EP2064716B1 - Drive unit, in particular drive head, with a first transmission element, which is capable of rotating about a first axis of rotation - Google Patents

Description

The invention relates to a drive unit, in particular drive head, having a first transmission element rotatable about a first rotation axis for actuating at least one switching unit by means of a plunger, wherein the first transmission element is rotatable by means of a cam and / or recess at least operatively connected to a drive axis. Furthermore, the invention relates to a hinge switch with such a drive unit.

Drive units are used, for example, in so-called hinge switches, which are electromechanical switching devices that serve to monitor and safeguard pivotable protective devices, such as doors or flaps. Hinge switches, for example, monitor guard doors by immediately turning off the power to a machine or equipment when attempting to open a secured door or cover during operation of the machine or equipment. Alternatively, instead of a shutdown also a report when exceeding a predetermined switching angle take place.

A hinge switch usually comprises a drive system, a switching system and a connection system. The drive system serves to record and transmit a rotary or pivoting movement. In the forwarding of the force effect, a transformation of this movement is effected in an actuation of the switching system. Usually this is a conversion of a rotational movement in a linear actuation movement of need. The actuating movement is used to actuate NC and / or NO contacts. The connection system allows a conductor connection, which allows the control of a circuit.

In order to ensure a proper and permanently safe operation of a hinge switch, a relatively high adjustment effort is required in the known from the prior art hinge switches. Since the movement recording takes place mechanically and the connection between the hinge and the drive element of the switching element must be positive, the positions of many components to each other must be maintained exactly. This leads to a relatively high production and assembly costs.

Among other things, hinge switches fulfill the function of personal protection, normally using normally closed contacts which must be positively opening according to IEC 60947-5-1. A positive opening pulls in this context a positive operative connection for the actuating movement after. When using a hinge switch as a safety switch a shutdown or switching on at a specified switching angle can be realized. Usual switching angles are 6 to 8 °. In the past, a trend has been observed which, due to the market, leads to ever smaller door opening widths and thus inevitably leads to ever smaller switching angles, such as, for example, 2 to 5 °. It must always be ensured that the movement recording takes place mechanically and the connection between the monitored object and the drive system is form-fitting.

From the DE 195 08 153 For example, an actuator for a hinge is known, which has a transfer element integrated in the hinge, which is formed on the hinge part moved by the object and can provoke a linear actuation movement.

document DE 1241893 shows a drive unit according to the preamble of claim 1.

In the past, it has proven to be disadvantageous that by this variant, there is a limitation of the opening width, or proves to be a hindrance at smaller opening angles. In addition, an exposed actuating cam is necessary to convert the rotary motion into a linear one. This bearing point between hinge axis and no-cken- or cam and actuator cams may be subject to mechanical damage and environmental influences, as well as manipulation by the user.

Under some circumstances, the disadvantages arise in this or other variants of a hinge switch that the drive system is designed too large due to the cams, or the drive system has very high actuation forces, which in turn leads to high wear due to the friction between, for example, a cam and a switching element slide to lead.

In addition, hinge switches prove to be expensive, which have no supporting function in terms of a mechanical stabilization of the object, so that additional additional hinges are necessary, which have a pure mechanical function.

The invention has for its object to provide a space-saving, safe and user-friendly drive unit, in which the above-mentioned disadvantages are significantly minimized.

This object is achieved in a drive unit of the type mentioned above in that the first axis of rotation of the first transmission element is arranged substantially perpendicular to the drive axis and the actuation of the plunger is durchgefürht means of a second transmission element. The object is further achieved by a hinge switch with such a drive unit.

According to the invention, the drive unit, which is embodied for example as a drive head, has a rotatable first transmission element, which is rotatable about a first rotation axis. The first rotatable transmission element is provided for transmitting the rotational movement of a drive shaft to a plunger, wherein the plunger causes a linear movement of a slider or actuator of a switching unit. Here, the drive axle with the operational to moving object, such as a security door, positively connected. The movement of the object leads to a rotational movement of the drive axle. The power transmission from the drive axle to the first transmission element is accomplished by means of a cam and / or a recess. In this case, for example, a cam on the first transmission element and a recess on the drive axle, or a cam on the drive axle and a recess on the first transmission element may be provided. Furthermore, combinations of such arrangements with, for example, multiple cams and / or recesses are conceivable, and these can be used for transmitting power from the drive axle to the first transmission element. The power transmission leads to a transmission of the rotational movement of the drive axle to the first transmission element. In addition to the cam or recess arrangement, it is also possible to ensure an operative connection via further molded elements of the drive axle to the transmission element. A first axis of rotation of the first transmission element is arranged substantially perpendicular to the drive axis. Advantageous in this context is the possibility to arrange the drive unit or the drive head at one end of the drive axle and thus to remove the drive unit or the drive head from the movement space of the object and / or the hinge. Furthermore, it is possible to save a space by a corresponding design of the first transmission element. The first transmission element may advantageously be designed as a lever, which may be at least partially made of metal or plastic. Advantageously, very small switching angle can be achieved up to about 2 °, at the same time the necessary space is decisively minimized and yet realized a high translation and the operating force is minimized crucial. The high ratio can be achieved while avoiding large forces on the functional surfaces, which also the Wear minimized or the service life of the drive unit is improved.

In an advantageous embodiment, the drive unit has a single first transmission element, whereby the transmission mechanism remains operable, however, the number of components translating from the rotational movement of the drive shaft to the linear actuating movement of a switching element is reduced to a single component.

In an advantageous embodiment, a switching angle or a switching angle range on the design of the drive axle, which is designed for example as a shaft or hinge axis, and on the design of the first transmission element, which is designed for example as a lever can be adjusted. This means that a switching angle or a Schaltwinkelinterwall can be provided within a range of 2 to 360 ° by a cam or recess with the appropriate length and location is provided.

In an advantageous embodiment, it is not necessary to guide the drive axle through the drive unit or drive head, since it is quite sufficient to provide the laying of the effective area by means of the cams and / or recesses conveniently at the upper or lower end of the drive axle. In this case, additional space is gained, which is not affected by the designed as a shaft drive axle or cams, but can be used effectively for the transmission of the angular movement.

In an advantageous embodiment, the drive unit and in particular the effective areas or functional surfaces can be shielded from external environmental influences by means of a housing. This means that functional surface pairs or the surface interaction of the components of the drive unit by unwanted foreign matter is avoidable.

In an advantageous embodiment, the cam is provided on the first transmission element in the vicinity of the first axis of rotation, whereby a high translation and thus a small operating force is achieved. This can be further improved by the first transmission element having a first effective range remote from the first rotational axis, in particular a first kneading head.

In an advantageous embodiment of the first effective range for actuating the plunger and for simultaneous movement of a point within the first effective range is provided. As a result, the different directions of movement of the plunger or a transmission element, in particular of the first transmission element, advantageously taken into account.

In an advantageous embodiment, the first transmission element is designed like a lever and / or at least partially like a disk. In addition to a space control a translation control of the drive element is also possible.

In an advantageous embodiment, the drive unit has at least one actuated and at least one unactuated state as a function of the position of the recess for triggering an actuating movement. It is conceivable that, for example, over a certain angular range or a plurality of angular ranges, an actuated state or unactuated state is triggered. This ensures triggering in a large number of positions. In addition, a plurality of states can be defined, which are particularly useful if the switching element itself can also be in several states.

Furthermore, a continuous detection of the position of the object to be monitored is advantageously conceivable if one or more switching units are provided for the detection of the current position. It is advantageous if the cam and / or the recess are provided for detecting the actuating movement. The detection can be implemented via the corresponding geometries of the cam or the recess, wherein positions of the slider of the switching element correspond to positions of the object.

In the erfindugsgemäßen embodiment, the first transmission element is provided by means of an actuation of at least one second transmission element for actuating the plunger. In particular, in the embodiment of the first and the second transmission element as a lever leverage advantageous lever can be used to achieve a corresponding translation very small switching angle to about 1 °, while still saving space and an operating force reduction is achieved. In addition, the force acting angle on the plunger can be minimized, so that a further increase in service life and wear minimization are possible.

In an advantageous embodiment, the first axis of rotation of the first and second axes of rotation of the second transmission element are arranged parallel or perpendicular to each other. As a result, further space advantages and translation advantages can be worked out.

In an advantageous embodiment, at least one first active region and / or a second active region are provided for increasing the stroke of the first transmission element. By means of a corresponding shaping of the effective regions, a desired stroke can be accomplished in connection with the rotational movement, so that switching elements with differently sized strokes can also be used together with the drive unit.

Further advantageous embodiments and preferred developments of the invention can be taken from the description of the figures and / or the dependent claims.

The invention will be described and explained in more detail below with reference to the embodiments illustrated in the figures.

FIG 1

betriebsgemäß angeordnete Bauteile eines Scharnierschalters,

FIG 2

betriebsgemäß angeordnete Bauteile eines Scharnierschalters mit zwei Übertragungselementen im betätigten Zustand,

FIG 3

die Bauteile aus FIG 2 bei unbetätigtem Scharnierschalter,

FIG 4

eine perspektivische Ansicht eines Scharnierschalters.

Show it:

FIG. 1

operatively arranged components of a hinge switch,

FIG. 2

operatively arranged components of a hinge switch with two transmission elements in the actuated state,

FIG. 3

the components off FIG. 2 with unactuated hinge switch,

FIG. 4

a perspective view of a hinge switch.

FIG. 1 shows operationally arranged components of a hinge switch. To see is a plunger 4, which belongs to the not further shown switching system or switching element. Next, a first transmission element 1 is shown, which represents the only movable component of the lever mechanism. In the drive axis, which is designed as a hinge axis 5, a drive shaft 3 is arranged, which causes a recess 10, a movement of the first transmission element 1 upon rotation of the drive shaft 3 about the hinge axis 5. During the rotation of the drive shaft 3, first the recess 10 moves under the cam 8 of the first transmission element 1. The cam 8 is lowered into the recess 10 when the angle or the Winkelinterwall is reached to trigger. This causes a rotation of the first transmission element 1 about the first axis of rotation 6, wherein the first transmission element 1 acts on the plunger 4 via its first effective region 9.

Due to the fact that the first active region 9 is relatively far away from the first axis of rotation 6 compared to the cam 8, a translation from a small rotational movement to a larger rotational movement takes place. Since the point of application of the first active region 9 moves toward the plunger 4 during the actuation thereof, the rotational movement of the first transfer element 1 can be transferred to a linear movement of the plunger 4. The necessary stroke can be adjusted by a corresponding length of the first transmission element 1, so that you can work with a switching system of a specific lever.

Advantageously, the first active region 9 can be designed in the form of a knitting head, so that a long sweeping of the point of application is ensured. It should be noted here that the positive connection between the drive shaft 3, the first transmission element 1 and the plunger 4 and thus the positive opening of the hinge switch is maintained.

It is advantageous if, for the position switch, the drive shaft 3 and the lever mechanism are already positioned relative to one another during production. As a result, a higher precision is achieved and delivered the hinge or position switch fully assembled. As a result, an additional normal hinge is no longer required because the switch can also take over the hinge function. This also eliminates a customer-specific adaptation or design of the protective doors, flaps, cams or cams, which is why so far a considerable amount of personnel had to be operated.

FIG. 2 shows operationally arranged components of the hinge switch according to the invention with two transmission elements 1,2 in the actuated state. Shown are the lever mechanism, consisting of the first transmission element 1 and a second transmission element 2, and the already in FIG. 1 shown drive shaft 3 with the recess 10. The operation of the first transmission element 1 and the drive shaft 3 in conjunction with the recess 10 and the cam 8 corresponds to the in FIG. 1 described operation.

The additional attachment of a second transmission element 2, which is similar to the first transmission element 1 is movable about a second axis of rotation 7, accomplished first a force transmission or transmission of the movement from the first transmission element 1 on the plunger, not shown. By an appropriate shaping of the second active region 12 and / or a third active region 14, an additional stroke is achieved by the rotational movement of the second transmission element 2. The third active region 14 is integrally formed on the transmission element 2 and represents the counterpart to the first active region 9. The lever mechanism formed with the first transmission element 1 and the second transmission element 2 is therefore able to realize an increased ratio compared to the first embodiment. Here, the first rotation axis 6 and the second rotation axis 7 are arranged in parallel. Both are consequently positioned perpendicular to the hinge axis 5.

A parallelism of the axes of rotation 6, 7 of the transmission elements 1.2 is not mandatory here. The number of transmission elements 1, 2 and the position of their axes of rotation 6, 7 can be selected depending on the stroke to be achieved and the respective application conditions.

FIG. 3 shows the components FIG. 2 with unactuated hinge switch with a plunger 4. It is shown by way of example, like that FIG. 2 known lever mechanism, consisting of the first transmission element 1 and the second transmission element 2, can be arranged on the plunger 4. The plunger 4 is in this case substantially perpendicular to the axis of rotation 5 and to the axes of rotation 6,7, but may also have a certain angle to said axes, if the application so requires. Likewise, the axes of rotation 6,7 could form an angle.

To further increase the stroke additional levers or transmission elements are used, which are similar to the transmission elements 1,2. As a result, a larger number of switching elements can be used in conjunction with the drive unit.

FIG. 4 shows a perspective view of a hinge switch. The hinge switch has a switching system, a drive head 13 and the drive shaft 3. Both the first and the second embodiment of 1 and FIG. 2 can be arranged in such a drive head 13 of the hinge switch.

It is advantageous that the lever mechanism accomplishes the transmission of force at one end of the drive shaft 3, wherein all effective regions 8, 9, 10, 12, 14 are protected from environmental influences by the housing 11 and can optionally be greased, especially the grease, in particular between the effective regions 8, 9, 10, 12, 14, because of the housing 11 can not pick up dirt and provides for easier operation and a longer life of the drive unit. In addition, manipulation by the user is excluded.

In summary, the invention relates to a drive unit, in particular drive head, with a rotatable about a first axis of rotation first transmission element for actuating at least one switching unit by means of a plunger. As a particularly space-saving and safe drive unit for example, a hinge switch, the drive unit has a drive axle which is arranged substantially perpendicular to the first axis of rotation of the first transmission element. This results in a number of advantages, such as the placement of the drive unit at the end of the drive axle.

Claims (13)

1. Drive unit, in particular drive head, with a first transmission element (1), rotatable about a first axis of rotation (6), for actuating at least one switch unit by means of a tappet (4), the first transmission element (1) being rotatable by means of a cam (8) and/or recess (10) at least actively connected to a drive axis (5), the first axis of rotation (6) of the first transmission element (1) being arranged essentially perpendicularly to the drive axis (5), characterized in that the first transmission element (1) is provided for actuating the tappet (4) by means of actuation of at least one second transmission element (2).
2. Drive unit according to Claim 1, the cam (8) being provided on the first transmission element (1) in the vicinity of the first axis of rotation (6).
3. Drive unit according to one of the preceding claims, the first transmission element (1) having a first active region (9), in particular a first active head, remote from the first axis of rotation (6).
4. Drive unit according to Claim 3, the first active region (9) being provided for actuating the tappet (4) and for the simultaneous movement of an engagement point within the first active region (9).
5. Drive unit according to one of the preceding claims, the first transmission element (1) being of lever-like and/or at least partially disc-like form.
6. Drive unit according to one of the preceding claims, the drive unit having at least one actuated and at least one non-actuated state as a function of the position of a recess (10) for triggering an actuating movement.
7. Drive unit according to one of the preceding claims, the cam (8) and/or the recess (10) being provided for controlling the actuating movement.
8. Drive unit according to one of the preceding claims, the second transmission element (2) being provided for actuating the tappet (4).
9. Drive unit according to one of the preceding claims, the second active region (12) being provided for actuating the tappet (4) and for the simultaneous movement of an engagement point within the second active region (12).
10. Drive unit according to one of the preceding claims, the second transmission element (2) being of lever-like and/or at least partially disc-like form.
11. Drive unit according to one of the preceding claims, the first axis of rotation (6) of the first transmission element (1) and a second axis of rotation (7) of the second transmission element (2) being arranged parallel to or perpendicularly to one another.
12. Drive unit according to one of the preceding claims, at least the first active region (9), the second active region (12) and/or the third active region (14) being provided for increasing the stroke of the first transmission element (1).
13. Switch having a drive unit according to one of Claims 1 to 12, the switch being formed as a hinge, switch or position switch.

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