Systems for processing elements

Abstract

A system for processing elements, including a supply device, a processing device and a hollow transport line. The supply device and the processing device are connected via the hollow transfer line. The processing device processes elements, and the supply device supplies elements to the hollow transfer line so that the elements are transferred to the processing device via the hollow transfer line in order to supply the processing device with the elements. A pneumatically operated system component is provided to operate the system. The system includes a gas compressor unit for providing compressed and/or accelerated pressurised air. The gas compressor unit is in an installation space that accommodates the system. The gas compressor unit takes air in from the environment of the processing device and/or from the environment of the supply device in the installation space and provides compressed and/or accelerated pressurised air for the pneumatically operated system component.

Claims

1. A system for processing elements, wherein the elements are connecting elements, joining elements such as screws and rivets, self-piercing rivets, clinch rivets and/or functional elements such as self-piercing, punch-in, press-in, stamp-in nuts and/or self-piercing, punch-in, press-in or stamp-in bolts, comprising a feed device, a processing device and a hollow transport line, wherein the feed device and the processing device are connected to one another via the hollow transport line, wherein the processing device is designed for processing elements, wherein the feed device is designed to receive a plurality of elements and transfer them to the hollow transport line, wherein the elements can be transported to the processing device via the hollow transport line in order to supply the processing device with the elements, wherein a pneumatically operable system component for operating the system is provided, wherein the system comprises a gas compressor unit for generating and supplying compressed and/or accelerated pressurized air, wherein the gas compressor unit is provided in an installation space in which the system is accommodated, wherein the gas compressor unit is designed to take in air from the environment of the processing device and/or from the environment of the feed device in the installation space and to supply compressed and/or accelerated pressurized air for the pneumatically operable system component for the operation of the feed device and for the operation of the processing device, wherein at least two gas compressor units are provided, wherein the two gas compressor units differ in construction and/or in the principle of operation.

2. A system for press-joining a material, comprising a press-joining device, wherein the press-joining device is designed for press-joining, wherein the system is provided in an installation space, wherein a pneumatically operable system component for operating the press-joining device is provided, wherein the system comprises a gas compressor unit for generating and supplying a compressed and/or accelerated gas volume, wherein the gas compressor unit is provided in the installation space, wherein the gas compressor unit is designed to take in air from the environment of the press-joining device in the installation space and to supply compressed and/or accelerated pressurized air for the pneumatically operable system component for the operation of the press-joining device, wherein a plurality of gas compressor units is provided, wherein two gas compressor units are provided, wherein the two gas compressor units differ in construction and/or in the principle of operation.

3. The system as claimed in claim 1, wherein the pneumatically operable system component for operating the processing device comprises an element filling station and/or a tool changing station.

4. The system as claimed in claim 1, wherein a gas compressor unit is designed to supply pressurized air at different pressure levels.

5. The system as claimed in claim 1, wherein one gas compressor unit which operates according to the dynamic compressor principle is provided, and in that one gas compressor unit which operates according to the positive displacement principle is provided.

6. The system as claimed in claim 1, wherein the gas compressor unit is designed to supply a pressure level which is below a pressure level that is 0.3 bar above an initial pressure, or which is below a pressure level that is 0.2 bar above an initial pressure, or which is below a pressure level that is 0.1 bar above an initial pressure, wherein the gas compressor unit operates according to the positive displacement principle.

7. The system as claimed in claim 1, wherein the gas compressor unit is adapted to supply a system component arranged downstream of the gas compressor unit with a maximum system pressure level.

8. The system as claimed in claim 1, wherein the gas compressor unit is adapted to supply a system component arranged downstream of the gas compressor unit with a maximum system pressure level, wherein the pressure level can be adapted in a dynamically flexible manner during operation.

9. The system as claimed in claim 1, wherein the feed device has a gas compressor unit.

10. The system as claimed in claim 1, wherein the processing device has a gas compressor unit.

11. The system as claimed in claim 1, wherein the gas compressor unit has an electric drive.

12. The system as claimed in claim 1, wherein the gas compressor unit has a mechanical drive.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features and advantages are explained in greater detail with reference to the exemplary embodiments illustrated schematically in the figures.

(2) FIG. 1 shows a schematically illustrated system for processing elements, comprising a feed device, a processing device and a transport line;

(3) FIG. 2 shows the arrangement according to FIG. 1 without workpieces and without the robot;

(4) FIG. 3 shows an upper segment of the feed device from FIGS. 1 and 2 in front view without a front-side device door;

(5) FIG. 4 shows an alternative system;

(6) FIG. 5 shows another alternative system in highly schematized form;

(7) FIG. 6 shows another system illustrated partially in a schematic way; and

(8) FIG. 7 shows another schematically illustrated system.

DETAILED DESCRIPTION OF THE INVENTION

(9) In some cases, the same reference signs are used below for essentially corresponding elements of different exemplary embodiments.

(10) FIG. 1 shows a system 1 for processing elements (not illustrated in FIGS. 1-3) in a perspective view. The system 1 comprises a feed device 2, a processing device 3, and a hollow transport line 4. The transport line 4 is designed as a hollow flexible feed hose, for example. The transport line 4 is connected or attached at one end 4b, via a line connection 3a of the processing device 3, to the processing device 3. The processing device 3 is designed for processing the elements. The feed device 2 serves to receive a plurality of elements and to transfer the elements to the transport line 4.

(11) The system 1 is used to act on or process workpieces 5, 6, 7 and 8 present at a fixed point in a processing station 11. The action on the workpieces 5-8 in order to attach an element at a joining location is performed by means of the processing device 3 for processing the elements or, for example, for setting an element on the respective workpiece 5-8 at the joining location. For example, the angular workpieces 5-7 are each riveted to workpiece 8, which is designed as a flat sheet metal layer. Workpieces 5-7 are positioned at regular intervals on an upper side of workpiece 8. According to FIG. 1, the processing device 3 is situated in the region of workpiece 5.

(12) The processing device 3 is connected to a robot 9 or mounted on a movable robot arm 10 of the robot 9. The robot 9 is used for the operation and spatial movement of the processing device 3 in order, for example, to attach the elements to workpieces 5-8.

(13) The processing device 3, which is designed as a rivet processing device, for example, has a hydropneumatic or pneumohydraulic drive 15 and a C-bracket 12 with two limbs, for example. A punch unit 13 is mounted on one limb of the C-bracket 12, and a die unit 14 of the processing device 3 is mounted on the other limb (see FIG. 2).

(14) The system 1, together with the robot 9 and the processing station 11 with workpieces 5-8, is positioned in an installation space R. The installation space R, which occupies part of a production shop, for example, is indicated schematically by a dashed border in FIG. 1.

(15) FIG. 2 shows the system 1 without workpieces 5-8 and without the robot.

(16) The feed device 2 and the processing device 3 are connected to one another via the hollow transport line 4. The elements are transported in transport direction T from the feed device 2 to the processing device 3 by a gas flow within the transport line 4, which is, in particular, gastight. The elements arriving at the processing device 3 are carried onward in corresponding line sections of the processing device 3 and are set at the respective joining location of workpieces 5-8 by means of the punch unit 13. The processing device 3 is used to set rivets, such as self-piercing rivets, clinch rivets or functional elements on workpieces 5-8, for example.

(17) The feed device 2 is designed as a peripheral unit separate from the processing device 3, e.g. with bottom rollers 2a to enable the processing device 3 to be driven on a firm underlying surface.

(18) The feed device 2 has a storage container 16 with a receiving volume 16a for the presentation or reception of a plurality of elements (not illustrated). The storage container 16 is connected to a sorting pot 18 via a hollow tube-like intermediate piece 17 to enable the elements to pass through individually. In the sorting pot 18, the elements arriving from the intermediate piece 17 are positioned individually in the correct position and transferred to a buffer line 19 connected to the sorting pot 18. In the buffer line 19, the elements are presented one behind the other in a row in each case in the same orientation. From the buffer line 19, the elements progress downward to a separating device 20 for the elements.

(19) From the separating device 20, the elements pass individually into a hollow line section 21 of the feed device 2. Through the line section 21, the elements pass to a connection point 22 of the feed device 2.

(20) At the connection point 22, the elements can be discharged from the feed device 2. At the connection point 22, the line section 21 is connected, e.g. in a gastight manner, to one end 4a of the transport line 4. In the exemplary embodiment shown, the line section 21 and the transport line 4 are formed integrally with one another or connected integrally to one another. By way of example, the line section 21 and the transport line 4 are formed by a continuous piece as a feed hose.

(21) The elements can be transported from the connection point 22 to the processing device 3 situated at a distance from the feed device 2 with the aid or by means of a gas flow G in the line section 21 and in the transport line 4. The elements are, for example, taken along individually in the region of the separating device 20 and transported in the direction of the connection point 22 by the gas flow G prevailing in the line section 21 (see FIG. 3). The gas flow continues in the transport line 4, with the result that the elements are moved from the line section 21 into the transport line 4. Owing to the gas flow G in the transport line, the elements are transported with little friction in the transport line 4 as far as an end 4b of the transport line 4. The end 4b of the transport line 4 extends as far as the line connection 3a on the processing device 3, e.g. in the region of the punch unit 13. The end 4b of the transport line 4 is connected to the line connection 3a on the punch unit 13, through which the elements enter a punch channel of the punch unit 13 individually and in the correct position, being blown in with the aid of the gas flow G, for example.

(22) The system 1 has a pneumatically operated system component. Here, the pneumatically operated system component is used, for example, to operate the feed device, e.g. is a part of the feed device 2.

(23) The system 1 comprises a gas compressor unit 23 for generating and supplying compressed and/or accelerated pressurized air. For example, the gas compressor unit 23 is designed as a gas flow generating device in order to provide the gas flow G. To provide the gas flow G in the line section 21 and further in the transport line 4, the feed device 2 has the gas compressor unit 23. The gas compressor unit 23 is, for example, provided exclusively for the feed device 2, for the purpose of delivering the elements by means of the gas flow G. Via a suction side 23a of the gas compressor unit 23, which is open to the environment or atmosphere, atmospheric air L is taken in from the environment and compressed and/or accelerated in the gas compressor unit 23. The gas compressor unit 23 is, for example, capable of being operated electrically by means of an integrated drive motor or electric motor. A delivery side 23b of the gas compressor unit 23 is connected to the separating device 20 via a pressurized-air-carrying connecting line 24, for example. In this case, the pressurized-air gas flow enters the region of the line section 21 which is connected to the separating device 20. The gas flow gives rise to a suction or entrainment force on an isolated element on a discharge side of the separating device 20. In this case, the incoming pressurized air flows across into the line section 21 and entrains an individual isolated element that is furthest forward in the separating device 20, for example, and carries it forward into the line section 21. The separating device 20 separates the element that is furthest forward toward the separating device 20 from a series of elements waiting in the buffer line 19 on the separating device 20.

(24) When the gas compressor unit 23 is active, the elements successively separated by the separating device can be moved through the line section 21 to the connection point 22 by means of the gas flow.

(25) In the connected state of the line section 21 and transport line 4, the elements can be transported from the connection point 22 out of the line section 21 and onward in the transport line 4 as far as the processing device 3 by means of the gas flow.

(26) The gas compressor unit 23 is designed to take in air L from the environment of the feed device 2 on the suction side 23a of the gas compressor unit 23 in order to provide the gas flow.

(27) The gas compressor unit 23 is designed to take in air at atmospheric pressure from the environment of the feed device 2, i.e. some of the air in the installation space R of the feed device 2, on the suction side 23a of the gas compressor unit 23 in order to provide the gas flow. The suction side 23a is, for example, within a housing 25 of the feed device 2 or in an interior space 26, surrounded by the housing 25, of the feed device 2, wherein the interior space 26 is open to the environment or connected to the air space in the installation space R. Alternatively, or in addition, the suction side 23a is, for example, open to the air space in the installation space R outside the housing 25 of the feed device 2. The gas compressor unit 23 has an air flow generator, for example.

(28) The box-type housing 25 has side walls 25a, a rear wall 25b, a base 25c, an upper side 25d and a pivotable door 25e. The upper side 25d is open to the environment by means of an opened pivotable flap, this being shown in FIGS. 1 and 2, ensuring that sufficient ambient air always reaches the suction side 23a of the gas compressor unit 23 during the operation of the gas compressor unit 23. Electric cabling, for example, for supplying the feed device 2 with electrical energy is not shown. The feed device 2 does not have a supply interface for a decentralized supply of pressurized air to the feed device 2, for example. Accordingly, the feed device 2 does not, for example, have a pressurized air connection or a pressurized air inlet for feeding in pressurized air supplied externally or in a centralized way with respect to the system 1.

(29) The gas compressor unit 23 comprises, for example, a gas compression unit for the gas flow generated on the suction side in the line section 21. The gas flow can be supplied by compressed and/or accelerated air by means of the gas compressor unit 23, this being possible in various ways. For example, the gas compressor unit 23 has a pressurized air compression unit. For example, the gas compressor unit 23 operates according to the turbocompressor principle with a radial compressor and/or axial compressor, e.g. with a multistage radial compressor and/or with a multistage axial compressor.

(30) A higher-level control unit 27 (not illustrated specifically) of the feed device 2 has a computer control system or software and a processing and storage unit and serves to control the operation of the feed device 2. The control unit 27 serves, in particular, to control a specifiable or adaptable and/or adjustable power level of the gas compressor unit 23. By means of the control unit 27, it is possible, for example, to specify and/or vary the compression of the pressurized air, the generation of pressurized air and the air output that can be supplied by this means. The air output that can be supplied can be adapted, e.g. dynamically adapted, by means of the control unit 27, in particular, to an actual, e.g. respectively instantaneously required, air demand. The actual air demand is, in particular, programmable and/or can be adapted to the actual demand, e.g. dynamically, e.g. on the basis of the sensor values acquired by sensor means (not shown). Acquired sensor values relate, for example, to a speed of the delivered elements in the line section 21 and/or the transport line 4. By means of the control unit 27, adaptation of the speed of the delivered elements to a target or setpoint value stored in software is possible, e.g. on the basis of the sensor-acquired speed of the delivered elements in the line section 21 and/or the transport line 4.

(31) The sensor mechanisms of the feed device 2 are provided for acquiring and making available the sensor values, e.g. for making available sensor values for further processing by the control unit 27.

(32) An alternative (not shown) of the system 1 is distinguished by the presence on the processing device 3, e.g. directly on the processing device, of a feed device having the components corresponding to feed device 2 but, for example, without a housing 25. Alternatively, a feed device having the functions or components corresponding to feed device 2 is provided on the robot 9, for example. On the robot 9 there is, for example, magazine capacity for the elements in the form of the storage container and/or, in addition, a sorting pot and/or a buffer line. For a system designed as a technology system, precisely one feed device or precisely two or more than two feed devices, are provided, for example. For example, it is also possible, in an alternative system, for at least one component as in feed device 2 to be provided on the processing device 3 and for at least one other component as in feed device 2 to be provided on the robot 9.

(33) In an alternative system or technology system, provision is made, for example, for the means of delivering the elements to be provided on the processing device 3 and/or on the robot 9 in order to deliver the elements from a conveying device to a filling station of the processing device.

(34) In an alternative system or technology system, provision is made, for example, to deliver the elements from a magazine provided on the processing device in order to hold a multiplicity of elements ready at a processing point of the processing device. The processing point of the processing device comprises, for example, a setting head of the processing device, comprising the punch unit and the die unit.

(35) In the case of a multi-track overall system with, for example, systems as per system 1 operating in parallel, provision can be made, for example, for the respective track to be designed in accordance with the system 1 described above.

(36) Another alternative of a system is distinguished by the fact that a standard compressor or, for example, a commercially available known compressor, is provided in the feed device 2 and/or on the processing device 3 and/or on the robot 9. The compressor operates, for example, according to the positive displacement principle and is implemented, for example, as a piston or screw compressor.

(37) FIG. 4 differs from the system 1 shown in FIG. 1 in that the feed device 2 does not have an integral gas compressor unit. On the contrary, the system 1 has a gas compressor unit 29 provided as a separate subunit 28, which is indicated in a highly schematized form. During the operation of the gas compressor unit 29, the unit takes in air L from the installation space R on the suction side of the gas compressor unit 29 and supplies compressed and/or accelerated pressurized air on the delivery side. The pressurized air leaves the gas compressor unit 29 on the delivery side of the gas compressor unit 29, e.g. in the form of a gas flow. From the gas compressor unit 29, the pressurized air flows into a gastight outflow line 30 connected to the gas compressor unit 29 on the delivery side. The outflow line 30 is divided and opens into a line section 30a and a line section 30b.

(38) Via valves (not illustrated), for example, in the outflow line 30 and/or in line section 30a and/or in line section 30b, the pressurized air in the outflow line 30 flows into line section 30a and/or into line section 30b.

(39) Via the line section 30a connected to the feed device 2, a pneumatically operated system component (not designated) of the feed device 2 can be supplied with pressurized air.

(40) Via the line section 30b connected to the processing device 3, a pneumatically operated system component (not designated) of the processing device 3 can be supplied with pressurized air.

(41) FIG. 5 shows an alternative system 1 with a decentralized pressurized air supply in a highly schematized form. The system 1 comprises a feed device 2, a processing device 3 and a transport line 4. On the processing device 3, between a punch unit 13 and a die unit 14, there is a workpiece W, e.g. a sheet-metal workpiece, into which an element 31 can be pressed, this being illustrated in highly schematic form.

(42) The feed device 2 comprises precisely one gas compressor unit 23, e.g. precisely one compressor. The gas compressor unit 23 can be operated electrically or comprises an electric motor, for example. By means of the gas compressor unit 23, air L can be taken in from the environment of the feed device 2 on the suction side of the gas compressor unit 23. During the operation of the gas compressor unit 23, pressurized air at a pressure, for example, of 3 to 6 bar is supplied on the delivery side for pneumatic operation of system components.

(43) By means of a separating device 20, elements 31, a number of which are held in a storage container 16 of the feed device 2, are separated. Via the hollow transport line 4, which is supplied with pressurized air by the gas compressor unit 23 via a connecting line 24, individual elements are each successively fed to the processing device 3 from the separating device 20, being delivered pneumatically.

(44) In addition, a system component 33 of the processing device 3 is supplied with pressurized air, made available by the gas compressor unit 23, via a hollow pressurized air line 32, which is formed on the delivery side between the gas compressor unit 23 and the processing device 3. The system component 33 can be operated pneumatically. For example, the system component 33 is a motion drive for pneumatically or pneumohydraulically driving a linear-motion punch of the processing device 3 or, for example, a locking member for mechanically locking a movable component. The system component 33 is supplied with pressurized air via the hollow pressurized air line 32, which is gastight with respect to the outside.

(45) A system component 35 of the processing device 3 is supplied with pressurized air, made available by the gas compressor unit 23, via a further hollow pressurized air line 34, which is situated on the delivery side between the gas compressor unit 23 and the system component 35. The system component 35 comprises a tool changing station 36 with, for example, four tools 37 arranged releasably and in the correct position on the tool changing station 36. The tools 37 can each be exchanged individually for a tool on the processing device 3, e.g. for a tool of a punch unit of the processing device 3, this being accomplished pneumatically by means of the pressurized air supplied via the pressurized air line 34.

(46) A system component 39 of the processing device 3 is supplied with pressurized air, made available by the gas compressor unit 23, via a further hollow pressurized air line 38, which is situated on the delivery side between the gas compressor unit 23 and the system component 39. The system component 39 comprises a storage container 40, in which a plurality of elements 41, e.g. rivets or functional elements, are held. For example, the storage container 40 is designed as a magazine or element magazine, in the internal volume of which the elements 41 are accommodated and can be introduced from outside. The elements 41 can be swapped pneumatically into a magazine (not illustrated in FIG. 5) for receiving a number of elements 41 on the processing device 3, this being accomplished pneumatically by means of the pressurized air supplied via the pressurized air line 38. To fill the magazine for receiving elements 41, for example, the processing device 3 is driven, e.g. by a robot on which the processing device 3 is mounted and can be moved in space, up to the storage container 40 filled with elements 41. The pneumatic transfer of the elements 41 then takes place, and, following this, the processing device 3 moves away from the system component 39 again.

(47) FIG. 6 shows an arrangement with precisely one gas compressor unit 23 for the decentralized supply of pressurized air for a system component 35 and for a further system component 39. The gas compressor unit 23 according to FIG. 6 is a compressor, for example. The system components 35 and 39 are mounted on a common boom 42. The gas compressor unit 23 takes in air L from the environment of the gas compressor unit 23 and compresses it to 3 to 6 bar, for example. Via a pressurized air line 43, the pressurized air is delivered to the boom 42 and onward to system component 35 and/or system component 39.

(48) The gas compressor unit 23 can be set up as a separate unit in the vicinity of the processing device or can be part of a feed device 2.

(49) Finally, FIG. 7 shows an alternative system 1 with a decentralized pressurized air supply in a highly schematized form. The system 1 shown in FIG. 7 comprises precisely one gas compressor unit 23. In other respects, the system 1 comprises twice as many components as the system 1 shown in FIG. 5.

(50) The system 1 comprises a first feed device 2, a second feed device 2, a first processing device 3 with a workpiece W, and a second processing device 3 with a workpiece W. There is a first transport line 4 between the first feed device 2 and the first processing device 3.

(51) There is a second transport line 4 between the second feed device 2 and the second processing device 3.

(52) The system 1 comprises a gas compressor unit 23. For example, the precisely one gas compressor unit 23 is part of the feed device 2, the gas compressor unit 23 being a compressor, for example. The gas compressor unit 23 takes in air L from the environment of the feed device 2 and supplies a plurality of, e.g. all, pneumatic system components of the system 1.

(53) During the operation of the gas compressor unit 23, pressurized air at a pressure, for example, of 3 to 6 bar is supplied on the delivery side for pneumatic operation of pneumatically operable system components 35, 39, 35 and 39. For example, the system components 35 and 39 are system components of the processing device 3. For example, the system components 35 and 39 are system components of the processing device 3. The gas compressor unit 23 furthermore supplies pressurized air for transporting elements 31 from the feed device 2 to the processing device 3. The gas compressor unit 23 furthermore supplies pressurized air for transporting elements 31 from the feed device 2 to the processing device 3.

(54) For this purpose, pressurized air lines 32, 34, 38, 32, 34 and 38 are provided.

(55) Via a pressurized air line 44, the gas compressor unit 23 is connected to a pressurized air accumulator 45 of the feed device 2. Thus, pressurized air supplied by the gas compressor unit 23 is delivered into the pressurized air accumulator 45 and made available there to feed the separated elements 31 to the processing device 3 via the transport line 4.

(56) Alternatively, it is also possible, for example, for the pressurized air accumulator 45 of the feed device 2 to be omitted. For example, the pressurized air accumulator 45 may not be part of the feed device 2, but may be situated at some other point in the system 1.

(57) In addition to the gas compressor unit 23, for example, precisely one further gas compressor unit or a further number of gas compressor units may be provided, for example, e.g. as part of the feed device 2 and/or as a separate gas compressor unit 23 outside the feed device 2 and/or 2 or outside the processing devices 3, 3 and/or as part of at least one of the processing devices 3, 3.

LIST OF REFERENCE SIGNS

(58) 1, 1 system 2, 2 feed device 2a roller 3, 3 processing device 3a line connection 4, 4 transport line 4a, 4b end 5-8 workpiece 9 robot 10 robot arm 11 processing station 12 C-bracket 13 punch unit 14 die unit 15 drive 16 storage container 16a receiving volume 17 intermediate piece 18 sorting pot 19 buffer line 20 separating device 21 line section 22 connection point 23 gas compressor unit 23a suction side 23b delivery side 24 connecting line 25 housing 25a side wall 25b rear wall 25c base 25d upper side 25e door 26 interior space 27 control unit 28 subunit 29 gas compressor unit 30 outflow line 30a, 30b line section 31, 31 element 32, 32 pressurized air line 33 system component 34, 34 pressurized air line 35, 35 system component 36 tool changing station 37 tool 38, 38 pressurized air line 39, 39 system component 40 storage container 41 element 42 boom 43 pressurized air line 44 pressurized air line 45 pressurized air accumulator