EP2567047A1

EP2567047A1 - Door opener

Info

Publication number: EP2567047A1
Application number: EP11717181A
Authority: EP
Inventors: Kai Gröne
Original assignee: Dorma Deutschland GmbH
Current assignee: Dorma Deutschland GmbH
Priority date: 2010-05-05
Filing date: 2011-04-08
Publication date: 2013-03-13
Also published as: DE102010019578A1; WO2011137959A1; CN102884266A

Abstract

The invention relates to an electrical door opener (10) comprising: a door opener housing (15) in which a locking element is arranged so as to be rotatably mounted on a rotary shaft (25); a spring-loaded adjusting bracket (40) which is arranged inside the door opener housing so as to be rotatably mounted and which is blocked or released by the locking element; a latch (20) which is operatively connected to the adjusting bracket (40) and blocks or releases a door latch; electromagnets (45, 50) which are operatively connected to the locking element; and a return spring. When current is not supplied to the electromagnets (45, 50), the return spring moves the locking element into a position in which the adjusting bracket (40) is blocked. According to the invention, the locking element comprises two parts, a locking lever (55) and a cascade (60), which are each at a different spacing from the respective associated electromagnet (45, 50), such that the forces of the locking lever (55) and cascade (60) acting on the adjusting bracket (40) are added when the electromagnets (45, 50) are supplied with current.

Description

Title: Door opener

The present invention relates to an electric door opener according to the preamble of claim 1.

Such an electric door opener has a locking element, which is formed in two parts and consists of a locking lever and a cascade, which have a different distance to the respective associated electromagnet, so that when energizing the electromagnets acting on the adjustment forces of locking lever and Add cascade. The prior art discloses electric door openers that are equipped with electromagnets that are energized to release a door latch. By energizing the electromagnets, a locking element is magnetically attracted by the electromagnet. The stroke travel of the locking element to be covered in this case overcomes a distance which prevails between the electromagnet and a locking lever in the non-energized state of the electromagnets.

The prior art involves the disadvantage that the magnetic force of the electromagnets decreases sharply with increasing distance between the locking element and the electromagnet. As a result, a small magnetic force is available at the moment of current supply to the electromagnets, the operating point, but a considerably larger magnetic force is required in order to move the locking element into a release position.

CONFIRMATION COPY Another disadvantage of the known electric door openers is that under the effects of preloads such as wind load, the required magnetic force at the operating point is too low to operate the door opener reliable.

It is therefore the object of the present invention to provide an electric door opener of small size, which bridges the distance between the locking element and the electromagnets when energizing the electromagnets and provides a sufficiently large magnetic force at the operating point, which ensures that the locking element functionally transported in a release position.

This object is achieved according to the preamble of claim 1 in conjunction with the characterizing features. Advantageous further developments of the invention are specified in the dependent claims.

The invention includes the technical teaching that the locking element is formed in two parts and consists of a locking lever and a cascade, which have a different distance from the respectively associated electromagnet, so that when energizing the electromagnets acting on the adjustment forces of Add locking lever and cascade.

The inventive embodiment has the advantage that in the locked state of the adjustment angle, the cascade can be positioned closer to the electromagnet associated with the cascade, since unlike the locking lever, it does not block or release the adjustment angle, but is mounted so as to be relatively freely rotatable on an axis. The locking lever has to maintain a predetermined by the present in the door opener lever ratios distance to the associated electromagnet, which can be ignored by the cascade. When energized the electromagnet is the operating point where the largest magnetic force is needed to move the locking lever to a release position. The added forces of locking lever and cascade acting on the adjustment angle ensure an increased magnetic force at the work point.

It is also advantageous that the distance of the cascade to the electromagnet is less than the distance of the locking lever to the electromagnet. Thus, when the electromagnets are energized, an increased magnetic force acts directly on the cascade in order to be able to pivot the cascade about the axis of rotation at which the cascade is arranged.

Another advantage is that the cascade is freely rotatably arranged on the axis of rotation. Due to the freely rotatable arrangement of the cascade, the cascade is independent of the prevailing lever ratios and independent of possible preloads that can act on the electric door opener. Thereby, the cascade can be positioned with a small distance to the associated electromagnet. It is also advantageous that the cascade has a driver which cooperates with current supply of the electromagnet with the locking lever while the locking lever at least partially entrains the electromagnet. This ensures that the distance between the locking lever and the associated electromagnet is reduced, whereby an increased magnetic force acts on the locking lever, which is used at the operating point.

A further preferred embodiment is that the locking lever and the cascade each have a separate solenoid is assigned. Thus, differentiating electromagnets can be used. It is also advantageous that when energizing the electromagnets, the distance between the locking lever surface of the locking lever and the locking lever associated electromagnet due to the driver of the cascade is reduced. Thus, the required magnetic forces are available directly at the operating point.

Furthermore, it is advantageous that in electroless electromagnet due to a arranged on the recording return spring and the driver, the distance between the locking lever surface and the electromagnet is greater than the distance between the cascade surface and the electromagnet. The locking lever is imposed by the present in the door opener housing leverage a predetermined distance that can ignore the cascade, whereby the cascade can be positioned with a smaller distance to the associated electromagnet.

It is also advantageous that the locking lever and the cascade are rotatably mounted on a rotation axis within the door opener housing. Thus, a simple arrangement is ensured in conjunction with the required leverage ratios within the door opener housing.

It is also advantageous that the locking lever with the rotary axis pin and the cascade with the rotary axis pin are rotatably mounted on the axis of rotation of the Türöffnergehäu- ses. As a result, a simple construction of the locking lever and the cascade is possible.

It is also advantageous that the locking lever is spring-loaded disposed within the door opener housing. In the de-energized state of the electromagnets, the locking lever is moved due to the spring load in the blocking position, in which the locking lever blocks the adjustment. It is advantageous that the receptacle for receiving the return spring is arranged in a portion of the locking lever surface of the locking lever. The return spring is to be installed in a simple and reliable way. It is also advantageous that the locking lever has a hook in a gate. Thus, a simple construction of the locking lever and a required hook for blocking the adjustment angle is guaranteed.

An advantageous embodiment is that the hook blocks or releases the adjustment angle. By the pivoting movement, which exerts the locking lever when energized and when withdrawing the energization of the electromagnets, the adjustment of the hook is blocked or released.

It is also advantageous that the driver of the cascade is arranged on the side opposite the cascade surface. Thus, the driver is given space to overcome a distance between the cascade and the locking lever can.

It is also advantageous that the driver is in operative connection with the locking lever in a portion of the plant surface. In the de-energized state of the electromagnets, the locking lever is moved due to the spring force of the return spring in the blocking position in which the locking lever blocks the adjustment. During this movement of the locking lever, the driver contributes to the spring force of the return spring being transmitted to the cascade, whereby the cascade is forcibly moved into the position in which the cascade is at a distance from the associated electromagnet, this distance being smaller is, as the distance between the locking lever and the electromagnet associated with the locking lever. Another advantage is that the electromagnets are energized simultaneously. This ensures that the required magnetic force is present at the operating point. The invention of a preferred embodiment will be further illustrated by the following description and drawings.

1: an electric door opener in a perspective view,

FIG. 2 shows the electric door opener from FIG. 1, with the individual parts of the electric door opener being removed, which are insignificant for the presentation of the invention,

FIG. 3 shows the electric door opener from FIG. 2 in a further perspective view;

FIG. 4 shows the cascade and the locking lever in the arrangement as they are arranged next to one another in the assembly;

5 shows the electric door opener from FIGS. 2 and 3 in a rear view, FIG. 6 shows the electric door opener from FIGS. 2 and 3 in the non-energized state in a view from the right, FIG.

FIG. 7 shows the electric door opener from FIGS. 2 and 3 in the non-energized state in a view from the left,

FIG. 8 shows the electric door opener from FIG. 3 without the adjustment angle in a further perspective view; FIG. 9 shows the electric door opener from FIGS. 2 and 3 in a view from the right, wherein the energization of the electric motor has just taken place, FIG. 10 shows the electric door opener from FIG. 9 in a view from the left, FIG.

11 shows the electric door opener from FIG. 3 without the adjustment angle in a further perspective view, the current supply of the electromagnets having just taken place, FIG.

Figure 12: the electric door opener of Figures 2 and 3 in one

View from the right, wherein the adjustment angle is released from the locking lever,

FIG. 13 shows the electric door opener from FIG. 12 in a view from the left,

FIG. 14 shows the electric door opener from FIG. 3 without the adjustment angle in a further perspective view, wherein the adjustment angle is released by the locking lever,

Figure 15: a diagram from which the ratios of the magnetic force in dependence on the distance are indicated.

Figure 1 shows the electric door opener 10 with a door opener housing 15, which has a rotation axis 25 which is also present on the opposite side of the door opener housing 15. A trap 20 is shown that blocks or releases a door latch.

FIG. 2 shows the electric door opener 10 from FIG. 1, with the individual parts of the electric door opener being removed, which are for illustration of the invention are insignificant. Thus, the adjustment angle 40 can be seen, which is blocked by the hook 80. The rotary shaft pin 30 corresponds to the axis of rotation 25 of the door opener housing 15. FIG. 3 shows the electric door opener 10 from FIG. 2 in a further perspective view, wherein a driver 75 and the rotary shaft pin 30 are arranged on the cascade 60. The cascade 60 is associated with the solenoid 50. The locking lever 55 is associated with the solenoid 45. The driver 75 is arranged on the cascade 60 and cooperates with the locking lever 55 in a portion of the contact surface 90.

In the figure 4, the cascade and the locking lever are shown in the arrangement, as they are arranged in the assembly within the door opener housing 15 side by side. The cascade 60 has a rotary shaft pin 30 and a cascade surface 70, wherein the cascade surface 70 cooperates with the electromagnet 50. The locking lever 55 has a rotary shaft pin 35 and a locking lever surface 65, wherein the locking lever surface 65 cooperates with the electromagnet 45. On the locking lever surface 65, a receptacle 85 for receiving a return spring is arranged in a section. The locking lever 55 further includes a hook 80 which blocks or releases the adjustment 40.

FIG. 5 shows the electric door opener 10 from FIGS. 2 and 3 in a rear view, wherein the state of the blocked adjustment angle is shown. The electromagnet 45 is disposed in the region of the locking lever 55 and is associated with the locking lever 55. The electromagnet 50 is disposed in the region of the cascade 60 and is associated with the cascade 60. The locking lever surface 65 has a greater distance to the electromagnet 45 than the cascade surface 70 to the electromagnet 50. FIG. 6 shows the electric door opener 10 from FIGS. 2 and 3 in the de-energized state in a view from the right, with the hook 80 of the blocking lever 55 blocking the adjustment angle 40. A return spring, not shown, is received by the receptacle 85, wherein the spring force of the return spring pivots the locking lever 55 due to the rotation axis 25 and the pivot pin 35 in the blocking position in which the hook 80 blocks the adjustment 40. The driver 75 is located on the plant surface 90. Due to the spring force of the return spring, not shown, the cascade 60 is also pivoted, wherein the Kas- kadenfläche 70 has a distance from the electromagnet 50. Since the electromagnets 45 and 50 are arranged on one level, FIG. 6 illustrates the different distances between the blocking lever surface 65 and the electromagnet 45 and between the cascade surface 70 and the electromagnet 50, wherein the distance between the blocking lever surface 65 and the electromagnet 50 Electromagnet 45 is greater than the distance between the cascade surface 70 and the electromagnet 50th

FIG. 7 shows the electric door opener 10 from FIGS. 2 and 3 in the de-energized state in a view from the left, wherein the hook 80 blocks the adjustment angle 40. The cascade 60 has a small distance to the electromagnet 50, wherein the driver 75 rests in a portion of the contact surface 90 of the locking lever 55.

FIG. 8 shows the electric door opener 10 from FIG. 3 without the adjustment angle 40 in a perspective view, wherein it can be seen that the locking lever surface 65 of the blocking lever 55 has a greater distance from the electromagnet 45 than the cascade surface 70 of the cascade 60 Electromagnet 50. FIG. 9 shows the electric door opener 10 from FIGS. 2 and 3 in a view from the right, the energization of the electromagnets having just taken place. The just done energization is about the operating point where the largest magnetic force is needed to move a locking lever to a release position. This is a static friction in a sliding friction, which act between the hook 80 of the locking lever 55 and the adjustment 40. Both electromagnets 45 and 50 are energized simultaneously, wherein the cascade 60 is magnetically attracted by the associated electromagnet 50. The driver 75 pivots the locking lever 55, wherein the locking lever surface 65 is conveyed in the direction of the electromagnet 45. As a result, the locking lever surface 65 of the locking lever 55 is closer to the electromagnet 45, wherein the hook 80 continues to block the adjustment 40. With this pivoting movement of the locking lever 55 due to the pivoting movement of the cascade 60 and the driver 75, which cooperates with a portion of the contact surface 90, the locking lever 55 and thus the locking lever surface 65 is brought closer to the electromagnet 45.

FIG. 10 shows the electric door opener 10 from FIGS. 2 and 3 in a view from the left, wherein the energization of the electromagnets has just taken place. The cascade 60 is attracted to the electromagnet 50 and abuts against the electromagnet 50. The driver 75 has the locking lever 55 pivoted in the direction of the electromagnet 45, wherein the hook 80, the adjustment angle 40 is still blocked.

FIG. 11 shows the electric door opener 10 from FIG. 3 without the adjustment angle in a perspective view, the energization of the electromagnets just taking place. Here, the cascade 60 is magnetically attracted by the electromagnet 50 and is applied to the electromagnet 50. The driver 75 cooperates in a portion of the contact surface 90 with the contact surface 90 and has pivoted the locking lever 55 in the direction of the electromagnet 45, the Sperrhebel- surface 65 having a smaller distance to the electromagnet 45 than in the de-energized state of the electromagnets 45 and 50th FIG. 12 shows the electric door opener 10 from FIGS. 2 and 3 in a view from the right in the energized state of the electromagnets 45 and 50, the adjustment angle 40 being released from the blocking lever 55. The electromagnet 45 attracts the locking lever 55, wherein the Sperrhe- beifläche 65 abuts against the electromagnet 45. In this position, the locking lever 55 and thus the hook 80 is pivoted about the axis of rotation 25 so far that the adjustment angle 40 is released from the hook 80. Furthermore, there is a distance between the driver 75 and the contact surface 90.

FIG. 13 shows the electric door opener 10 from FIGS. 2 and 3 in a view from the left in the energized state of the electromagnets 45 and 50, wherein the adjustment angle 40 is released from the blocking lever 55. The hook 80 is pivoted with the locking lever 55 such that the adjustment angle 40 is released. The driver 75 of the cascade 60 has a distance to the contact surface 90 of the locking lever 55.

FIG. 14 shows the electric door opener 10 from FIG. 3 without the adjustment angle 40 in a perspective view in the energized state of the electromagnets 45 and 50, the adjustment angle 40 being released from the blocking lever 55. The locking lever 55 and the cascade 60 are magnetically attracted by their associated electromagnet 45 and 50 and abut against them with the locking lever surface 65 and the cascade surface 70 at. The driver 75 has a distance to the contact surface 90 locking lever 55.

15 shows a diagram from which the ratios of the magnetic forces of the electromagnets 45 and 50 in dependence on the distance of the locking lever surface 65 to the electromagnet 45 and the cascade surface 70 to the electromagnet 50 are indicated. The magnetic force is indicated on the vertical with the symbol F and the unit Newton, whereby the distance on the horizontal with the symbol s and the unit mm is specified. Two points P1 and P2 exemplify how the magnetic forces change depending on distances. P1 shows by way of example a distance of 1 mm between the cascade surface 70 and the electromagnet 50 and a magnetic force of 0.8 N. P2 shows by way of example a distance of 2 mm between the blocking lever surface 65 and the electromagnet 45 and a magnetic force of 0.25 N. ,

With these example values, the function of the inventive embodiment will be described below, wherein the example values may vary in further embodiments of the invention.

In the inventive embodiment, the trap 20 blocks a door latch with the solenoids 45 and 50 de-energized. In this case, the adjustment angle 40, which is in operative connection with the latch 20, is blocked by the hook 80. A return spring, not shown, which is arranged with a first free end on the receptacle 85 of the locking lever 55 and rests with its second free end in the interior of the door opener housing 15 in a portion of the door opener housing 15, pivots due to their spring force the locking lever 55 such that Hook 80 blocks the adjustment angle 40 and the locking lever surface 65 has a distance of 2 mm from the electromagnet 45. The pivoting movement is due to the pivot pin 35 of the locking lever 55, wherein the rotary shaft pin 35 is rotatably mounted in the axis of rotation 25 of the door opener housing 15.

The cascade 60 has a rotary shaft pin 30 which is arranged in the axis of rotation 25 of the door opener housing 15, wherein the cascade 60 is disposed freely rotatably mounted inside the door opener housing 15. The cascade 60 furthermore has a driver 75, which interacts with the blocking lever 55 in a section of the contact surface 90 of the blocking lever 55. A part of the spring force of the return spring is due to the interaction between the plant surface 90 and the driver mer 75 to the cascade 60, whereby the cascade 60 is also pivoted and a distance between the cascade surface 70 and the electromagnet 50 of 1 mm is present. In the de-energized state of the electromagnets 45 and 50 have the locking lever surface 65 of the locking lever 55 and the cascade surface 70 of the cascade 60 different distances to the associated electromagnets 45 and 50. The locking lever 55 is associated with the electromagnet 45 and the cascade 60 is the electromagnet 50th associated, wherein the locking lever surface 65 cooperates with the electromagnet 45 and the cascade surface 70 cooperates with the electromagnet 50. In the de-energized state of the electromagnets 45 and 50, the distance between the locking lever surface 65 and the electromagnet 45 is greater than the distance between the cascade surface 70 and the electromagnet 50th

In this embodiment, the distance values are exemplified. The distance between the locking lever surface 65 and the electromagnet 45 is 2mm. The distance between the cascade surface 70 and the electromagnet 50 is 1 mm. Of course, in other embodiments, these values may vary.

To release the adjustment angle 40 and thus a door latch, it is necessary that the hook 80 is pivoted so far that the adjustment angle 40 is released from the hook 80. Due to existing lever ratios, a pivotal path of the locking lever 55 is necessary for this, which simultaneously leads to a minimum distance between the locking lever surface 65 of the locking lever 55 and the associated electromagnet 45 being maintained in the de-energized state of the electromagnets 45 and 50. By this minimum distance a small magnetic force of the electromagnet 45 acts on the locking lever 55, which is too low for the operating point. To release the adjustment angle 40, both electromagnets 45 and 50 are energized simultaneously. In this case, a magnetic force of 0.8 N of the electromagnet 50 acts on the cascade 60 and attracts the cascade 60 magnetically, wherein the cascade 60 is pivoted and the cascade surface 70 is applied to the electromagnet 50. The magnetic force of 0.8 N of the electromagnet 50 is formed because the distance between the cascade surface 70 and the electromagnet 50 is small, which is 1 mm in this embodiment. The force acting on the cascade 60 magnetic force of 0.8 N of the electromagnet 50 is transmitted via the driver 75 on the locking lever 55. In this case, the driver 75 bears against the contact surface 90 of the locking lever 55 and pivots the locking lever 55 such that the locking lever surface 65 approaches the electromagnet 45. Thus, the locking lever 55 is pivoted by the amount by which the cascade 60 is pivoted to the abutment of the cascade surface 70 on the electromagnet 50. As a result, in the de-energized state of the electromagnets 45 and 50 distance between the locking lever surface 65 and the electromagnet 45 is reduced from 2mm to 1mm, whereby the required Verschwenkweg of the locking lever 55 to release the adjustment angle 40 was partially made and thus the hook 80, the adjustment 40th still blocked.

By the approach of the locking lever surface 65 to the electromagnet 45, a magnetic force of 0.8 N of the electromagnet 45 acts on the locking lever 55. This magnetic force attracts the locking lever 55 magnetically, wherein the locking lever surface 65 rests against the electromagnet 45. As a result, the locking lever 55 is pivoted so far that the hook 80 releases the adjustment 40. As a result, there is a required magnetic force at the operating point in order to enable the adjustment angle 40 to function reliably even with possible preloads. In the diagram of FIG. 15, values are given that are exemplary and merely intended to illustrate the invention.

The first point P1 represents that the distance from the cascade 60 to the solenoid 50 has a value of 1 mm, with a magnetic force of the electromagnet 50 of 0.8 N present. The second point P2 represents that the distance from the lock lever 55 to the solenoid 45 has a value of 2mm, with a magnetic force of the solenoid 45 of 0.25N being present. In this example, the 2mm amount to the minimum distance that is required to pivot the locking lever 55 to release the adjustment angle 40 can.

In this example, there is a total magnetic force at the operating point for releasing the adjustment angle 40 of 1.05 N when the electromagnets 45 and 50 are energized.

If, for example, the distances from the blocking lever 55 and the cascade 60 to the respective associated electromagnets 45 and 50 were the same, in this case 2 mm, for example, total magnet forces of 0.5 N would be present when the electromagnets 45 and 50 were energized be to release the adjustment angle 40 can.

This inventive embodiment ensures that even with possible preloads occurring the function of the electric door opener 10 is ensured.

The two-part design of the locking element and the use of different distances of the two-part locking element to associated magnets are transferable to devices that are equipped with electromagnets. LIST OF REFERENCE NUMBERS

10 electric door opener

15 door opener case 0 trap

5 axis of rotation

0 Rotary axis pin 5 Rotary axis pin 0 Adjusting angle 5 Electromagnet 0 Electromagnet 5 Locking lever

0 cascade

5 locking lever surface 0 cascade surface 5 drivers

0 hooks

5 recording

0 plant area

Claims

claims

1. Electric door opener (10)

- With a door opener housing (15), in which a locking element is rotatably mounted on a rotational axis (25),

- With a within the door opener housing (15) rotatably mounted and spring-loaded adjustment angle (40) which is blocked or released by the locking element,

with a latch (20) which is in operative connection with the adjustment angle (40) and blocks or releases a door latch,

- with electromagnets (45, 50), which are in operative connection with the locking element,

with a restoring spring which, in the de-energized state of the electric magnets (45, 50), conveys the locking element into a position in which the adjustment angle (40) is blocked,

characterized in that

- The locking element is formed in two parts and consists of a locking lever (55) and a cascade (60), which have a different distance from the respectively associated electromagnets (45, 50),

- So that upon energization of the electromagnets (45, 50) on the adjustment angle (40) acting forces of locking lever (55) and cascade (60) add. 2. Electric door opener (10) according to claim 1, characterized in that the distance of the cascade (60) to the electromagnet (50) is less than the distance of the locking lever (55) to the electromagnet (45). 3. Electric door opener (10) according to claim 1 or 2, characterized in that the cascade (60) is freely rotatably mounted on the axis of rotation (25). Electric door opener (10) according to claim 3, characterized in that the cascade (60) has a driver (75) which cooperates with current supply of the electromagnet (50) with the locking lever (55) while the locking lever (55) at least partially entrains the electromagnet (45).

Electric door opener (10) according to claim 4, characterized in that the locking lever (55) is associated with the electromagnet (45) and the cascade (60) of the electromagnet (50) is associated.

Electric door opener (10) according to claims 1 and 4, characterized in that in electroless electromagnets (45, 50) due to a on a receptacle (85) arranged return spring and the driver (75), the distance between a locking lever surface (65) and the electromagnet (45) is greater than the distance between a cascade surface (70) and the electromagnet (50).

Electric door opener (10) according to claim 1, characterized in that the locking lever (55) spring-loaded within the door opener housing (15) is arranged.

Electric door opener (10) according to claims 6 and 7, characterized in that the receptacle (85) for receiving the return spring in a portion of the locking lever surface (65) of the locking lever (55) is arranged.

9. Electric door opener (10) according to claim 1, characterized in that the locking lever (55) in a gate has a hook (80).

10. Electric door opener (10) according to claim 9, characterized in that the hook (80) blocks or releases the adjustment angle (40).

Electric door opener (10) according to claims 4 and 6, characterized in that the driver (75) of the cascade (60) on the cascade surface (70) opposite side is arranged.

Electric door opener (10) according to claims 4 and 11, characterized in that the driver (75) with the locking lever (55) in a portion of a contact surface (90) is in operative connection.

13. Electric door opener (10) according to claims 4 and 5, characterized in that the electromagnets (45, 50) are simultaneously energized.