6 is a partial enlarged view of a first station feeding main body and a second station feeding main body of an upper die changing mechanism of the double-station squeeze riveter.

Detailed Description

The invention is further described with reference to the following description and embodiments in conjunction with the accompanying drawings.

As shown in fig. 1 to 6, an upper die changing mechanism 1 of a double-station squeeze riveter comprises a first station feeding main body 18, a second station feeding main body 19, a front and rear mounting base plate 17, a left and right mounting base plate 16, a left and right translation mechanism, a front and rear translation mechanism and a connecting assembly connected with the squeeze riveter, wherein the first station feeding main body 18 and the second station feeding main body 19 are respectively and fixedly connected with the front and rear mounting base plate 17, and the front and rear mounting base plate 17 and the left and right mounting base plate 16 are connected through a front and rear guide rail slider mechanism 14, so that the front and rear mounting base plate 17 can perform front and rear translation sliding relative to the left and right mounting base plate 16, and the first station feeding main body 18 and the second station feeding main body 19 are driven to perform front.

The front-rear translation mechanism is connected to the front-rear mounting substrate 17.

The left and right translation mechanism is respectively connected with the left and right mounting base plates 16 and the connecting assembly, the left and right mounting base plates 16 are connected with the connecting assembly through the left and right guide rail sliding block mechanisms 13, so that the left and right mounting base plates 16 can perform left and right translation sliding relative to the connecting assembly.

The front-back translation mechanism drives the first station feeding main body 18 and the second station feeding main body 19 to switch between a feeding station and a riveting station, the riveting station comprises an execution station collinear with a Z-axis pressure head of a riveting press and an non-execution station not collinear with the Z-axis pressure head of the riveting press, and the left-right translation mechanism drives the first station feeding main body 18 or the second station feeding main body 19 located on the riveting press to reach the execution station, namely, one of the first station feeding main body 18 and the second station feeding main body 19 executes riveting under the Z-axis pressure head of the riveting press.

Control translation mechanism including control cylinder 110 and control cylinder connecting plate 11, control cylinder connecting plate 11 and be the L type, control cylinder 110's cylinder body and fix about on the mounting substrate 16, control cylinder 110's piston rod pass through control cylinder connecting plate 11 with coupling assembling connects.

The left and right cylinders 110 are preferably biaxial cylinders.

Coupling assembling includes feeder regulating plate 12, feeder regulating block 114 and connector 115, be equipped with on the feeder regulating block 114 and adjust recess 1141, feeder regulating plate 12 sets up in adjusting recess 1141 and with adjust recess 1141 sliding fit, feeder regulating plate 12 with feeder regulating block 114 is through adjusting bolt lock connection, and the height of installing base plate 16 about the accessible is adjusted feeder regulating plate 12, feeder regulating block 114 locking position between them.

The feeder adjusting block 114 is connected with the connector 115, the connector 115 is connected with the squeeze riveter, and the bottom of the feeder adjusting plate 12 is fixedly connected with the left and right cylinder connecting plates 11.

The feeder adjusting plate 114 is connected at its bottom to the left and right mounting boards 16 via left and right rail slider mechanisms 13.

Front and back translation mechanism includes front and back cylinder 113, front and back cylinder connecting block 112 and front and back cylinder mounting panel 111, front and back cylinder mounting panel 111 is fixed on controlling mounting substrate 16, front and back cylinder 113's cylinder body passes through front and back cylinder connecting block 112 with front and back cylinder mounting panel 111 fixed connection, front and back cylinder 113's piston rod with preceding rear mounting substrate 17 fixed connection.

Spacing lug 1162 about both ends are equipped with respectively about controlling mounting substrate 116's top, feeder regulating plate 114 is located about two between the spacing lug 1162, about the below of mounting substrate 116 is equipped with spacing recess 1161 around, mounting substrate 17 sets up around within spacing recess 1161 for spacing around.

Parallel arrangement about first station pay-off main part 18, the second station pay-off main part 19, first station pay-off main part 18, the second station pay-off main part 19 are installed through locating pin and locating hole respectively around on the mounting substrate 17, first station pay-off main part 18, the second station pay-off main part 19 are pay-off main part hinge structure.

A first station placing groove 181 is arranged at the front end of the first station feeding main body 18, a second station placing groove 191 is arranged at the front end of the second station feeding main body 19, the front ends of the left and right mounting base plates 16 are provided with a first station feeding pipe 15 and a second station feeding pipe 16, the first station feeding pipe 15 is matched with the first station placing groove 181 of the first station feeding main body 18, the second station feeding pipe 16 is matched with the second station placing groove 191 of the second station feeding main body 19, when the front and rear cylinders 113 drive the first station feeding main body 18 and the second station feeding main body 19 to be positioned at the feeding station, the first station feeding pipe 15 is communicated with the first station placing groove 181 of the first station feeding main body 18, the second station feeding pipe 16 is communicated with the second station placing groove 191 of the second station feeding main body 19.

The first station feeding pipe 15 is connected with a first tray through a first hose 117, and the second station feeding pipe 16 is connected with a second tray through a second hose 118.

The front and rear air cylinders 113 are preferably pen-shaped air cylinders, and the first hose 117 and the second hose 118 are both made of PU tubes.

The invention provides an upper die changing mechanism 1 of a double-station riveting press, which has the following working principle:

when the rivets with the first specification are fed, the front cylinder 113 and the rear cylinder 113 contract, the front mounting base plate 17 and the rear mounting base plate 17 drive the first station feeding main body 18 and the second station feeding main body 19 to synchronously retreat to a feeding station, the rivets with the first specification on the first material plate are fed into the first station placing groove 181 of the first station feeding main body 18 through the first hose 117 and the first station feeding pipe 15, feeding is completed, and the feeding mode can adopt an air blowing mode;

when rivets with a first specification are riveted, the front and rear cylinders 113 extend out, the front and rear mounting substrates 17 extend out to drive the first station feeding main body 18 and the second station feeding main body 19 to synchronously advance to a riveting station, the front and rear cylinders 113 extend out, and the left and right mounting substrates 16 drive the first station feeding main body 18 to move to an execution station, so that the first station placing groove 181 of the first station feeding main body 18 is collinear with a Z-axis pressing head of a riveting machine, and a pressing head of a cylinder driving shaft of the riveting machine is pressed downwards to finish riveting;

when the rivets with the second specification are fed, the front cylinder 113 and the rear cylinder 113 contract, the front mounting base plate 17 and the rear mounting base plate 17 drive the first station feeding main body 18 and the second station feeding main body 19 to synchronously retreat to a feeding station, the rivets with the second specification on a second material disc are fed into the second station placing groove 191 of the second station feeding main body 19 through the second hose 118 and the second station feeding pipe 16, feeding is completed, and the feeding mode can adopt an air blowing mode;

when rivets of a second specification are riveted, the front and rear cylinders 113 extend out, the front and rear mounting substrates 17 extend out to drive the first station feeding main body 18 and the second station feeding main body 19 to synchronously advance to the riveting station, the front and rear cylinders 113 extend out, and the left and right mounting substrates 16 drive the second station feeding main body 19 to move to the execution station, so that the second station placing groove 191 of the second station feeding main body 19 is collinear with a Z-axis pressing head of the riveting machine, and a pressing head of a cylinder driving shaft of the riveting machine is pressed downwards to complete riveting.

The upper die changing mechanism of the double-station riveting press provided by the invention can realize the press riveting of two rivets with different specifications, and improves the processing efficiency.

The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the invention be limited to these specific details. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.

Claims

1. The utility model provides an last mould die change mechanism of duplex position squeeze riveter which characterized in that: the riveting machine comprises a first station feeding main body, a second station feeding main body, a front mounting substrate, a rear mounting substrate, a left mounting substrate, a right mounting substrate, a left translation mechanism, a right translation mechanism, a front translation mechanism and a rear translation mechanism, and a connecting assembly connected with a riveting machine, wherein the first station feeding main body and the second station feeding main body are respectively fixedly connected with the front mounting substrate and the rear mounting substrate, the front mounting substrate and the rear mounting substrate are connected with the left mounting substrate and the right mounting substrate through a front guide rail slider mechanism and a rear guide rail slider mechanism, the front translation mechanism and the rear translation mechanism are connected with the front mounting substrate and the rear mounting substrate, the left mounting substrate and the right mounting substrate are connected with the connecting assembly through a left guide rail slider mechanism and a right guide rail slider mechanism, the front translation mechanism and the rear translation mechanism drive the first station feeding main body and the second station feeding main body to be switched between a feeding station and a riveting station, the riveting station comprises, the left-right translation mechanism drives the first station feeding main body or the second station feeding main body located at the press riveting station to reach the execution station.

2. The upper die changing mechanism of the double-station squeeze riveter according to claim 1, which is characterized in that: control translation mechanism including control the cylinder and control the cylinder connecting plate, control the cylinder body of cylinder and fix control on the mounting substrate, control the piston rod of cylinder and pass through control the cylinder connecting plate with coupling assembling connects.

3. The upper die changing mechanism of the double-station squeeze riveter according to claim 2, characterized in that: the left cylinder and the right cylinder are double-shaft cylinders.

4. The upper die changing mechanism of the double-station squeeze riveter according to claim 2, characterized in that: coupling assembling includes feeder regulating plate, feeder regulating block and connector, be equipped with the regulation recess on the feeder regulating block, the feeder regulating plate sets up in the regulation recess and with regulation recess sliding fit, the feeder regulating plate with the feeder regulating block passes through adjusting bolt lock joint, the feeder regulating block with the connector is connected, the bottom of feeder regulating plate with control cylinder connecting plate fixed connection.

5. The upper die changing mechanism of the double-station squeeze riveter according to claim 4, which is characterized in that: the bottom of the feeder adjusting plate is connected with the left and right mounting substrates through a left and right guide rail sliding block mechanism.

6. The upper die changing mechanism of the double-station squeeze riveter according to claim 1, which is characterized in that: front and back translation mechanism is including front and back cylinder, front and back cylinder connecting block and front and back cylinder mounting panel, front and back cylinder mounting panel is fixed control mounting plate is last, the cylinder body of front and back cylinder passes through front and back cylinder connecting block with front and back cylinder mounting panel fixed connection, the piston rod of front and back cylinder with front and back mounting plate fixed connection.

7. The upper die changing mechanism of the double-station squeeze riveter according to claim 6, which is characterized in that: spacing lug about both ends are equipped with respectively about controlling of mounting substrate's top, coupling assembling is located about two between the spacing lug, about mounting substrate's below be equipped with spacing recess around, mounting substrate sets up around within the spacing recess.

8. The upper die changing mechanism of the double-station squeeze riveter according to claim 1, which is characterized in that: the first station feeding main body and the second station feeding main body are arranged in parallel left and right, and are respectively installed on the front and rear installation substrates through positioning pins and positioning holes.

9. The upper die changing mechanism of the double-station squeeze riveter according to claim 8, characterized in that: the front end of first station pay-off main part is equipped with first station and places the recess, the front end of second station pay-off main part is equipped with the second station and places the recess, the front end of controlling mounting substrate is equipped with first station inlet pipe and second station inlet pipe, first station inlet pipe with the recess cooperatees is placed to the first station of first station pay-off main part, the second station inlet pipe with the recess cooperatees is placed to the second station of second station pay-off main part, works as translation mechanism drive around first station pay-off main part, second station pay-off main part are located the material loading station, first station inlet pipe with the recess is placed to the first station of first station pay-off main part and is linked together, the second station inlet pipe with the recess is placed to the second station of second station pay-off main part and is linked together.

10. The upper die changing mechanism of the double-station squeeze riveter according to claim 9, characterized in that: the first station feeding pipe is connected with the first material tray through a first hose, and the second station feeding pipe is connected with the second material tray through a second hose.