JP3783719B2 - Elevator equipment - Google Patents

Description

  The present invention relates to an elevator apparatus, and more particularly to an elevator apparatus using a synchronous motor using a permanent magnet for a hoisting machine.

  A hoisting machine using a synchronous motor, particularly a permanent magnet motor, is installed in an elevator shaft, and a traction elevator that effectively uses the entire space of the building has been proposed and put into practical use.

In the case of a synchronous motor using a permanent magnet, it is necessary to detect the position of the magnetic pole. Title: Introduction to servo technology for mechatronics (issue date: October 30, 1986 issue place: Nikkan Kogyo) Fig. IV · 5.1 · SM type AC servo control block diagram on page 81 of Shimbun). In addition, as shown in Fig. IV , 2 and 3 servo motor structure on page 57 of the same document, the detector is mounted on the non-load side. The detector includes a Z phase for detecting the position of the magnetic pole, an A phase and a B phase for detecting the rotation speed and the rotation direction.

If the side fitted with a magnetic pole detector of the driving motion motor becomes the elevator shaft wall, after installation of the elevator system, when replacing the magnetic pole detector, that Ru precisely align the magnetic pole detector to the position of the magnetic poles Can not.

  An object of the present invention is to provide an elevator apparatus capable of accurately aligning magnetic poles even when replacing a magnetic pole detector after installation.

To achieve the above object, the present invention provides a traction sheave fixed to a rotating body driven by a permanent magnet electric motor, a hoisting rope wound around the traction sheave, and a hoisting rope that can be moved up and down by the hoisting rope. In the elevator apparatus equipped with a car in the elevator shaft, the permanent magnet motor is disposed between one elevator shaft wall and the vertical projection space of the car, and the traction sheave is connected to the elevator shaft wall. A space is formed on the inner diameter side of the member that supports the rotating body via a bearing and on the side opposite to the elevator shaft wall via a bearing, and the magnetic pole position of the permanent magnet type electric motor is The detector to detect was installed in the inside of the space.

  According to the said structure, after installing an elevator apparatus in an elevator shaft, when replacing | exchanging a detector, a magnetic pole position can be exactly matched.

  When the detector needs to be replaced after installing the hoisting device on the elevator shaft, it can be replaced in the elevator shaft without removing the hoisting device.

  Hereinafter, the structure of the elevator apparatus used as the object of the present invention will be described with reference to FIGS. 1 and 2.

  A car 1 and a counterweight 2 are suspended on a hoisting rope 3 of the elevator. The car 1 is suspended by winding a hoisting rope 3 around a pair of turning pulleys 4 (4a, 4b) pivotally supported at the lower part. A hoisting device 6 having a traction sheave 7 around which the hoisting rope 3 is wound is arranged on the uppermost part of the elevator shaft.

  The car 1 and the counterweight 2 move up and down the elevator shaft along the car guide rails 8a and 8b and the counterweight guide rails 9a and 9b that guide them. Each guide rail is supported by a wall of the elevator shaft or a building beam via a guide rail support, which is not shown.

  The hoisting rope 3 runs as follows. One end of the hoisting rope 3 is fixed to the fixing means 12 of the machine base 10 located at the uppermost part of the elevator shaft. The hoisting rope 3 from the fixing means 12 descends until it meets the turning pulley 5 pivotally supported by the counterweight 2. When the turning pulley 5 is wound, the hoisting rope 3 rises again and is wound around the traction sheave 7 of the hoisting device 6. The hoisting rope 3 wound around the traction sheave 7 descends to the car 1 side, passes through turning pulleys 4 (4a, 4b) supporting the car 1, and the uppermost fixing means ( It rises to 13) in FIG. The other end of the hoisting rope 3 is fixed by this fixing means (13 in FIG. 2). A machine base 10 is stacked and fixed on the upper ends of the counterweight guide rails 9a and 9b. A fixing means 12 at one end of the hoisting device 6 and the hoisting rope 3 is attached and fixed to the machine base 10 to firmly hold the respective vertical loads.

  The space between the hoisting device 6 and the wall 14 of the elevator shaft is very small. In the state where the hoisting rope 3 is wound around the traction sheave 7, it is impossible to replace the parts on the back side of the hoisting device 6.

FIG. 3 shows an example of a specific configuration of the hoisting device 6. The traction sheave 7 is fixed to the rotating body 22 by bolts 26a and 26b. A support shaft 21 is fixed to the base structure 20 of the hoisting device 6. The rotating body 22 is supported by bearings 27a and 27b and rotates around the support shaft 21. The rotating body 22 has a peripheral wall concentric with the support shaft 21, and a plurality of permanent magnets 22a are fixed to the inner periphery thereof. Fixed iron core 24a which faces the inner diameter side through these permanent magnets 22a and the circumferential direction of the small air gap is set around the fixed winding 24b, and is fixed to the base structure 20 by bolts 25.

  The support shaft 21 forms a space 21a inside the anti-base structure 20 side, and a detector 29b is accommodated therein. The magnetic pole position signal Z and the rotation output signals A phase and B phase of the detector 29b are output to the terminal block 33 at the top of the base structure 20 via the output line 30a, the connectors 33a and 33b, and the output line 30b.

The detector 29b is fixed to the detector fixing plate 30 by a metal fitting 29c. The rotating shaft 29a of the detector 29b is fixed to the detector shaft fixing plate 28. The detector fixing plate 30 is fixed to the support shaft 21 by guide pins 32a. The detector shaft fixing plate 28 is supported on the rotating body 22 by guide pins 31a. The guide pins 31a and 32a are for centering, and fixing bolts (not shown) are provided separately. Since the length of each guide pin is for centering, it is about 3 to 5 mm from the axial surface of the support shaft 21 and the rotating body 22.

  FIG. 4 shows the relationship among the permanent magnet 22a, the fixed iron core 24a, and the centering guide pins 31a and 32a. On the central axis Y, there are the permanent magnet 22a, the center of the fixed iron core 24a and the guide pins 31a, 32a.

  The positional relationship between the centering guide pins 31a and 32a may not be on the Y axis. As shown in FIG. 17, the center of the permanent magnet 22a and the fixed iron core 24a and the guide pin 31a are on the Y axis, and the guide pin 32a may be set on the X axis. That is, when the angles of the center of the permanent magnet 22a, the center of the fixed iron core, the guide pin 32a of the detector fixing plate, and the guide pin of the detector fixing plate are in a predetermined angular relationship, an output of the magnetic pole position is generated. When the detector is replaced, which is an effect of the present invention, the positional relationship at the time of assembly can be restored.

  5 and 6 show the positional relationship between the detector 29b, the detector fixing plate 30, the detector shaft fixing plate 28, the guide pin holes 31a1, 32a1, and the fixing bolt holes 31c, 31d, 32c, 32d. On the Y axis, there are a guide pin hole 32a1 of the detector fixing plate 30 and a guide pin hole 31a1 of the detector shaft fixing plate 28. The detector shaft fixing plate 28 has three mounting holes 32e. The X axis has fixing holes 32c and 32d of the detector fixing plate 30, and the tapped holes (32e and 32f in FIG. 10) of the support shaft 21 are fixed to the fixing holes through bolts (not shown). Also, the detector shaft fixing plate 28 has fixing holes 31c and 31d, and bolts (not shown) are fixed to the tapped holes (31e and 31f in FIG. 10) of the rotating body 22 through the fixing holes.

  The detector 29b is provided with an output line 30a, to which a connector 33a is connected. A connector 33b is connected to the tip of the output line 30b. The connectors 33a and 33b are connected in the space 21a of the support shaft 21.

  When attaching the detector 29b, the output line 30b is pulled out, the connectors 33a and 33b are connected, the detector 29b is fixed, and then the extra length of the output line 30b is pulled out from the terminal block 33 side.

The detector 29b with the output line 30a and the connector 31a is fixed to the detector fixing plate 30 with a metal fitting 29c. When the rotation shaft 29a of the detector 29b is attached to the detector shaft fixing plate 28 and the guide pin holes 31a1 and 32a1 are positioned on the Y axis as shown in FIG. 5, a signal of the detector 29b is generated. The rotating shaft 29a is adjusted and fixed to the detector shaft fixing plate 28.

Next, details of the relationship between the detector shaft fixing plate 28, the detector fixing plate 30, and the detector 29b will be described with reference to FIGS. 7, 8, and 9. FIG. FIG. 7 shows the relationship, FIG. 8 shows the detector shaft fixing plate, and FIG. 9 shows the detector fixing plate.

The detector 29b is fixed to the detector fixing plate 30 with a mounting bracket 29c and fixing screws 29c1 and 29c2. Reference numeral 30 a denotes an inlay portion for fixing to the support shaft 21. The rotation shaft 29a of the detector 29b is fixed to the detector shaft fixing plate by a key 29a1. The rotary shaft 29a, the key 29a, the shaft hole 28b and the key groove 28c in FIG. 31a1 and 32a1 are guide pin holes. As shown in FIG. 5, in order to output a magnetic pole when the Y-axis is positioned in the guide holes 31a1 and 32a1, an adjustment hole (not shown) is provided in the mounting bracket 29c, and the fixing screw is loosened. After matching, fix with screw lock. 9d of FIG. 9 is a hole which penetrates the rotating shaft 29a.

  FIG. 10 is a schematic diagram showing the positional relationship between the rotating body 22, the guide pin holes 31a2, 32a2 of the support shaft 21, and the fixing holes 31e, 31f, 32e, 32f as viewed from the A direction of the Z axis in FIG.

FIG. 11 shows the relationship between the rotor 22, the detector shaft fixing plate 28 of the support shaft 21, and the inlay portion of the detector fixing plate 30. Diameter of fitting between the detector shaft fixing plate 28 and the spigot portion of the rotating body 22 =
d1, depth = l1 is the dimension of FIG. 8 and FIG. Further, the fitting diameter = d2 and the depth = l2 of the inlay portion of the detector fixing plate 30 and the support shaft 21 are the dimensions of FIGS.

  When assembling the hoisting device 6, first, the detector fixing plate 30 with the detector 29b attached is positioned using the guide pin hole 32a1 and the guide pin hole 32a2 of the support shaft 21, and detected by a screw (not shown). The instrument fixing plate 30 is fixed to the support shaft 21. Next, the key 29a1 is inserted into the rotating shaft 29a, and inserted into the shaft hole 28b and the key groove 28c of the detector shaft fixing plate 28 shown in FIG. 8, and the guide pin hole 31a1 of the detector shaft fixing plate 28 and the rotating body are inserted. Then, the detector shaft fixing plate 28 is fixed to the rotating body 22 with screws (not shown).

  Since the key groove 28c is fitted with a skimmer, a slight shift in the rotational direction occurs, and the key groove 28c is fixed with a screw lock.

  When the detector 21b needs to be replaced after the hoisting device 6 is installed on the elevator shaft, the faulty detecting device 40 shown in FIG. 6 is removed with the hoisting device 6 attached, and the hoisting device 6 is again installed. It can be recovered by the procedure at the time of assembly.

  As another embodiment, a structure having no spigot portion will be described.

FIG. 13 shows a cross-sectional view of the hoisting device 6, and only differences from FIG. 3 will be described. Only a guide pin 32b for fixing the detector fixing plate 30 and a guide pin 31b for fixing the detector shaft fixing plate 28 are added. FIG. 13 has the same purpose as FIG. 4, and guide pins 31b and 32b are added on the Y axis. 14 and 15 are almost the same as FIGS. 5 and 6. Guide pin holes 31b1 and 32b1 are added, and there are four mounting holes 32e. The shaft 2 9 a is fully secured to detector shaft fixing plate 28, the entire detection device 40 are integrated. FIG. 16 is the same as FIG. 13, and guide pin holes 31b2 and 32b2 are added.

  When assembling the hoisting device 6, the integrated detection device 40 shown in FIG. 15 is centered using guide pins, and the detector fixing plate 30 is fixed to the support shaft 21 with screws (not shown) and detected. The instrument shaft fixing plate 28 is fixed to the rotating body 22 with screws (not shown).

The block diagram of a traction elevator. The layout of an elevator apparatus. Sectional drawing of an elevator apparatus. Positional relationship between magnetic pole position and detector mounting guide pin. Positional relationship between guide pin hole and mounting hole of detector. The schematic diagram of a detection apparatus. Mounting plate for detection device. Detector shaft mounting plate. Detector mounting plate. Positional relationship between guide pin holes and fixing screw holes on the rotating body and support shaft. The detailed drawing of the spigot part of a rotary body and a support shaft. Sectional drawing of the elevator apparatus of another Example. The positional relationship of the magnetic pole position of another Example and the guide pin for detector attachment. The positional relationship of the hole for guide pins and the mounting hole of the detection apparatus of another Example. The schematic diagram of the detecting device of other examples. The positional relationship of the rotating body of other Example, the hole for guide pins of a support shaft, and the screw hole for fixing. The positional relationship of the magnetic pole position of another Example and the guide pin for detector attachment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Car, 2 ... Counterweight, 6 ... Hoisting device, 7 ... Traction sheave, 21 ... Support shaft, 21a ... Space, 22 ... Rotating body, 28 ... Detector shaft fixing plate, 29a ... Rotating shaft of detector , 29b ... detector, 30 ... detector fixing plate.

Claims (2)

Elevator equipped with a traction sheave fixed to a rotating body driven by a permanent magnet motor, a hoisting rope wound around the traction sheave, and a car suspended up and down by the hoisting rope in an elevator shaft In the apparatus, the permanent magnet type electric motor is disposed between one elevator shaft wall and a vertical projection space of the car, and the traction sheave is positioned so as to be substantially parallel to the elevator shaft wall, A space is formed on the inner diameter side of the member that supports the rotating body via a bearing and on the side opposite to the elevator shaft wall, and a detector for detecting the magnetic pole position of the permanent magnet motor is installed in the space. An elevator device characterized by that. The detector is attached to the detector fixing plate, the detector fixing plate, the elevator apparatus according to claim 1, characterized in that fixed to the side surface of the member supporting the rotating body.

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