US20110271504A1

Movatterモバイル変換

Info

Publication number: US20110271504A1
Application number: US12/866,846
Authority: US
Inventors: Giuseppe Preti
Original assignee: OBER SpA
Current assignee: OBER SpA
Priority date: 2008-02-21
Filing date: 2009-07-16
Publication date: 2011-11-10
Also published as: BRPI0907795B1; DE602008002698D1; EP2093024B1; ES2353468T3; ATE482055T1; EP2093024A1; ITBO20080117A1; BRPI0907795A2; WO2009103695A1

Abstract

The electro-hydraulic pistol device (100) comprises: a first electric micro-motor (1), for setting in right-wise or left-wise rotation a threaded rod (2), respectively for engaging or disengaging the rod (2) from a rivet (3); a hydraulic system (4) in which a fluid (F) pushes a cursor (40), associated to the rod (2) for impressing thereon an axial translation which causes plastic deformation of a predetermined portion of the rivet (3), such as to block the rivet (3) to a corresponding wall (P); a second electric micro-motor (5), for commanding a piston (50) destined to compress the fluid (F). An electrical circuit (6) is associated to the above organs, which electrical circuit (6) is managed by a control unit (60), to which are connected: a first micro-switch (61) activated by tie rod (2) for activation of the first micro-motor (1) in a right-wise direction; a second micro-switch (62), destined to be activated by a trigger (63) after deactivation of the first micro-switch (61), for activating the second micro-motor (5), first in a direction, for compressing the fluid (F), and then in another direction, for reducing the pressure of the fluid (F), as well as for activating, in g1hase relation, the first micro-motor (1) in a left-wise rotation; supply means (7) for the circuit (6) and the micro-motors (1, 5). The left-wise rotation of the first micro-motor (1) and the rod (2) proceeds as long as the trigger (63) is kept pressed.

Description

TECHNICAL FIELD

The invention relates to the technical sector of riveting pistols, with special reference to servo-assisted pistols, used for rivets having a cylindrical shape, al partially-threaded axial hole, an abutment collar at a head thereof and a specially-weakened portion at which the plastic deformation will occur.

BACKGROUND ART

The rivets are destined to join two walls stably, for example in place of spot welding, or for constituting a threaded anchoring bush of an adequate sturdiness, for structures made of too-soft or too-thin materials for fashioning sufficiently-resistant threads.

The above-described rivets can be of considerable dimensions, and for their application it is necessary to avail of the necessary equipment, which must be able to exert thereon a high compression force.

A known-type riveting pistol, constructed by the same applicant in accordance with an Italian patent application for industrial invention no. B02007A000311, comprises a body and a grip wherein are housed:

- a pneumatic motor, for rotating a threaded rod either right-wise or left-wise, respectively for engaging or disengaging the rod from the threaded axial hole of one of the rivets;
- a hydraulic system for impressing an axial translation on the motor-rod group, for causing a plastic deformation of a predetermined portion of the rivet, such as to block the rivet to a structure;
- a pneumatic thrust amplifier, activating a piston for compressing the fluid of the hydraulic system;
- a pneumatic system, in which are comprised: an auxiliary valve activated to open by the rod; a main valve, activated to open by a trigger;
- a hydro-pneumatic exchange valve, connected to the hydraulic and pneumatic systems, comprising: first organs for detecting a pressure of the hydraulic fluid; second organs for switching delivery of compressed air from the pneumatic thrust amplifier to the pneumatic motor, upon reaching a predetermined maximum pressure of the hydraulic fluid;
- an emergency control for setting the pneumatic motor in left-wise rotation.

The pistol functions as follows:

- the rivet is arranged in the hole afforded for it in the structure, with the relative collar contacting thereon, or, alternatively, the rivet is manually positioned before the rod of the pistol;
- the rod is placed in the axial hole of the rivet, up to the start of the thread thereof, thus determining an axial thrust on the rod towards the body of the pistol, which causes the opening of the auxiliary valve, which auxiliary valve enables compressed air to be sent to the motor, setting it in right-wise rotation in order to screw in the rivet; when the collar thereof strikes against the front head of the body, the auxiliary valve is automatically closed and the motor stopped;
- by pressing the trigger the main valve is opened, which enables sending compressed air to the thrust amplifier, through the hydro-pneumatic exchange valve, with a consequent increase in pressure of the hydraulic fluid and a starting of the axial translation of the motor-rod group;
- by keeping the trigger pressed, the translation proceeds, causing a progressive compression of the rivet which is thus deformed in an external direction, in the weakened portion, defining an annular edge that adheres to the surface of the opposite structure to the structure on which the collar rests, thus determining the blocking of the rivet;
- still by keeping the trigger pressed, on reaching the maximum pressure determined for the hydraulic fluid, the second organs of the hydro-pneumatic exchange valve intervene and interrupt the inflow of compressed air towards the thrust amplifier and send it to the pneumatic motor, setting the motor in left-wise rotation; at the same time the air contained in the thrust amplifier is discharged to the outside;
- the left-wise rotation of the motor is transmitted to the threaded rod which unscrews from the rivet, now blocked to the structure;
- the operator releases the trigger when the rod is disengaged from the rivet.

The riveting pistol described above functions excellently, but requires a compressed air source to which it can be collected; it cannot therefore be used when the air source is not available.

DISCLOSURE OF INVENTION

The aim of the present invention is to provide an electro-hydraulic pistol device having an electronic control for deforming the fastening element, which therefore does not require a connection with a source of compressed air.

A further aim of the invention is to provide an electro-hydraulic pistol device which exhibits an operating logic which is entirely similar to that of the known pistol described in the preamble hereto.

A further aim of the invention relates to the desire to provide an electro-hydraulic pistol device which can be realized in numerous variant embodiments, different in the type of electrical supply provided and/or in the constructive design, with components that can be housed in the body and the grip, or that can be external thereof.

A further aim of the invention consists in the possibility of offering versions of the electro-hydraulic pistol device which are particularly compact and light, thanks to the external location of components.

BRIEF DESCRIPTION OF THE DRAWINGS

The characteristics of the invention will better emerge from the following description of preferred embodiments thereof, in agreement with what is set out in the appended claims and with the aid of the accompanying figures of the drawings, in which:

FIG. 1 illustrates an embodiment of the electro-hydraulic pistol device of the invention, in a sectioned schematic lateral view;

FIG. 2 is a section made along plane II-II ofFIG. 1;

FIG. 3 is a section made along plane III-III ofFIG. 1;

FIGS. 4 from11 illustrates views similar toFIG. 1, with the electro-hydraulic device in the most important operating stages.

BEST MODE FOR CARRYING OUT THE INVENTION

With reference to the figures of the drawings,100 denotes a first embodiment of the electro-hydraulic pistol device of the invention, in its entirety; in the following description, for the sake of simplicity, thedevice100 will be known simply as a pistol.

Thepistol100 comprises abody101 and agrip102 in which the following are housed:

- a firstelectric micro-motor1, for rotating leftwise or rightwise, viafirst transmission organs11, a threadedrod2, respectively for engaging or disengaging therod2 in the threadedaxial hole3A of one of therivets3;
- ahydraulic system4 comprising acylinder51, containing a fluid F and connected to achamber41, in which acursor40 slides, the cursor impressing an axial translation to therod2, in order to determine plastic deformation of a predetermined portion of therivet3, such as to block it to a corresponding wall P;
- a secondelectric micro-motor5, for commanding, by means ofsecond transmission organs52, an outward and return run of apiston50, which compresses, during the outward run, the fluid F of thehydraulic system4 in thecylinder51;
- anelectric circuit6, comprising the following: acontrol unit60; a first micro-switch61, activated by therod2 to switch the first micro-switch1 such that therod2 rotates towards the right; a second micro-switch62 activated by atrigger63, for activating thesecond micro-motor5 first in one direction and then in the other and, in a phase relation determined by thecontrol unit60, for activating thefirst micro-motor1 in left-wise rotation;
- batteries7, associated to an ON/OFF switch, not illustrated, for supplying electrical energy to theelectric circuit6 and, via this, to the first and second micro-motor1,5.

Thepistol100 further comprises an emergency button control, not illustrated in detail but preferably arranged with a position and/or conformation protected from accidental activation, associated to theelectric circuit6 and destined to activate the first micro-switch1 such that therod2 rotates to the left, in a way which will be described herein below.

Thefirst transmission organs11 are constituted, for example, by a plurality of gears also functioning as speed reducer; preferably theseorgans11 cause themicro-motor1 and therod2 to rotate in a same direction (FIGS. 2 and 3).

Thesecond transmission organs52 are constituted, for example, by an epicyclical gear reducer.

There follows a description of the operation of thepistol100 for application of arivet3 to a wall P, starting from the inoperative position ofFIG. 4, in which:

- the first and the second micro-motor1,5, are stationary;
- the pressure in thehydraulic system4 is at the minimum, with thepiston50 in tie lowered position of thecylinder51 and thecursor40 advanced in theclamber41, towards the front head101aof thebody101, due to the action ofrelative contrast spring42;
- the switch associated to thebatteries7 is in the ON position.

Therivet3 is arranged in the hole in the wall P therefore, with therelative collar3B striking against the wall; or, alternatively, therivet3 is manually positioned before therod2 of the pistol100 (seeFIG. 4).

When thecollar3B of therivet3 strikes against thefront head101A of thebody100, therod2 is recalled in an external wise direction, releasing thefirst micro-switch61 and thus causing thefirst micro-motor1 to stop (FIG. 5).

By pressing thetrigger63, the second micro-switch62 is activated and thecontrol unit60 starts up the automatic operating cycle of the pistol100 (FIG. 6).

The second micro-motor5 is then activated in the suitable direction, in order to determine the outward run of thepiston50 in thecylinder51, with a consequent increase in the pressure of the hydraulic fluid F into thechamber41 of the cursor40 (FIG. 7).

By keeping the trigger pressed63, thepiston50 continues to rise, while the pressurized fluid F overcomes the resistance of thecontrast spring42 and pushes thecursor40 to retreat, together with the associated threadedrod2.

The translation continues, causing a progressive compression of therivet3 which deforms towards the outside, in the weakened portion, to define anannular edge3C adhering to the surface of the wall P opposite the surface on which thecollar3B is resting, thus determining a blocking of the rivet3 (FIG. 8).

The increase in the pressure in thehydraulic system4 increases the resistance to rising of thepiston50, which leads to a proportional increase in the absorption of power on the part of the second micro-motor5.

The value of this absorption is constantly monitored by thecontrol unit60, since the force exerted on therod2 to deform therivet3 is calculated in relation thereto, by means of suitable parameters.

On the basis of the maximum force the pistol is to be calibrated for the maximum peak of absorption the second micro-switch5 has to reach is calculated and the relative datum is stored in thecontrol unit60.

When the instantaneous absorption detected equals the maximum value foreseen, and with this the predetermined deformation thrust having been reached, thecontrol unit60 inverts the rotation of thesecond micro-motor5, with consequent inversion of the movement of the piston50 (FIG. 9).

The above leads to a sharp drop in hydraulic fluid pressure F, with a consequent interruption of the retraction of the cursor-rod group and thus of the stressed on therivet3.

While thepiston50 proceeds in its descent, due to the action of thesecond micro-motor5, thecontrast spring42 newly prevails on the force determined by the fluid pressure F and advances thecursor40 and therod2.

Thecontrol unit60, in a suitable phase relation with the descent of thepiston50, starts up the first micro-motor1 too, setting the threadedrod2 in leftwise rotation so that it unscrews from therivet3 which by now is blocked to the wall (FIG. 10).

The second micro-motor5 is maintained in motion until thepiston50 reaches the lowered start position, after which it is automatically deactivated by the control unit60 (seeFIG. 10 once more); the signal which attests to the reaching of the position can be given by an end-run sensor (not illustrated), or by the increase of absorption of the micro-motor5 consequent upon the intercepting of a mechanical end-run stop53 which is integral with thepiston50.

The rotation of thefirst micro-motor1, on the other hand, continues as long astie trigger63 is kept depressed, such that the rotation of therod2, for unscrewing the just-appliedrivet3, proceeds for the time decided by the operator.

On release of thetrigger63, with a consequent stop of the first micro-motor1, tie foreseen functioning program is completed (FIG. 11).

At this point thepistol100 is newly in the condition described with reference toFIG. 4, with thecontrol unit60 predisposed for a new cycle.

A particularly able operator, therefore, can optimally synchronize the disengagement of therod2 with the halting of the micro-motor1, such as to render thepistol100 immediately ready for anotherrivet3, previously positioned on the wall P.

If thetrigger63, due to error or another reason, is released before the disengagement of therod2, the unscrewing can be completed by pressing the emergency command, in order to reactivate the micro-motor1 with a further leftwise rotation of therod2.

Worthy of note is the fact that thepistol100, as described, does not minimally suffer from any maneuvering error which might be committed if, following an early release of thetrigger63, pressure is newly placed thereon.

The control logic of thecontrol unit60 can be programmed to continue the interrupted cycle if, for example, release occurs during the stage of deformation of therivet3.

In a case where the maneuvering error is in the final stage of unscrewing, with a subsequent pressure on thetrigger63, instead of the activating of the emergency control, the pistol repeats the automatic traction cycle on therod2 Without causing undesired stress on therivet3 applied, as on reaching the preceding maximum fluid pressure F, thecontrol unit60 interrupts the action and starts unscrewing, so that the only drawback that obtains is a slight waste of time.

Other embodiments of the electro-hydraulic pistol device are envisaged, apart from the one illustrated and described herein above.

In a second embodiment, not illustrated, thebatteries7 and possibly also thecontrol unit60 can be housed in a module which is external of the body of the pistol; this is to contain the weight and size of the pistol, making it easier to use.

In a third embodiment, also not illustrated, the batteries are eliminated and electrical energy is sourced from a network, with the interposing of a suitable transformer/rectifier, with the aim of obtaining unlimited working autonomy, together (in this case too) with a considerable reduction in weight.

Certainly, with reference to the last solution, total device independence of external energy sources is lost, but it is extremely evident that having a current tap available is much more likely than having a handy source of compressed air.

In a further embodiment, not illustrated, the constructional characteristics of the two above-mentioned embodiments are combined, thus providing a module which is external of the body of the pistol which contains, apart from the batteries and the control unit, the transformer/rectifier for network-sourced power and possibly a device for recharging the batteries.

From the above it can be understood how the electro-hydraulic pistol device fully reaches the set aims, in particular for obtaining a functioning logic which is entirely similar to that of the known-type pistol cited in the preamble hereto, without there being any need for supply of compressed air.

The constructional possibilities given by the choice of electrical workings leans that it is easy to set up numerous constructional variations, without there being any negative effect on the functioning of the device, which variations can respond to needs that otherwise would be destined to remain unaddressed.

Thanks to the external locating of the components such as the batteries, it is possible to attain considerable benefits in terms of compactness and lightness of the device, with obvious advantages in the use thereof.