Applicants claim priority under 35 U.S.C. §119 of Austrian Application No. A1192/2001 filed on Jul. 31, 2001. Applicants also claim priority under 35 U.S.C. §365 of PCT/AT02/00215 filed on Jul. 19, 2002. The international application under PCT article 21(2) was not published in English.
The invention relates to a safety switch unit for electrically controlled machines, for use in combination with the actual control elements of the machine control system in handheld applications or for manual control, as defined in claim 1.
Patent specification DE 199 09 968 A1 filed by the same applicant describes a safety switch unit for electrically controllable machines. This safety switch unit has several contact stages and two mutually independent, redundant switch circuits. The active contact stages of the safety switch unit are provided in the form of a key function, i.e. they can only remain active as long as they are being actively depressed by a user. Detection systems which operate without contacts are provided as a means of detecting the respective switch position and are connected to an electronic evaluation circuit. Two operating elements are used to switch to the different contact states and are disposed so as to be linearly slidable relative to a housing in which they are partially enclosed. A linking arrangement or cap connecting the two operating elements is provided, the purpose of which is to allow the operating elements to be displaced simultaneously. It is also stated that the housing has guide tracks designed so that the operating elements can be guided substantially without any clearance. As an alternative, it is also pointed out that rotating motions can also be effected with the operating elements in order to initiate the desired switching function. The specified construction requires relatively large integration depths, which means that this design is not suitable for all applications. Moreover, the more it is used, the more the arrangement proposed for guiding the linear or rotary motions of the operating elements is at risk of mechanical jamming caused by dirt or abrasive wear on the slide surfaces, for example. The guided sliding or rotating motions also need to be very precise, which increases the cost of producing the safety switch unit.
The underlying objective of the present invention is to propose a safety switch unit of high mechanical functioning reliability which can be operated in the standard fashion.
This objective is achieved by the invention as a result of the characterising features defined in claim 1.
The advantage of this approach is that the safety switch unit is built so as to incorporate two full circuits, including from a mechanical point of view, and therefore meets the criteria of so-called fail-safe control. Another major factor is the specific way in which the operating elements are mounted so as to pivot about pivot axes, which provides a mechanically very reliable design that is guaranteed to function perfectly and unimpaired irrespective of the number of operating cycles. In particular, the operating properties of the specified safety switch unit remain unaltered, even after numerous operating cycles, and it is not susceptible to any significant wear. Also of particular advantage is the fact that any risk of the operating elements sticking, moving out of line or even jamming altogether is minimised due to the way in which the operating elements are mounted so as to rotate about the corresponding pivot axes, thereby conforming to high safety requirements. The rotary mounting of the operating elements will not adversely effect the trigger behaviour of the safety switch even if the operating force applied by the user is off-centre, which means that it will be possible to output the respective switch commands correctly even in panic situations or if the safety switch unit is being held incorrectly or carelessly. The push button unit nevertheless enables a substantially linear operating motion for the safety switch unit to be achieved, thereby constituting the basis for intuitive and familiar operation by the respective user.
As a result of the embodiment defined in claim 9, the points at which force is introduced into the push button unit are essentially fixed and are disposed above the switch elements, thereby enabling the force to be transmitted to the switch elements as directly as possible. In addition, this motion does not have to be reversed and instead the adjustment direction of the safety switch unit may be the same as the adjusting direction for triggering switching procedures in the switch elements.
The embodiment defined in claim 11 offers a simple way of enabling special switching states of the safety switch unit to be detected without the need for complex latching or locking mechanisms.
As a result of the embodiment defined in claim 14, switch elements that are intrinsically relatively sensitive can be accommodated in a perfectly stable manner in a plastic housing and the switch elements will still be very resistant to breakage and damage, even if the operating force is applied quite forcefully, as would be the case in panic situations, or if the correct operating mode were not used.
As a result of the embodiment defined in claim 17, in spite of the relatively large surface available on the push button unit for operating purposes, the safety switch unit is still relatively small in terms of its construction size. In particular, the specified safety switch unit can also be integrated in a device housing in which only a shallow depth is available for integration purposes.
The advantageous embodiment defined in claim 5 or 6 on the one hand ensures that the operating elements are mounted so that they will not become blocked or move out of line and on the other hand provides a central zone at which force is introduced. Furthermore, the fact that the operating elements merge with one another within the zone in which force is introduced ensures that the operating elements will always be correctly operated by the user even though the two operating elements are mechanically independent or each mounted separately and not positively coupled with one another in displacement.
With the embodiment defined in claim 21, the operating elements roll in a sliding arrangement relative to the push button unit when pivoted about their pivot axes and the push button unit is supported on the operating elements with as little friction as possible. In particular, an easy relative displacement is produced between the operating elements and the push button unit disposed in front within the force transmission zone, whilst inducing as little friction as possible
The embodiment defined in claim 24 ensures that the operating elements, which are mounted so that they move independently of one another, are always moved simultaneously and conforming to the same shape when operating force is applied to the rubber-elastic cover element. In addition, the substantially dimensionally stable pressure-transmitting block rules out the possibility of misalignment between the cover element or push button unit and the pivoting operating elements.
As a result of the embodiment defined in claim 27, the safety switch unit can be switched from the contact stage constituting the confirmation state to the contact stage representing panic mode without unacceptably high forces on the switching elements affecting the normally open contacts. In addition, the requisite operating forces are such that they are perceptibly different because the resiliently flexible compensating elements have to be deformed in order to switch from confirmation to panic mode.
The invention will be explained in more detail with reference to examples of embodiments illustrated in the appended drawings.
Of these:
Firstly, it should be pointed out that the same parts described in the different embodiments are denoted by the same reference numbers and the same component names and the disclosures made throughout the description can be transposed in terms of meaning to same parts bearing the same reference numbers or same component names. Furthermore, the positions chosen for the purposes of the description, such as top, bottom, side, etc., relate to the drawing specifically being described and can be transposed in terms of meaning to a new position when another position is being described.
This safety switch unit 1 is preferably operated by a user who applies pressure with the finger. Naturally, however, it would also be possible for the safety switch unit 1 to be designed so that it can be operated by the foot. The safety switch unit 1 is intended as a means of controlling machines or robots in combination with the actual control elements of the electric machine control system and, this being the case, is specifically used to provide manual control of motion and function sequences of a machine. For example, the safety switch unit 1 proposed by the invention is used during manual operation of a multi-axis robot arm or multi-axis processing machines, for example. The safety switch unit 1 is thus used in combination with the actual control elements which have to be operated by the user, such as a controller stick, a controller ball or a so-called “track ball”, directional control keys or similar for example, thereby enabling the machine under control to perform a movement or function intended by the user only when the safety switch unit 1 is operated in a pre-defined manner. The safety switch unit 1 is therefore comparable to a confirmation system and can be integrated in a stationary or mobile handheld control device for the machine or alternatively it can be used in conjunction with a switch or control lever or similar.
The safety switch unit 1 is used for so-called “teach-in procedures” or learning processes for robots, during which the motion sequence to be performed by the robot arm is pre-set beforehand by means of a manual control, after which the robot performs the motion sequence learned during the manual control process on its own.
The safety switch unit 1 is designed to operate on the basis of a push button in particular, i.e. the switch position initiated by the user is maintained only as long as the safety switch unit 1 is consciously operated.
The safety switch unit 1 is therefore connected to at least some of the individual control elements on a handheld device or control panel for the respective machine so as to operate in what is virtually a serial mode. In other words, the machine will not perform the motion or function intended by the user unless the safety switch unit 1 is being operated in addition, preferably by the second hand of the user, thereby providing confirmation of the motion or sequence to be performed. The safety switch unit 1 therefore fulfils a safety function since it ensures that unintentional activation of the control elements for the machine or automated manipulator, caused by jostling for example, can not cause uncontrolled movements or functions. Similarly, if a mobile handheld device drops to the floor or is subjected to impact stress, no critical control commands will be output unless the safety switch unit 1 is simultaneously being operated in such a way that the confirmation mode is assumed.
The safety switch unit 1 may optionally also have a panic mode or emergency stop function, which can be initiated rapidly and reliably in the event of a risk situation. In practice, since a hand or at least one finger of the user is supported on the safety switch unit 1 when critical motions or functions are being performed, only a short additional operating path has to be covered in order to ensure rapid switching when necessary.
The specified safety switch unit 1 can reduce the risk of injury to personnel on the one hand and minimise the risk of damage to machine parts or workpieces on the other, which all in all makes control of the corresponding machine relatively safe. The construction of the safety switch unit 1 described below is very reliable both in terms of mechanical and electrical operating functionality, so that these safety aspects are always preserved.
In addition to an initial or inactive position, the safety switch unit 1 has at least two switch positions and optionally also three different switch positions. In the first switch position or contact stage, in which the safety switch unit 1 is not being operated by the user, no confirmation is given for a critical movement of a machine part or a dangerous function of the machine being controlled and operated. In order to assume the second switch position or contact stage, the safety switch unit 1 must be operated, preferably by at least one finger of the user, and only at this stage is the authorisation given for the machine to perform a helical movement or function, for example. This authorisation or confirmation continues to apply only if the depressed position of the safety switch unit 1 is maintained accordingly, in particular is maintained only as long as a displaceably mounted push button unit 2 (
In the embodiment illustrated in
A movement of a machine part or the performance of a function by a machine can not be authorised again until the push button unit 2 has been fully released and the push button unit 2 operated again, starting from the inactive position and moving into the second contact stage. As the safety switch unit 1 is being re-set, in particular as the push button unit 2 is switched from the third contact stage (panic) via the immediately consecutive contact stage (authorisation) back to the first contact stage (inactive position), the safety switch unit 1 does not permit any authorisation—not even briefly—so that there is no way in which the machine an be activated again—even briefly—if the push button unit 2 was previously in the third contact stage (panic) and then released again. This so-called function lock or prevention of undesired or critical switch or operating modes of the safety switch unit 1 is preferably accomplished by using an electronic control or evaluation device for the safety switch unit 1. This control or evaluation device is therefore provided either in the form of a separate linked unit directly on the safety switch unit 1 or the electronic control or evaluation device 2 is disposed externally to the safety switch unit 1. In particular, the control or evaluation unit 3 may also be provided as a part of the control electronics of a handheld device or any other electronic machine control system.
Irrespective of whether the safety switch unit 1 is of a double-action or multi-action design, it is of a multi-channel or multi-circuit design, so that if one electric circuit fails, at least one other electric circuit remains operational and will continue to assume the respective functions, thereby guaranteeing a high probability that the safety switch unit 1 will not suffer a total failure. The safety switch unit 1 can therefore be classed as falling within the category known as “failsafe” switch elements, the functional reliability of which is significantly higher than that of conventional switch elements. The safety switch unit 1 preferably has two separate electric switch circuits 4, 5, each of which is independent of the other, and each electric switch circuit 4 and 5 has a separate mechanical operating element 6, 7. In particular, the operating element 6 co-operates with the first switch circuit 4. This being the case, the switch circuit 4 is designed to detect the respective position of the displaceable operating element 6 and to forward corresponding information or control commands to the control or evaluation device. The second switch circuit 5 co-operates with the other operating element 7 and is likewise designed to generate appropriate signals or control commands for the control or evaluation device depending on the position of the operating element 7. The safety switch unit 1 therefore constitutes a full dual-circuit system, both from an electrical and a mechanical point of view. In particular, this design offers both a mechanical and an electrical redundancy for the safety switch unit 1.
The two operating elements 6, 7 are mounted on a dimensionally stable mounting frame 8 or in an appropriate support element. The important point is that the two operating elements 6, 7 can be rotatably displaced or pivotably displaced to a limited degree by means of two separate pivot bearings 9, 10 for each operating element 6, 7. These pivot bearings 9, 10 on the mounting frame 8 thus form two pivot axes 11, 12 extending transversely to the longitudinal extension of the bar-type operating elements 6, 7. The push button unit 2 is disposed in front of the two operating elements 6, 7, by reference to an operating direction—arrow 13—of the safety switch unit 1.
The push button unit 2 is therefore connected to the two pivotably mounted operating elements 6, 7 so as to guarantee and produce a substantially translating or linear operating motion of the safety switch unit 1. This linear or translating operating motion of the safety switch unit 1 is effected starting from the inactive position in the direction of arrow 13 into the authorisation position and optionally into a panic or emergency stop position. If the push button unit 2 is moved in a straight line relative to the mounting frame 8 as indicated by arrow 13, the operating elements 6, 7 are pivoted about the pivot axes 11, 12 thus changing their operating states, in particular the contact states of the two electric switch circuits 4, 5. Each switch circuit 4, 5 preferably has at least one electric switch element 14, 15. These switch elements 14, 15 are preferably provided in the form of switch contacts, which may be of a standard type. The switch circuits 4, 5 each have at least one electric normally open contact 16, 17. Especially if the safety switch unit 1 is of a three-stage design with an emergency stop or panic function, each switch circuit 4,5 is provided with at least one respective electric normally closed contact 18, 19. These normally closed contacts 18, 19 are operated specifically when the third switch position of the safety switch unit 1 or push button unit 2 is assumed, thus enabling the control or evaluation system 3 to detect an emergency stop or panic situation. The normally closed contacts 18, 19 may alternatively or also directly intervene in a switch circuit to be protected and halt the respective machine functions or machine movements or initiate other safety measures, such as an emergency shut-down, for example.
The normally open contacts 16, 17 are operated when the second switch position or authorisation position is assumed, in particular when they are switched to the closed contact state. This active contact state of the normally open contacts 16, 17 is detected by the control or evaluation device, after which appropriate actions are initiated. In particular, the control elements of the machine control system to be protected are functionally released for normal use.
The switch elements 14, 15 are preferably provided in the form of electromechanical switch contacts. Alternatively, the switch elements 14, 15 could also be provided as inductive, capacitive, optical or magnetic detection elements or detection elements operating on some other physical principle.
The switch elements 14, 15 are preferably provided in the form of standard, commercially available electromechanical switch elements 14, 15 designed for printed circuit board mounting. The spring means needed for re-setting the normally closed contacts 18, 19 and normally open contacts 16, 17 are already provided in the interior of these components or switch elements 14, 15 and no additional spring or re-setting means are needed to construct the safety switch unit 1. Using nothing more than the existing re-setting means in the standard components or switch elements 14, 15, the safety switch unit 1 is constructed so that they are reliably returned to the initial or inactive position when the operating forces applied by a user to the push button unit 2 are released. One of the reasons for this high functional reliability is the pivot bearings 9, 10 used for the operating elements 6, 7, which are particularly effective in preventing misalignment and guarantee long-term functional safety. The fact that no additional spring or re-setting means are needed for the operating elements 6, 7 or for the push button unit 2 of the proposed safety switch unit 1 significantly enhances mechanical operating reliability still further. The switch elements 14, 15, available as standard components, have been widely tried and tested and such commercially available components will guarantee functional reliability for thousands of operating cycles.
It is preferable if the operating force which has to be applied in order to displace or switch the normally closed contacts 18, 19 is greater than the operating forces necessary to switch the normally open contacts 16, 17. This will result in a clearly perceptible difference between the switch positions of the safety switch unit 2, 3. Furthermore, the sum of the operating forces to be applied to the normally open contacts 16, 17 and the normally closed contacts 18, 19 in each switch circuit 4, 5 is such that the displacement force needed to switch the safety switch unit into the third switch mode or panic position rises by a step. The clearly perceptible pressure point between the second switch position (confirmation position) and the third switch position (panic position) significantly facilitates manipulation of the safety switch unit 1, virtually ruling out faulty or incorrect control of the safety switch unit 1.
The mechanical structure and kinematic design of the safety switch unit 1 described above ensures that the push button unit 2 is displaced in as straight a line as possible, even if operating force is applied at an angle or off-centre. The described mechanical design also ensures that the respective switch elements 14, 15 of each switch circuit 4, 5 are operated as far as possible simultaneously and conforming to the same shape. If the control or evaluation device detects that the signals of the respective identical switch elements 14; 15 in the two switch circuits 4, 5 follow one after the other in time or there is too long a time lag, it can be concluded that the function of the safety switch unit 1 is impaired and an appropriate warning signal can be issued under the control of the control or evaluation device 3. Likewise in situations where only a single signal can be generated or received by the two parallel switch circuits 4 and 5, an appropriate alert or warning signal can be output by the control or evaluation device 3. Optical and/or acoustic output elements may be used for signalling purposes. To implement acoustic signalling, a summer or similar may be provided, either directly on the safety switch unit 1 or alternatively connected to the central control or evaluation unit.
As may best be seen from
The control or evaluation device is designed in such a way that a control or switch signal indicating the same function must always be received from each switch circuit 4, 5. Should it suddenly happen that only one switch signal can be received, in particular only one confirmation signal or only one emergency stop signal, the control or evaluation device is able to conclude from this that the safety switch unit 1 is damaged or faulty, whereupon appropriate measures can be initiated, for example warning or error signals issued and/or a safety shut-down operated.
The two operating elements 6, 7 are mounted so as to pivot relative to a mounting frame 8 for at least one electric switch element 14, 15 of the two switch circuits 4, 5. In particular, each operating element 6, 7 has a respective pivot axis 11, 12, with two mutually independent pivot bearings 9, 10 for the two operating elements 6, 7. The two operating elements 6, 7 are displaceable in rotation to a limited degree via the two pivot bearings 9, 10 relative to the mounting frame 8 and the electric switch elements 14, 15. As illustrated most clearly in
The push button unit 2 disposed in front of the operating elements 6, 7 is formed by a part-region of the elastically flexible cover element 42, indicated by broken lines in
The mounting frame 8 on which the operating elements 6, 7 are pivotably mounted by means of the pivot bearings 9, 10 is of a trough-type or box-type shape in this embodiment. This being the case, the two operating elements 6, 7 on either side of the mounting frame 8 constitute articulated flaps or cover elements which bound the mounting frame 8 at the top, as may best be seen from
Disposed on the legs 50, 51 or alternatively on the base plate 49 is at least one retaining tab 52 for securing the safety switch unit 1 in the interior of a portable housing, for example for an electronic handheld device.
As best illustrated in
The printed circuit board 22 with the electric switch elements 14, 15 is inserted and retained in position in the substantially C-shaped mounting frame 8 substantially without any clearance. In particular, a bottom face 53 of the printed circuit board 22 is supported as far as possible by its full surface on an opposing face 54 of the mounting frame 8 and on the base plate 49. The printed circuit board 22 together with the switch elements 14, 15 soldered thereto is therefore at least partially accommodated in the trough-shaped or housing-shaped mounting frame 8 and positioned in the mounting frame 8 by means of the legs 50, 51 and optionally additional webs. The printed circuit board 22 incorporating the switch elements 14, 15 can be easily inserted in the cage-type mounting frame 8 by moving the operating elements 6, 7 to the outwardly pivoted position or with the operating elements 6, 7 already accommodated in the mounting frame 8.
One advantage of this embodiment resides in the fact that the electromechanical switch elements 14, 15 can be accommodated and retained in the mounting frame 8 without any screw fittings. In practical terms, as soon as the printed circuit board 22 incorporating the switch elements 14, 15 is placed in the mounting frame 8, the operating elements 6, 7 can be pivoted into the initial or inactive position illustrated in
To improve the way in which the switch elements 14, 15 are fixed and secured, flexible, resiliently elastic catch elements 55 are provided on the mounting frame 8, which secure the printed circuit board 22 relative to the mounting frame 8. These catch elements 55 thus form a sort of snap-fit connection between the printed circuit board 22 and the mounting frame 8, thereby enabling the safety switch unit 1 to be assembled without the need for tools. In particular, the printed circuit board 22 merely has to be slotted into the trough-shaped or housing-type mounting frame 8, without involving any screwing, and is secured ready for use.
As may be seen from
In this embodiment, therefore, the push button unit 2 is formed directly by the elastically resilient, deformable cover element 42, in particular in the form of a rubber membrane 43. This rubber membrane 43 preferably also fulfils the function of sealing off a housing orifice in which the safety switch unit 1 is inserted and operated with respect to the surrounding area of an appropriate housing.
As illustrated most clearly in
The four switch elements 14, 15 of the safety switch unit 1 are respectively arranged offset from one another in two directions perpendicular with one another by reference to their seating or support plane 59, which as a rule is the component side of the printed circuit board 22. In other words, the switch elements 14, 15, in particular the two normally open contacts 16, 17 and the two normally closed contacts 18, 19 are disposed at the comers of an imaginary parallelogram. Looking down from above onto the seating or support plane 59, which is aligned substantially parallel with the base plate 49, the switch elements 14, 15 therefore constitute the comers or contour of a virtual parallelogram. This special layout of the switch elements 14, 15 enables identical parts to be used for the operating elements 6, 7, thereby reducing the manufacturing costs of the safety switch unit 1 without jeopardising quality or reliability.
The switch elements 14, 15 incorporating the normally open contacts 16, 17 are also disposed at a shorter distance 39, 40 from the respective pivot axis 11, 12 of the co-operating operating element 6, 7 than the respective normally closed contact 18, 19 in the same respective switch circuit 4, 5. In particular, the normally closed contacts 18, 19 are closer to the middle region between the pivot axes 11, 12 than the two normally open contacts 16, 17, as illustrated most clearly in
As illustrated most clearly in
Another essential aspect is the fact that the switch elements 14, 15 are disposed with the normally closed contacts 18, 19 essentially directly underneath the force-introduction zone 58 where the operating elements 6, 7 merge with one another.
Another aspect of this embodiment of the safety switch unit 1 is that the operating elements 6, 7 can be pushed into the initial or inactive position by means of the intrinsic return force of the switch elements 14, 15, as illustrated in
For the sake of good order, it should be pointed out that in order to provide a clearer understanding of the structure of the safety switch unit 1, it and its constituent parts are illustrated to a certain extent out of scale and/or on an enlarged scale and/or on a reduced scale.
Number | Date | Country | Kind |
---|---|---|---|
A 1192/2001 | Jul 2001 | AT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/AT02/00215 | 7/19/2002 | WO | 00 | 8/16/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/012809 | 2/13/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3771636 | Kerns | Nov 1973 | A |
4295017 | Kashima et al. | Oct 1981 | A |
4720608 | Mizuta | Jan 1988 | A |
4967467 | Udagawa | Nov 1990 | A |
5932854 | Umemura | Aug 1999 | A |
6454487 | Buenning et al. | Sep 2002 | B1 |
6841751 | Sasaki et al. | Jan 2005 | B2 |
Number | Date | Country |
---|---|---|
19909968 | Sep 1999 | DE |
0033985 | Aug 1981 | EP |
0702384 | Mar 1996 | EP |
0734817 | Oct 1996 | EP |
WO 9309377 | May 1993 | WO |
Number | Date | Country | |
---|---|---|---|
20050011740 A1 | Jan 2005 | US |