METHOD FOR TESTING A DOOR OPERATOR

Abstract

A method (1000) for testing of a door operator (100), said door operator (100) being configured to via a mechanism (104) move at least one door leaf (200) between an first position and a second position, the door operator (100) comprising a first drive unit (102) configured to optionally move the door leaf (200) into said first position, said door operator (100) further comprising a control unit (103) connected to a sensor (105).

Claims

1. A method (1000) for testing of a door operator (100), said door operator (100) being configured to via a mechanism (104) move at least one door leaf (200) between a first position and a second position, the door operator (100) comprising a first drive unit (102) configured to optionally move the door leaf (200) into said first position, said door operator (100) further comprising a control unit (103) connected to a sensor (105), the method comprising: initiating (1001) a simulated powerless mode, in which the first drive unit (102) will power the movement of the door leaf (200) into the first position and in which the control unit (103) is still electrically connected, measuring (1002) by the sensor (105) how the door operator (100) moves the mechanism (104) and the associated at least one door leaf (200) to the first position, and comparing (1003) the measured values of the movement of the mechanism (104) by means of the control unit (103) with reference values for the movement of the mechanism (104) and the associated door leaf (200).

2. Method (1000) for testing a door operator (100) according to claim 1, wherein the door operator (100) comprises an electrically powered second drive unit (101) configured to generate mechanical power to move the door leaf between the first and the second position, and wherein the initiation (1001) of the simulated powerless mode includes deactivating the second drive unit (101).

3. Method (1000) for testing a door operator (100) according to claim 2, wherein the sensor (105) is an encoder (105) connected to an electric motor (101a) of the second drive unit (101) and wherein the encoder (105) measures the rotation of the electric motor (101a).

4. Method (1000) for testing a door operator (100) according to claim 2, the method further comprising a latch check (1004), wherein the first position is a closed position of the door leaf (200), comprising activating the second drive unit (101) to try to open the door leaf (200) once it has reached its first position, and detecting by the sensor (105) whether the door leaf (200) can be opened by the second drive unit (101) or not.

5. Method (1000) for testing a door operator (100) according to claim 1, wherein the method is performed automatically at predetermined time intervals and/or by manual activation of the test method (1000)

6. Method (1000) for testing a door operator (100) according to claim 1, wherein the reference values include that the door leaf (200) moves between the first and the second position or vice versa in between 4-10 seconds.

7. Method (1000) for testing a door operator (100) according to claim 1, wherein the first position is a closed position of the door leaf (200), and wherein the reference values include that a time to complete a last 10° of movement of the door leaf (200) into the closed position is greater than about 1.5 seconds.

8. Method (1000) for testing a door operator (100) according to claim 1, further comprising generating (1005) an output signal based on the result of the comparison (1003).

9. A door operator (100), said door operator (100) being configured to via a mechanism (104) move the at least one door leaf (200) between the first position and the second position, the door operator (100) comprising the first drive unit (102) configured to optionally move the door leaf (200) into said first position, said door operator (100) further comprising the control unit (103) connected to the sensor (105), wherein said door operator (100) being configured to perform the method (1000) according to claim 1.

10. Door operator (100) according to claim 9, further comprising an electrically powered second drive unit (101) configured to generate mechanical power to move the door leaf between the first and the second position, and wherein the initiation (1001) of the simulated powerless mode includes deactivating the second drive unit (101).

11. Door operator (100) according to claim 9, wherein the first drive unit (102) comprises a spring being configured to store energy from the movement of the associated door leaf (200) in one direction optionally useable to subsequently move the door leaf (200) in an opposite direction.

12. Door operator (100) according to claim 10, wherein the powered second drive unit (101) comprises an electric motor (101), comprising a permanent magnet DC motor (101) configured to power the mechanism (104) to move the associated door leaf (200).

13. Door operator (100) according to claim 12, wherein the sensor (105) comprises an encoder (105) connected to the electric motor (101), the encoder (105) measuring the rotation of the electric motor (101).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] The present invention will be described further below by way of example and with reference to the enclosed drawings. In the drawings:

[0021] FIG. 1 shows a front view of a door leaf and a door operator according to one embodiment,

[0022] FIG. 2 shows a schematic drawing of a door operator according to one embodiment, and

[0023] FIG. 3 shows a schematic flowchart of a method for testing a door operator according to one embodiment.

DETAILED DESCRIPTION OF EMBODIMENTS

[0024] Embodiments of the invention will now be described with reference to the accompanying drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. The terminology used in the detailed description of the particular embodiments illustrated in the accompanying drawings is not intended to be limiting of the invention. In the drawings, like numbers refer to like elements.

[0025] FIG. 1 shows a door leaf 200, here a single door leaf 200 of a swing door type, but the teachings herein may just as well be applied to double swing door leafs 200. The door leaf 200 is hinged at a lateral side to the door frame in a conventional manner. The door leaf 200 may be moved manually or by means of a door operator 100. The door operator 100 may be controlled by means of sensors such as motion detectors, e.g. IR-detectors (not shown), and/or by means of a push button 106. The door operator 100 may be mounted to the wall above the door leaf 200, and attaches to the door leaf 200 by means of a mechanism 104. The door operator 100 may also be of the door mounted type, where the door operator 100 is mounted on the door leaf 200 and being connected to the door frame or wall via the mechanism 104.

[0026] The mechanism 104 may comprise one or several arms and/or rails which are moveable by means of the door operator 100 to achieve a corresponding movement of the door 200. Preferably, the mechanism 104 comprises at least one arm connected and rotatable by means of a rotatable output shaft 108 from the door operator 100. The shaft 108 is in turn connected to a first drive unit 102 and, in embodiments comprising a second drive unit 101, also to the second drive unit 101. The teachings herein are not however limited to a specific type of door operator 100, and the skilled person would realize that the door operator itself may embodied in many different forms.

[0027] The door leaf 200 is moveable between a first position and a second position and the door operator 100 comprises a first drive unit 102 configured to optionally move the door leaf 200 into the first position. The first drive unit 102 may be a spring biased drive unit 102, which stores energy as the door leaf 200 is brought into the second position. The first drive unit 102 may then use the stored energy to bring the door leaf 200 from the second position to the first position. In a preferred embodiment, the first position is one where the door leaf 200 is closed and the second position is thus an open position of the door leaf 200. This would be the case for instance for a fire door. However, the opposite may be true for doors which needs to be opened for facilitating evacuation. The first position would then be an open position of the door leaf 200, while the second position is a closed position.

[0028] The door operator 100 further comprises a control unit 103 connected to a sensor 105. The control unit 103 may be constituted by any suitable central processing unit CPU, microcontroller, Digital Signal Processor DSP, etc., capable of executing computer program code. The control unit 103 may be implemented using instructions that enable hardware functionality, for example, by using executable computer program instructions in a general-purpose or special-purpose processor that may be stored on a computer readable storage medium (disk, memory etc.) also comprised in the door operator 100 and to be executed by such a processor. The control unit 103 may be implemented using any suitable, publically available processor or Programmable Logic Circuit (PLC). The memory may be implemented using any commonly known technology for computer-readable memories such as ROM, RAM, SRAM, DRAM, FLASH, DDR, SDRAM or some other memory technology etc.

[0029] The sensor 105 is configured to detect the movement of the door leaf 200, which may be performed by measuring the movement of the door leaf 200 itself, measuring on the mechanism 104 connecting the door operator 100 to the door leaf, or by measuring on components within the door operator 100 itself. Naturally, the door operator 100 may comprise several sensors 105, as would be realized by the skilled person. The sensor 105 may comprise a proximity sensor (e.g. IR, capacitive, inductive, touch switches etc.), a hall sensor, or other types of sensors for detecting position, rotation and/or movement. Also inertia sensors, accelerometers, gyroscopic sensors, force sensors etc. are considered.

[0030] In one preferred embodiment shown in FIG. 2, the door operator 100 comprises a second drive unit 101 which is electrically powered in order to provide automated movement of the door leaf 200. The second drive unit 101 comprises an electric motor 101a, preferably a permanent magnet DC motor 101a configured to power the mechanism 104 to open and/or close the associated door leaf 200. The electric motor 101a may be connected to the mechanism 104 by a number of spur gears 107, levers and/or cam surfaces etc. Preferably, the electric motor 101a output shaft 110 powers a worm gear 107. The worm gear 107 is connected via spur gears to the output shaft 108 from the door operator 100, which forms part of the mechanism 104. The output shaft is also connected to a cam mechanism 109. The cam mechanism 109 rotates with the output shaft 108 and pushes on a lever 111 which is connected to the first drive unit 102. When the lever 111 moves will the spring 102a of the first drive unit 102 move accordingly. The spring 102a of the first drive unit 102 may via the lever 111 and the cam mechanism 109 power the output shaft 108 (i.e. also the mechanism 104). The second drive unit 101 (the electric motor 101a thereof) will in such circumstances rotate accordingly. The first drive unit 102 may only power the movement of the mechanism 104 in one direction, while the second drive unit 101 naturally may drive the door leaf 200 in either direction depending on which way the electric motor output shaft 110 is rotated. The first and second drive units 102, 101 will move together regardless of the if the first or second drive unit 102, 101 is powering the movement of the door leaf 200.

[0031] The movement of the door leaf 200 may during the normal electrically powered mode be monitored using feedback control, with the control unit 103 constantly monitoring sensor 105 input and controlling the first and/or second drive unit 102, 101 in order to make sure that the correct movement profile is achieved.

[0032] However, the door leaf 200 must be closed/opened automatically during certain circumstances. For instance, if there is a fire, it may be required that the door leaf 200 is closed in order to meet fire safety requirements. The door operator 100 must be able to move the door leaf 200 also when there is no electrical power available, i.e. in a powerless mode. The movement of the door leaf 200 in the powerless mode must also meet specific requirements, i.e. the door leaf 200 must not be closed to rapidly or too slowly nor with too high/too low force. It may also be preferred that the door leaf 200 manages to latch securely in the door frame, such that the door leaf 200 is not held in a semi-open position, as this may compromise e.g. fire protection by the door leaf 200.

[0033] The first drive unit 102 may power the movement of the door leaf 200 at least during the powerless mode. However, in the powerless mode, the movement of the door leaf 200 cannot be controlled via a feedback loop as the control unit 103 will be unpowered. Instead, the damping/braking of the movement of the door leaf 200 powered by the first drive unit 102 must be preset to achieve the desired movement. The damping/braking preset is generally performed when installing or servicing the door operator 100, as the damping required varies e.g. with type and size of the door leaf 200. In the preferred embodiment, the electric motor 101a of the second drive unit 101 provides the damping/braking effect by functioning as a generator, being powered by the closing movement of the door leaf 200 by the first drive unit 102. By varying the electrical resistance that the electric motor 101a is subjected to, the amount of damping can be varied. The damping may also be adjusted mechanically, for instance by altering the pretension for the spring 102a.

[0034] In FIG. 3 is a schematic flow chart shown of a method to test the door operator 100, more specifically its compliance to requirements regarding movement of the door leaf 200 in powerless mode. The method comprises initiating 1001 a simulated powerless mode, in which the first drive unit 102 will power the movement of the door leaf 200 into the first position and in which the control unit 103 is still electrically connected. The sensor 105 measures 1002 how the door operator 100 moves the mechanism 104 and the associated at least one door leaf 200 to the first position. The measured values describing the movement of the mechanism 104 are then compared 1003 by means of the control unit 103 with reference values, which are discussed below, for the movement of the mechanism 104 and the associated door leaf 200.

[0035] The method may either be initiated by a technician or be performed entirely automatically. For instance, the method may be performed at certain time intervals.

[0036] In case the measured values deviates from the acceptable required values for the movement of the door, the door operator 100 may be configured to generate 1005 an output signal based on the result of the comparison 1003. The output signal can be interpreted by a technician and indicates that service is necessary, and how the door operator 100 induced movement of the door leaf 200 deviates from the intended movement. The output signal may be generated via a relay to a billing automation system. The output signal may also be embodied as a wireless RF signal, such as WIFI, Bluetooth etc.

[0037] In the preferred embodiment, the door operator 100 comprises an electrically powered second drive unit 101 configured to generate mechanical power to move the door leaf between the first and the second position. The initiation 1001 of the simulated powerless mode may include deactivating the second drive unit 101, thus disallowing that it is used to actively control the movement of the mechanism 104 and the door leaf 200 via feedback control. The sensor 105 may as mentioned be embodied as an encoder 105 connected to an electric motor 101a of the second drive unit 101 and the sensor 105 measures the rotation of the electric motor 101a in order to determine how the door leaf 200 moves into the first position, solely powered by the first drive unit 102.

[0038] In one embodiment, the method further comprises a latch check 1004. The latch check activates the second drive unit 101 to try to open the door leaf 200 once it has reached its first position, where the first position is the closed position of the door leaf 200. The sensor 105 detects whether the door leaf 200 can be opened by the second drive unit 101 or not

[0039] The reference values for the movement of the door leaf 200 should preferably include at least that the door leaf 200 moves between the open and the closed position or vice versa in between 4-10 s. Even more preferably, between a 90° open position and a closed position in 4-10 s. The reference values may also include that the last 10° of movement of the door leaf 200 into the closed position should preferably take at least 1.5 s.

[0040] It should be mentioned that the inventive concept is by no means limited to the embodiments described herein, and several modifications are feasible without departing from the scope of the appended claims. In the claims, the term “comprises/comprising” does not exclude the presence of other elements or steps. Additionally, although individual features may be included in different claims, these may possibly advantageously be combined, and the inclusion in different claims does not imply that a combination of features is not feasible and/or advantageous. In addition, singular references do not exclude a plurality. The terms “a”, “an”, “first”, “second” etc do not preclude a plurality. Reference signs in the claims are provided merely as a clarifying example and shall not be construed as limiting the scope of the claims in any way.