JP2012140194A - Elevator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an elevator which has high operational reliability, is suppressed in the risk of dangerous installation operation and maintenance operation, and can shorten wiring.SOLUTION: An uppermost floor detecting detector 7a and a lowermost floor detecting detector 7b are disposed on a governor rope 3, the uppermost floor detecting sensor 6a and the lowermost floor detecting sensor 6b are disposed near a governor driving side pulley 2, a control part 9 which controls a driving operation of the governor with detection signals of the sensors 6a, 6b is disposed, and on the basis of detection of the uppermost floor detecting detector 7a with the uppermost floor detecting sensor 6a and the detection of the lowermost floor detecting detector 7b with the lowermost floor detecting sensor 6b, the driving operation of the governor is controlled by the control part 2.

Description

  The present invention relates to an elevator, and more particularly to a technique for preventing an excessive rise or fall of a car for safe operation of the elevator.

  FIG. 7 is a schematic configuration diagram of an elevator conventionally described in, for example, Patent Document 1 below. In the figure, reference numeral 1 denotes an elevator car, which is moved up and down by being guided by a car guide rail (not shown) standing in the hoistway thereof. Reference numeral 2 denotes a driving pulley attached to a drive shaft of a governor (not shown), and 3 denotes an endless governor rope hung on the governor driving pulley.

  Further, 4a and 4b are limit switches with levers installed near the terminal floor (uppermost floor, lowermost floor) in the hoistway, and 5 is a side surface of the car 1 for operating the limit switches 4a and 4b. It is a switch cam attached to. Reference numeral 9 in the figure denotes a control unit (control panel) which takes in various signals such as detection signals from the limit switches 4a and 4b and performs operation control such as raising / lowering operation of the car 1 or emergency stop operation.

  When the lever is pushed by the switch cam 5 as the car 1 moves up and down and the limit switch 4a or 4b operates, a detection signal of the limit switch 4a or 4b is input to the control unit 9. . Based on the detection signal, the movement of the car 1 is stopped by a stop command signal output from the control unit 9 to prevent the car 1 from excessively rising or falling.

  Further, in Patent Document 2 below, a detection sensor and a detection body are attached to a guide rail for a counterweight and a counterweight, while a detection sensor and a detection body are attached to a rope for a governor and a rope tensioner for a governor, respectively. A clearance management measuring device and method for an elevator balancing weight / governor rope-crawler equipped with a motor have been proposed.

  Further, in Patent Document 3 below, a car is connected to one end of a rope hung on a hoist in a machine room, a counterweight is connected to the other end of the rope, and the car in the hoistway is connected. In an elevator construction safety device that detects an upper limit position and a lower limit position with a limit switch, and inputs a detection signal of the limit switch to the control unit of the hoisting machine, the car side and the counterweight side in the vicinity of the hoisting machine It has been proposed that the limit switches are provided in the vicinity of the rope, and members for operating the limit switches are provided on the rope at positions corresponding to the upper limit position and the lower limit position of the car.

  Furthermore, in Patent Document 4 below, a plurality of IC tags having position information written therein are provided on a governor rope that circulates in conjunction with raising and lowering of the car, and the IC is provided on the hoistway wall of the car. It has been proposed to provide a tag reader that reads tag position information.

JP-A-61-69676 JP 2008-280101A Japanese Patent Publication No. 6-20989 JP 2006-36430 A

  In the prior art described in Patent Document 1, the limit switches 4a and 4b are installed in the hoistway of the car 1, and inspection work must be performed in the hoistway. May cause danger to maintenance personnel. Furthermore, the wiring for transmitting a signal from the limit switches 4a and 4b installed in the hoistway to the control unit 9 in the machine room becomes longer as the floor becomes higher, so that the wiring work becomes complicated and the cost increases. There is a problem such as inviting.

  In addition, as described above, the prior art described in Patent Document 2 is provided with a detection sensor and a detection body attached to the counterweight guide rail and the counterweight, and is detected by the governor rope and the governor rope tensioner, respectively. This is a method of measuring the clearance of an elevator counterweight / governor rope tensioned vehicle by attaching a sensor and a detector.

  For this reason, there is no role of a limit switch that prevents the car from going up and down beyond the terminal floor, and it is necessary to provide a limit switch as usual. Furthermore, since the elevator governor rope detector is installed at the top of the hoistway, the wiring to send signals to the control unit attached to the lower part of the hoistway becomes longer as the floor becomes higher. There are problems such as complicated wiring work and high costs.

  Since the limit switch with a lever is a mechanical component, various troubles are likely to occur and there is a problem in operation reliability. Further, since it is necessary to install a switch cam for operating the limit switch with lever on the car, the installation work is complicated.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an elevator that can eliminate such drawbacks of the prior art, has high operational reliability, has a low risk of installation work and maintenance work, and can shorten wiring.

In order to achieve the above object, the first means of the present invention includes:
A governor that adjusts the ascent and descent of the car,
In an elevator provided with an endless speed governor rope that is stretched between a driving pulley and a driven pulley of the speed governor and circulates along with the lifting and lowering operation of the car,
A detector for detecting the uppermost floor and a detector for detecting the lowermost floor are attached to a predetermined position of the governor rope,
A top floor detection sensor for detecting the arrival of the top floor detection object and a bottom floor detection sensor for detecting the arrival of the bottom floor detection body are installed on the circulation path of the governor rope. do it,
Based on detection signals from the uppermost floor detection sensor and the lowermost floor detection sensor, a control unit for controlling the driving operation of the governor is provided,
Based on detection of the detection object for detecting the highest floor by the sensor for detecting the highest floor, and detection of the detection object for detection of the lowest floor by the sensor for detecting the lowest floor, the controller drives the governor. The operation is controlled.

According to a second means of the present invention, in the first means,
The uppermost floor detection body and the lowermost floor detection body detect that the car is before landing on the uppermost floor or the lowermost floor and decelerate to reduce the moving speed of the car. It has a zone detection part.

A third means of the present invention is the first or second means,
The detection object for detecting the top floor and the detection object for detecting the bottom floor have a stop area detection unit for detecting that the car has arrived on the top floor or the bottom floor and stopping the car. It is characterized by being.

A fourth means of the present invention is the first to third means,
The detection unit for detecting the top floor and the detection unit for detecting the bottom floor have an overshoot area detection unit for detecting that the car has passed the top floor or the bottom floor and stopping the car. It is characterized by being.

A fifth means of the present invention is the first to fourth means,
The detection body for detecting the top floor and the detection body for detecting the bottom floor are:
A deceleration area detector for detecting that the car is before landing on the uppermost floor or the lowermost floor and decelerating the moving speed of the car;
A stop area detector for detecting that the car has arrived at the top floor or the bottom floor and stopping the car;
The vehicle has an overshoot area detection unit for detecting that the car has passed the uppermost floor or the lowermost floor and stopping the car.

According to a sixth means of the present invention, in the fifth means,
The deceleration area detection unit, the stop area detection unit, and the overshoot area detection unit are provided along the moving direction of the uppermost floor detection body and the lowermost floor detection body. .

A seventh means of the present invention is the first to sixth means,
The uppermost floor detection sensor and the lowermost floor detection sensor are composed of an optical sensor having a light emitting element and a light receiving element that receives detection light emitted from the light emitting element,
The uppermost floor detection body and the lowermost floor detection body are formed of a shield that blocks the detection light emitted from the light emitting element.

The eighth means of the present invention is the seventh means,
The shield constituting the detection body for detecting the uppermost floor and the detection body for detecting the lowermost floor,
A deceleration area detector for detecting that the car is before landing on the uppermost floor or the lowermost floor and decelerating the moving speed of the car;
A stop area detector for detecting that the car has arrived at the top floor or the bottom floor and stopping the car;
An overshoot area detecting unit for detecting that the car has passed the uppermost floor or the lowermost floor and stopping the car is provided in a moving direction of the uppermost floor detecting body and the lowermost floor detecting body. Along the staircase,
In the top floor detection sensor and the bottom floor detection sensor,
A first light-emitting element-light-receiving element pair for detecting the deceleration area detector;
A second light-emitting element-light-receiving element pair for detecting the stop area detector;
A third light emitting element-light receiving element pair for detecting the overshoot area detecting unit is provided, respectively.

A ninth means of the present invention is the first to eighth means,
The uppermost floor detection sensor and the lowermost floor detection sensor are installed in the vicinity of a driving pulley of the governor.

The tenth means of the present invention is the ninth means,
The speed governor provided with the drive pulley, the uppermost floor detection sensor and the lowermost floor detection sensor, and detection signals from the uppermost floor detection sensor and the lowermost floor detection sensor are input to input the speed control device. A control unit that outputs a drive control signal to the speed machine is installed in a machine room partitioned from the hoistway of the car.

The eleventh means of the present invention is the first to eighth means,
A driven pulley of the governor is provided in a hoistway of the car, and the uppermost floor detection sensor and the lowermost floor detection sensor are installed in the vicinity of the driven pulley. It is.

The twelfth means of the present invention is the eleventh means,
A governor weight is connected to the driven pulley.

The thirteenth means of the present invention is the eleventh means,
The control unit is provided at a position below half the height of the hoistway.

The present invention is configured as described above,
The uppermost floor detection detector and the lowermost floor detection detector are attached to a predetermined position of the governor rope, and the arrival of the uppermost floor detection detector is detected. A sensor and a sensor for detecting the lowest floor for detecting the arrival of the detector for detecting the lowest floor are installed on the circulation path of the governor rope,
Based on the detection signals from the top floor detection sensor and the bottom floor detection sensor, a control unit for controlling the drive operation of the governor is provided.
Based on the detection of the detection object for the top floor detection by the sensor for detection of the top floor and the detection object for detection of the bottom floor by the sensor for detection of the bottom floor, the control unit controls the driving operation of the governor. It has become.

  This eliminates the need for a trouble-prone limit switch and eliminates the need to provide a switch cam for moving the lever of the limit switch on the car, improving operational reliability and simplifying the configuration. .

  As described in claim 2, the detection object for detecting the top floor and the detection object for detecting the bottom floor detect that the car is before landing on the top floor or the bottom floor and move the car. Since it has a deceleration area detector for reducing the speed, the car can automatically decelerate before landing on the top floor or the bottom floor to smoothly land on the floor. it can.

  The stop for stopping the car when the top-floor detection body and the bottom-floor detection body detect that the car has arrived at the top floor or the bottom floor as described in claim 3. Since the area detection unit is provided, the car can be automatically landed on the top floor or the bottom floor.

  As described in claim 4, the detection object for detecting the uppermost floor and the detection object for detecting the lowermost floor detect that the car has passed the uppermost floor or the lowermost floor, and overshoot for stopping the car. Since the area detection unit is provided, it is possible to prevent a situation in which the ceiling of the building or the shock absorber is compressed even if the car goes over the top floor or the bottom floor.

As described in claim 5, the detection body for detecting the highest floor and the detection body for detecting the lowest floor are:
A deceleration area detection unit for detecting that the car is before landing on the top floor or the bottom floor and decelerating the moving speed of the car;
A stop area detection unit for detecting that the car has arrived at the top floor or the bottom floor and stopping the car;
Since it has an overshoot area detector that detects when the car has passed the top floor or the bottom floor and stops the car, it is possible to smooth the landing of the car on the top floor or the bottom floor. It can be done safely and safely.

  As described in claim 6, the deceleration region detection unit, the stop region detection unit, and the overshoot region detection unit are provided along the moving direction of the detection object for detecting the highest floor and the detection object for detecting the lowest floor. It is possible to time-sequentially decelerate the car, land on the top floor or the bottom floor, and stop the car when the top floor or bottom floor is exceeded.

  As described in claim 7, the uppermost floor detection sensor and the lowermost floor detection sensor are configured by an optical sensor, and the uppermost floor detection detector and the lowermost floor detection sensor are configured by a shield. Therefore, the configuration is simple, inexpensive, and easy to maintain.

As described in claim 8, the shield constituting the detection body for detecting the uppermost floor and the detection body for detecting the lowermost floor,
A deceleration area detection unit for detecting that the car is before landing on the top floor or the bottom floor and decelerating the moving speed of the car;
A stop area detection unit for detecting that the car has arrived at the top floor or the bottom floor and stopping the car;
An overshoot area detection unit for detecting that the car has passed the top floor or the bottom floor and stopping the car is provided along the moving direction of the top floor detection body and the bottom floor detection body. Provided in a staircase,
The first light emitting element-light receiving element pair for detecting the deceleration area detecting unit and the second light emitting element-detecting light for detecting the stop area detecting unit in the top floor detecting sensor and the bottom floor detecting sensor. Since the element pair and the third light emitting element-light receiving element pair for detecting the overshoot area detection unit are provided,
The car can be smoothly and safely placed on the top floor or the bottom floor. When the car is slowed down, the floor is landed on the top or bottom floor, and the top or bottom floor is overrun. The car can be stopped in a time series, and the configuration is simple and inexpensive.

  Since the top floor detection sensor and the bottom floor detection sensor are installed in the vicinity of the driving pulley of the governor as described in claim 9, the top floor detection detector and the bottom floor detection The governor rope supporting the detection body has little swing, and therefore the detection reliability is high.

  11. A speed governor provided with a driving pulley, a top floor detection sensor and a bottom floor detection sensor, and detection signals from the top floor detection sensor and the bottom floor detection sensor as claimed in claim 10. Since the control unit that outputs the drive control signal to the governor is installed in the machine room, the length of the wiring connecting the sensor and the control unit is not related to the elevation height of the car, That is, it can be shortened without considering the wiring in the hoistway, the wiring work is simple, and the risk of maintenance and inspection work of the sensor is small.

  Since the sensor for detecting the uppermost floor and the sensor for detecting the lowermost floor are installed in the vicinity of the driven pulley of the governor, the detector for detecting the uppermost floor and for detecting the lowermost floor are provided. The governor rope supporting the detection body has little swing, and therefore the detection reliability is high.

  As described in claim 12, since the governor weight is connected to the driven pulley, the tension state of the governor rope is maintained, and the uppermost floor detection body and the lowermost floor detection body are supported. The governor rope has little run-out, and the detection reliability is high.

  Since the control part is provided in the position below the half of the height of the hoistway as described in Claim 13, the length of the wiring which connects the said sensor and control part is set to the raising / lowering height of a car. It can be shortened regardless of whether the wiring work is simple.

1 is a schematic configuration diagram of an elevator according to a first embodiment of the present invention. In the elevator which concerns on this 1st Embodiment, it is the perspective view which showed the state just before a detection body arrives at a sensor. It is the top view which showed the state just before the detection body reaches | attains a sensor. It is a partial front view which shows the support structure of the sensor in the vicinity of the governor drive side pulley in this embodiment. It is a schematic block diagram of the elevator which concerns on 2nd Embodiment of this invention. It is a partial front view for demonstrating the elevator which concerns on 3rd Embodiment of this invention. It is a schematic block diagram of the conventional elevator.

Next, each embodiment of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a schematic configuration diagram of an elevator according to a first embodiment of the present invention.

  In the figure, reference numeral 1 denotes an elevator car, which is raised and lowered by being guided by a car guide rail (not shown) standing in the hoistway. Reference numeral 2 denotes a driving pulley attached to a drive shaft of a speed governor (not shown) installed in the machine room 10, and reference numeral 3 denotes a governor pulley 21 that is a governor driving pulley 2 and a driven pulley. It is a hung endless governor rope.

  6a is attached to the vicinity of the governor side drive pulley 2, and detects the top floor detection sensor for detecting that the car 1 has arrived near the top floor, and 6b is in the vicinity of the governor side drive pulley 2. A sensor for detecting the lowermost floor that is attached and detects that the car 1 has arrived near the lowermost floor. The uppermost floor detection sensor 6a and the lowermost floor detection sensor 6b are installed so as to face the governor rope 3 with the governor side drive pulley 2 therebetween.

  That is, both sensors 6a and 6b are installed on the circulation path of the governor rope 3 in the machine room 10, and the detection signals of both sensors 6a and 6b are installed in the same machine room 10. Is input to the control unit 9.

  7a is a detection object for detecting the highest floor attached to the governor rope 3, and 7b is a detection object for detecting the lowest floor. When the car 1 comes near the top floor, the top floor detection body 7a is detected by the top floor detection sensor 6a, and when the car 1 comes near the bottom floor, the bottom floor detection body 7a is detected. As shown in FIG. 1, the detectors 7a and 7b are attached to the top and bottom of the governor rope 3 so that the detector 7b is detected by the lowest floor detection sensor 6b.

  FIG. 2 is a perspective view showing a state immediately before the detection bodies 7a and 7b reach the sensors 6a and 6b, and FIG. 3 is a top view showing a state immediately before the detection bodies 7a and 7b reach the sensors 6a and 6b. FIG.

  As shown in FIG. 3, the sensor body 11 has a U-shaped planar shape, and a hollow portion 12 through which the detection bodies 7a and 7b pass is formed inside. A first light emitting element 13a, a second light emitting element 13b, and a third light emitting element 13c are arranged side by side at a predetermined interval on the inner surface of the sensor body 11 facing the hollow portion 12. The first light receiving element 14a, the second light receiving element 14b, and the third light receiving element 14c are arranged in parallel so as to face the first light emitting element 13a, the second light emitting element 13b, and the third light emitting element 13c through the hollow portion 12. So as to constitute a so-called three optical axis sensor.

  As the car 1 moves up and down, the detection bodies 7a and 7b are inserted into the hollow portions 12 of the sensors 6a and 6b. The detection bodies 7a and 7b are made of an opaque light shielding body such as a metal plate or a synthetic resin plate, and have a substantially rectangular side surface shape as shown in FIG. Is provided.

  The lower ends 15 of the detection bodies 7a and 7b extend over the entire width. On the other hand, a deceleration area detector 16, a stop area detector 17, and an overshoot area detector 18 are provided at the upper ends of the detection bodies 7a and 7b, respectively.

The deceleration area detector 16 has a function of a slow down switch (SDS) for decelerating the moving speed of the car 1.
The stop area detection unit 17 has a function of a switch for stopping the car 1 at a desired landing position. In the uppermost detection detector 7a, the function of an up limit switch (ULS), the uppermost detection detector 7b is provided. Has a function of a down limit switch (DLS).
The overshoot area detection unit 18 detects that the car 1 has passed the end floor and stops the car 1 from moving further so as not to compress the ceiling or shock absorber of the building. It has a switch (FLS) function.

  As shown in FIG. 2, the deceleration area detection unit 16, the stop area detection unit 17, and the overshooting area detection unit 18 have a height from the lower end part 15 as shown in FIG. > The overshooting area detection unit 18 has a relationship, and therefore, it is stepped as a whole.

  In the present embodiment, the uppermost floor detection sensor 6a and the lowermost floor detection sensor 6b, and the uppermost floor detection sensor 7a and the lowermost floor detection sensor 7b have the same shape.

  As shown in FIG. 3, the pair of the first light-emitting element 13a and the first light-receiving element 14a (first light-emitting element-light-receiving element pair) is the deceleration area detector 16, the second light-emitting element 13b, and the second light-receiving element 14b. Pair (second light emitting element-light receiving element pair) is a stop area detecting unit 17, and a pair of third light emitting element 13c and third light receiving element 14c (third light emitting element-light receiving element pair) is an overshoot area detecting unit. 18 is arranged to face 18.

  In the ascending process of the car 1, before the top floor detection sensor 7a approaches the top floor detection sensor 6a, the detection light 19 (see FIG. 3) emitted from the light emitting elements 13a to 13c is received by each light receiving element. Light is received by 14a to 14c. Accordingly, the first light receiving element 14a, the second light receiving element 14b, and the third light receiving element 14c are all in the ON state.

  As the car 1 rises, as shown in FIG. 2, when the top floor detection body 7 a approaches the top floor detection sensor 6 a and the deceleration area detection unit 16 blocks the detection light 19 from the light emitting element 13 a, Only one light receiving element 14a is turned off (the second light receiving element 14b and the third light receiving element 14c are kept on), and a detection signal generated by this change is input from the top floor detection sensor 6a to the control unit 9.

  Then, the controller 9 determines that the car 1 is before landing on the top floor, and outputs a deceleration signal for decelerating the ascending speed of the car 1 to a governor (not shown). Decrease the speed of 1.

  Next, detection from the light emitting element 13b is performed by the stop area detector 17 (in the case of the detection object 7a for the highest floor, the stop area detector 17 has the function of an up limit switch (ULS) as described above). When the light 19 is blocked, the second light receiving element 14b is also turned off (the first light receiving element 14a is already in the off state and the third light receiving element 14c is kept in the on state). Input from the detection sensor 6 a to the controller 9.

  Then, the control unit 9 determines that the car 1 has landed on the top floor, and outputs a stop signal to stop the ascent of the car 1 to a speed governor (not shown) to land the car 1. To do.

  Here, if the car 1 continues to rise for some reason, the detection light 19 from the light emitting element 13c is shielded by the overshoot area detector 18, and the first light receiving element 14a, the second light receiving element 14b, and the third light receiving element 14c. Are all turned off, and the detection signal generated by this change is input to the control unit 9 from the top floor detection sensor 6a.

  Then, the control unit 9 determines that the car 1 has gone over the top floor, and outputs an emergency stop signal for urgently stopping the ascent of the car 1 to the speed governor (not shown). Stop immediately so as not to rise any further.

  Further, in the descending process of the car 1, before the lowermost floor detection sensor 7b approaches the lowermost floor detection sensor 6b, the detection light 19 (see FIG. 3) emitted from the light emitting elements 13a to 13c is Light is received by each of the light receiving elements 14a to 14c. Accordingly, the first light receiving element 14a, the second light receiving element 14b, and the third light receiving element 14c are all in the ON state.

  As the car 1 descends, as shown in FIG. 2, the lowest floor detection body 7b approaches the lowest floor detection sensor 6b, and the deceleration area detector 16 blocks the detection light 19 from the light emitting element 13a. Only the first light receiving element 14a is in the OFF state (the second light receiving element 14b and the third light receiving element 14c are kept in the ON state), and the detection signal generated by this change is input from the top floor detection sensor 6a to the control unit 9. The

  Then, the control unit 9 determines that the car 1 is before landing on the lowest floor, and outputs a deceleration signal for decelerating the descending speed of the car 1 to a governor (not shown). Decrease the speed of the car 1.

  Next, the stop area detector 17 (in the case of the detection object 7b for the lowest floor, the stop area detector 17 has a function of a down limit switch (DLS) as described above) from the light emitting element 13b. When the detection light 19 is blocked, the second light receiving element 14b is also turned off (the first light receiving element 14a has already been turned off and the third light receiving element 14c has been kept on), and the detection signal generated by this change is the highest. Input to the control unit 9 from the lower floor detection sensor 6b.

  The control unit 9 determines that the car 1 has landed on the lowest floor, outputs a stop signal to stop the descent of the car 1 to the governor (not shown), and arrives at the car 1. To floor.

  Here, if the car 1 continues to descend for some reason, the detection light 19 from the light emitting element 13c is shielded by the overshoot area detector 18, and the first light receiving element 14a, the second light receiving element 14b, and the third light receiving element 14c. Are turned off, and the detection signal generated by this change is input to the control unit 9 from the lowest floor detection sensor 6b.

  Then, the control unit 9 determines that the car 1 has passed the lowest floor, outputs an emergency stop signal for emergency stop of the lowering of the car 1 to the governor (not shown), and the car 1 Stop immediately so as not to descend any further.

FIG. 4 is a partial front view showing a support structure for the sensors 6a and 6b in the vicinity of the driving pulley 2 of the governor.
As shown in the figure, the sensors 6a and 6b are supported by a frame-type or box-type sensor support member 20 with the governor drive side pulley 2 interposed therebetween. The sensor support member 20 can also be used as a support member for a speed governor (not shown). The state of this figure shows a state in which the lowest floor detection body 7b has reached the lowest floor detection sensor 6b.

  During periodic inspection of the elevator, the car 1 is operated at a high speed by operating the control unit 9 in the machine room 10 to check whether the sensors 6a, 6b and the detectors 7a, 7b are operating normally.

(Second Embodiment)
FIG. 5 is a schematic configuration diagram of an elevator according to the second embodiment of the present invention. This embodiment shows a case where there is no machine room.

  In the figure, reference numeral 1 denotes an elevator car, which is raised and lowered by being guided by a car guide rail (not shown) standing in the hoistway. 2 is a driving pulley attached to a speed governor installed near the bottom of the hoistway, and 3 is an endless shape wound between the speed governor driving pulley 2 and an upper driven pulley. It is a governor rope.

6a is a sensor for detecting the uppermost floor that is attached in the vicinity of the governor driving pulley 2 and 6b is a lowermost floor that is attached in the vicinity of the governor driving pulley 2 and detects the lowermost floor. In the detection sensor, the uppermost floor detection sensor 6a and the lowermost floor detection sensor 6b are installed so as to face the governor rope 3 through the governor driving pulley 2 therebetween. .
Although not shown, the sensors 6a and 6b are supported by a frame-type or box-type sensor support member.

  Detection signals from the top floor detection sensor 6a and the bottom floor detection sensor 6b are input to the control unit 9 installed on the side wall 24 of the hoistway. As shown in the drawing, the control unit 9 is installed below half of the height H of the hoistway.

  The controller 9 can be installed near the lower end of the side wall 24 or at the bottom of the hoistway so as to shorten the length of the wiring as much as possible.

  7a is a detection object for detecting the highest floor attached to the governor rope 3, and 7b is a detection object for detecting the lowest floor. When the car 1 comes near the top floor, the top floor detection body 7a is detected by the top floor detection sensor 6a, and when the car 1 comes near the bottom floor, the bottom floor detection body 7a is detected. The detection bodies 7a and 7b are attached to the top and bottom opposite positions of the governor rope 3 as shown in the figure so that the detection body 7b is detected by the lowest floor detection sensor 6b.

  Since the configurations and functions of the sensors 6a and 6b and the detection bodies 7a and 7b and the control operation of the car 1 based on these detection means are the same as those in the first embodiment, redundant description is omitted.

  During regular inspection of the elevator, the car 1 is operated at a high speed by operating a personal computer for maintenance in the elevator hall, and it is confirmed whether the sensors 6a, 6b and the detectors 7a, 7b are operating normally.

(Third embodiment)
FIG. 6 is a partial front view for explaining an elevator according to a third embodiment of the present invention.
In the case of this embodiment, the lower folded portion of the endless speed governor rope 3 is hung on the governor pulley 21, and a governor weight 22 is connected to the governor pulley 21. The governor pulley 21 and the governor weight 22 maintain the tension state of the governor rope 3 well. The governor pulley 21 and the governor weight 22 are supported by a governor support member 23 so as to be swingable in the vertical direction.

  In the vicinity of the governor pulley 21, an uppermost floor detection sensor 6a and a lowermost floor detection sensor 6b are disposed therebetween, and both sensors 6a and 6b are supported by a sensor support member 20.

  The sensors 6a and 6b according to the present embodiment are cylindrical so that the governor rope 3 and the detectors 7a and 7b can be inserted. Although not shown, the light emitting element 13a is formed on the inner surface of the sensors 6a and 6b. To 13c and the light receiving elements 14a to 14c are installed in pairs.

  In this embodiment, the cylindrical sensors 6a and 6b are used. However, it is also possible to use U-shaped sensors 6a and 6b as shown in FIG.

1 elevator car 2 speed governor drive pulley 3 speed governor rope 6a top floor detection sensor 6b bottom floor detection sensor 7a top floor detection body 7b bottom floor detection body 9 control unit 10 Machine room 11 Sensor body 12 Hollow part 13a First light emitting element 13b Second light emitting element 13c Third light emitting element 14a First light receiving element 14b Second light receiving element 14c Third light receiving element 15 Lower end part 16 Deceleration area detection part 17 Stop area detection Unit 18 Overshoot area detection unit 19 Detection light 20 Sensor support member 21 Governor pulley 22 Governor weight 23 Governor support member 24 Side wall of hoistway H Height of hoistway.

Claims (13)

A governor that adjusts the ascent and descent of the car,
In an elevator provided with an endless speed governor rope that is stretched between a driving pulley and a driven pulley of the speed governor and circulates along with the lifting and lowering operation of the car,
A detector for detecting the uppermost floor and a detector for detecting the lowermost floor are attached to a predetermined position of the governor rope,
A top floor detection sensor for detecting the arrival of the top floor detection object and a bottom floor detection sensor for detecting the arrival of the bottom floor detection body are installed on the circulation path of the governor rope. do it,
Based on detection signals from the uppermost floor detection sensor and the lowermost floor detection sensor, a control unit for controlling the driving operation of the governor is provided,
Based on detection of the detection object for detecting the highest floor by the sensor for detecting the highest floor, and detection of the detection object for detection of the lowest floor by the sensor for detecting the lowest floor, the controller drives the governor. An elevator characterized by controlling its operation. The elevator according to claim 1,
The uppermost floor detection body and the lowermost floor detection body detect that the car is before landing on the uppermost floor or the lowermost floor and decelerate to reduce the moving speed of the car. An elevator characterized by having an area detection unit. The elevator according to claim 1 or 2,
The detection object for detecting the top floor and the detection object for detecting the bottom floor have a stop area detection unit for detecting that the car has arrived on the top floor or the bottom floor and stopping the car. An elevator characterized by being. The elevator according to any one of claims 1 to 3,
The detection unit for detecting the top floor and the detection unit for detecting the bottom floor have an overshoot area detection unit for detecting that the car has passed the top floor or the bottom floor and stopping the car. An elevator characterized by being. The elevator according to any one of claims 1 to 4,
The detection body for detecting the top floor and the detection body for detecting the bottom floor are:
A deceleration area detector for detecting that the car is before landing on the uppermost floor or the lowermost floor and decelerating the moving speed of the car;
A stop area detector for detecting that the car has arrived at the top floor or the bottom floor and stopping the car;
An elevator having an overshoot area detecting unit for detecting that the car has passed the uppermost floor or the lowermost floor and stopping the car. The elevator according to claim 5,
The said deceleration area detection part, a stop area detection part, and an overshoot area detection part are provided along the moving direction of the said detection object for uppermost floor detection, and the detection object for lowermost floor. The elevator according to any one of claims 1 to 6,
The uppermost floor detection sensor and the lowermost floor detection sensor are composed of an optical sensor having a light emitting element and a light receiving element that receives detection light emitted from the light emitting element,
The elevator according to claim 1, wherein the uppermost floor detection body and the lowermost floor detection body are constituted by a shielding body that blocks detection light emitted from the light emitting element. The elevator according to claim 7,
The shield constituting the detection body for detecting the uppermost floor and the detection body for detecting the lowermost floor,
A deceleration area detector for detecting that the car is before landing on the uppermost floor or the lowermost floor and decelerating the moving speed of the car;
A stop area detector for detecting that the car has arrived at the top floor or the bottom floor and stopping the car;
An overshoot area detecting unit for detecting that the car has passed the uppermost floor or the lowermost floor and stopping the car is provided in a moving direction of the uppermost floor detecting body and the lowermost floor detecting body. Along the staircase,
In the top floor detection sensor and the bottom floor detection sensor,
A first light-emitting element-light-receiving element pair for detecting the deceleration area detector;
A second light-emitting element-light-receiving element pair for detecting the stop area detector;
The elevator characterized by each providing the 3rd light emitting element-light receiving element pair for detecting the said overshooting area detection part. The elevator according to any one of claims 1 to 8,
The elevator, wherein the uppermost floor detection sensor and the lowermost floor detection sensor are installed in the vicinity of a driving pulley of the governor. The elevator according to claim 9,
The speed governor provided with the drive pulley, the uppermost floor detection sensor and the lowermost floor detection sensor, and detection signals from the uppermost floor detection sensor and the lowermost floor detection sensor are input to input the speed control device. An elevator characterized in that a control unit that outputs a drive control signal to a speed machine is installed in a machine room partitioned from a hoistway of the car. The elevator according to any one of claims 1 to 8,
An elevator in which a driven pulley of the governor is provided in a hoistway of the car, and the uppermost floor detection sensor and the lowermost floor detection sensor are installed in the vicinity of the driven pulley. . The elevator according to claim 11,
An elevator characterized in that a governor weight is connected to the driven pulley. The elevator according to claim 11,
The elevator characterized in that the control unit is provided at a position below half of the height of the hoistway.

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