SYSTEM FOR DETECTION OF THE POSITION OF THE CLOSING LEAF FOR A BARRIER DURING ITS HANDLING

Abstract

System for detecting the movement conditions of the leaf (2) closing a barrier, this leaf being able to occlude a delimited opening or passage and in which the leaf itself is moved by a motor (5) whose rotation shaft (R1) is associated with a motion transmission mechanism to this leaf. On said motor is present a first device for measuring the rotation of said rotation shaft (R1), and at least a second measuring device is associated with at least a second rotation shaft (R2), said second rotation shaft being connected to the first shaft by means of a reduction gear (8), whose reduction ratio is non-integer.

Claims

1. System for detecting the movement conditions of the leaf (2) closing a barrier, this leaf being able to occlude a delimited opening or passage and in which the leaf itself is moved by a motor (5) whose rotation shaft (R1) is associated with a motion transmission mechanism to this leaf, characterized in that it comprises on said motor a first device for measuring the rotation of said rotation shaft (R1), and at least a second measuring device associated with at least a second rotation shaft (R2), said second rotation shaft being connected to the first shaft by means of a reduction gear (8), whose reduction ratio is non-integer.

2. System according to claim 1, wherein when one of the two rotation shafts (R1 or R2) performs an entire number of revolutions, the other shaft, due to the effect of the non-linear reduction ratio, performs a predetermined number of revolutions plus (or minus) a phase shift angle, this angle contains the indication of how many turns the shaft that having an integer number of turns has made.

3. System according to claim 1, in which, when the phase shift angle is measured in revolutions, its decimal part indicates the number of revolutions made by the shaft that performed the whole rotations.

4. System according to claim 1, wherein both such measuring devices are of the magnetic, capacitive, optical or resistive type.

5. System according to claim 4, in which both such measuring devices comprise a magnet (M1, M2) associated with the respective rotation shaft and a relative sensor (S1, S2) adapted to intercept the variations in the magnetic field.

6. System according to claim 1, in which said leaf (2) is a leaf of a gate sliding on a track (3) placed at the base of the passage, the motor (5) determines the movement of the leaf by means of the motion transmission comprising a rack (6) arranged longitudinally on the leaf and a pinion (7) keyed on the rotation shaft (R1) of this motor.

7. System according to claim 5, in which both the magnets (M1 and M2) and the reducer (8) are placed inside a suitable container, while the detection is carried out from the outside by placing the sensors (S1, S2) outside this container.

8. System according to claim 1, in which said measuring devices are connected to a door movement control unit that can manage the movement of the door itself by evaluating the measurements made.

9. System according to claim 1, wherein the first rotational device (R1) is provided directly on the motor.

10. System according to claim 1, wherein said reduction comprises a plurality of gears each mounted on a corresponding shaft, further rotation sensors may be present on at least one of such shafts.

Description

[0019] FIG. 1 is a schematic view of a gate with a sliding leaf to which the system according to the present invention is applied;

[0020] FIG. 2 is an enlarged detail of the area indicated with the arrow F of FIG. 1, illustrated exploded.

[0021] The system according to the present invention can be applied to a barrier having at least one sliding leaf 2 adapted to obstruct a delimited opening or gap and in which the leaf itself is moved by a motor the rotational shaft of which is associated with a mechanism for transmitting motion to such a leaf.

[0022] The example case illustrated concerns a gate having a sliding leaf 2 on a track 3 arranged at the base of the gap through wheels 4 or similar means adapted for sliding such a leaf along the gap.

[0023] A suitable motor 5 causes the movement of the leaf through the mechanism for transmitting motion to such a leaf comprising a rack 6 arranged longitudinally on the leaf and a pinion 7 keyed onto the rotational shaft R1 of such a motor.

[0024] According to the present invention a first device for measuring the rotation of such a shaft is associated on the rotational shaft R1 of such a motor. Advantageously, the system according to the present invention also comprises a second measuring device associated with at least a second rotational shaft R2. Such a second rotational shaft being connected to the first shaft through a reduction gear mechanism 8, which causes a predetermined reduction ratio thereof.

[0025] Said reduction gear can comprise a plurality of gears each mounted on a corresponding shaft. According to the present invention, further rotation sensors may be present on at least one of shafts of the reduction gear mechanism. In this way it is possible to improve the resolution of the measurements made by the sensors In practice, these measuring devices operate substantially as encoders and can be made in an equivalent way with technologies of the resistive, capacitive optical or magnetic type.

[0026] Both the first measuring device and the second are preferably made by means of magnets M1 and M2 which rotate together with the respective shafts. The rotation signal of the magnets can be intercepted by as many magnetic field sensors S1 and S2.

[0027] In an alternative embodiment the first device R1 is in the motor which is provided with its own rotational measuring device as a typical encoder or motor rotation sensor than can internally increment and decrements the counts increasing the accuracy of the position of the gate. Therefore only the second shaft is provided with a specific rotational measuring device because the rotation on the first shaft is directly provided by the motor. Typically, a brushless magnet sensor in a BLDC motor can be used.

[0028] Such devices measure the angular position (n1, n2) of the rotating magnets. Each rotation of the shaft corresponds to a predetermined linear displacement of the door. Therefore, by measuring the angular position, the position of the door can be determined at any time. In addition, the first device being keyed directly on the shaft of the motor that moves the leaf is also able to measure the effort, the speed or the torque imparted by the motor to move the leaf. Therefore, in the event that there are variations in said stress, for example due to the presence of an obstacle on the barrier, the measuring device is able to detect it.

[0029] Clearly, the two measuring devices can be connected to a control unit for the movement of the leaf, or of the gate in general, which can manage the movement of that leaf by evaluating the measurements made.

[0030] Advantageously, the device made using magnets has the advantage that both magnets and the reducer can be isolated inside a special container, while the detection can be carried out from the outside by placing sensors S1 and S2 outside this container.

[0031] The meaning of the double device is to allow the first to detect the position of the leaf by substantially counting the revolutions made by the crankshaft, while the second measuring device makes a more detailed reading based on the reduction ratio.

[0032] This reduction ratio, according to the present invention, is a non-integer ratio between the two shafts, so as to obtain a periodicity that in the instant in which there is a complete revolution of the second rotation shaft R2 (or of the first R1) the first shaft R1 (or of the second shaft R2) has not made an integer number of revolutions and therefore is slightly out of phase with respect to an integer value. This offset angle between the first shaft and the second shaft also provides information on the number of rotations performed by the first shaft (or second shaft). In fact, the phase shift will increase as the number of laps performed increases. In practice, when one of the two rotation shafts (R1 or R2) carries out an entire number of revolutions, the other shaft, due to the effect of the non-linear reduction ratio, carries out a predetermined number of revolutions plus (or less) a phase shift angle. This angle carries with it or contains an indication of how many turns the other shaft (R2 or R1) has made.

[0033] When the phase shift angle is measured in revolutions, its decimal part indicates the number of revolutions made by the shaft that performed the whole rotations.

EXAMPLE OF APPLICATION

[0034] The following table shows the rotations performed by the first shaft and those performed by the second shaft with a reduction ratio of 2.1.

TABLE-US-00001 Number of laps R1 Number of laps R2 0.0 0.0 2.1 1.0 4.2 2.0 6.3 3.0 8.4 4.0 10.5 5.0 12.6 6.0 14.7 7.0 16.8 8.0 18.9 9.0 21.0 10.0

[0035] When the second shaft makes one revolution, the first shaft makes 2.1 revolutions, which causes a phase shift of 0.1 revolutions between the two at this point. The decimal part of the phase shift (i.e. 1) also corresponds to the number of revolutions made by the second shaft.

[0036] Furthermore, when the second shaft makes four turns, the first shaft makes 8.4 turns, which causes a phase shift of 0.4 turns between the two at this point. The decimal part of the phase shift (i.e. 4) also corresponds to the number of revolutions made by the second shaft.

[0037] In this way, in the event that the signal received by the sensor of the second shaft is lost, for example due to a power cut, by visually evaluating the phase shift between the first and second shaft, it is possible to retrieve the information also on the number of revolutions performed from the first shaft and therefore, in general, what was the movement of the leaf.

[0038] An advantage of the fact of making a magnetic detection or measurement device is that the detection of the rotation and therefore the determination of the position of the door can be carried out even in a situation of absence of power supply. For example, in a situation where the gate is unlocked due to a motor failure and moved manually, the reading of the position takes place anyway.

[0039] The combination of the two measurements determines a precise detection of the stroke and position of the door. Therefore, this system can be used to determine the stroke of the leaf and therefore to establish the limit switch positions. As an alternative embodiment the system can also be used as a movement control device in general, for example to control the speed and reduce the speed itself near the limit switch positions, and also as an anti-crushing device.

[0040] Two examples of embodiments using two sensors Sa and Sb and with non-integer reduction ratios are reported below.

[0041] In the following: [0042] A is the low speed shaft. [0043] B is the high speed shaft directly connected to the pinion of the motor. [0044] Ra are the revolutions of A. [0045] Rb are the revolutions of B (that is the position of the gate). [0046] RR is the reduction ratio Rb/Ra. [0047] Sa is the value of angular sensor on A (1=360°). [0048] Sb is the value of angular sensor on B (1=360°). [0049] P is the period of the system, that is the maximum range of Rb, after that both sensors return to the initial positions.

[0050] Furthermore: [0051] [n] is the integer part of the number n. [0052] {n} is the fractional part of the number n.

[0053] The sensors measure the fractional part of the total rotation R.

[0054] Sb={Rb}={Ra×RR}

[0055] Since Ra=[Ra]+{Ra}=[Ra]+Sa

[0056] Sb={Ra×RR}=([Ra]+Sa)×RR 1={[Ra]×RR+Sa×RR}

[0057] Since RR=[RR]+{RR}

[0058] Sb={[Ra]×[RR]+[Ra]×{RR}+Sa×RR}

[0059] Since [Ra]×[RR] is an integer number it's not relevant on the fractional value.

Sb={[Ra]×{RR}+Sa×RR}(Eq.1).

First Example

[0060] In said example, the fractional part of the reduction ratio is not zero, but 1 is divisible by it, that is 1/{RR}=K integer, for each revolution of the shaft A, Sb increase of the fractional part of the reduction ratio.

[0061] The Period of the System is:

[0062] P=RR×K=RR/{RR}

[0063] Therefore, the maximum range is K times the range of case 1.

[0064] In a period there are K revolutions of the shaft A.

[0065] Measuring Sa and Sb, it's possible to calculate [Ra] by Eq. 1.

[0066] Then the Position of the Gate is:

[0067] Rb=Ra×RR=(Sa+[Ra])×RR

[0068] Here the sensor B can used just to calculate [Ra], but, Sb can be used to achieve a better resolution adjusting the Rb value calculated by Sa with the previous equation.

Second Example

[0069] In said example the fractional part of the reduction ratio is not zero, and 1 is not divisible by {RR}, that is 1/{RR} is not an integer, but 1/{RR}=K+k, where K is the integer part and k is the fractional part.

[0070] The period is P=RR×10{circumflex over ( )}n

[0071] where n is the number of decimal digits of RR.

[0072] In this case, only in the first K revolutions of A the increase of Sb is constant:

[0073] DSb={RR}.

[0074] From the revolution K to the revolution K+1 there is a roll over of Sa and

[0075] Dsb=({RR}×K)−1.

[0076] This happens every K revolutions of A.

[0077] In this Case the Period is

[0078] P=RR×K=RR×[1/{RR}].