JP4359187B2 - Electromagnetic brake device and electromagnetic brake device for elevator hoisting machine - Google Patents

Abstract

An electromagnetic braking apparatus is disclosed, including the following components: braking sheets (2a, 2b) provided on braking faces (1a, 1b) of a braked body, a first and a second braking arms (3a, 3b) whose one end part can be rotatably supported; braking springs (4a, 4b) which causing the braking sheets to push and press the braking faces so as to brake the braked body; an electromagnet (6) which is composed by a magnet yoke and an electromagnetic winding and operates in a connection direction of another end part (3d) connecting the first and the second braking arms; an electromagneticdevice (5) which is composed by iron sheets (7a, 7b) provided corresponding to the electromagnet and magnetic pole faces, and overcomes the elasticity of a brake spring through the electromagnetism suction generated when the electromagnet is electrified to drive the first and the second braking arms, releases the pushing and pressing force of the braking sheets to release the braking to the braked body, wherein the electromagnetic device is composed by one or two fixed electromagnets and two or one movable iron sheet, and respectively drives the first and the second braking arms through the movable iron sheet.

Description

  The present invention relates to an electromagnetic brake device having two sets of brake mechanisms, and more particularly to an electromagnetic brake device for an elevator hoist suitable for use in an elevator hoist.

  For example, as an electromagnetic brake device, a braking piece held by two sets of braking arms whose one end is pivotally supported comes into contact with a braking surface of a brake drum as a braked body, and the other end is pressed by a braking spring. A yoke that also serves as an electromagnetic coil and a case, and consists of two movable iron cores facing each other, and operates the electromagnetic attraction of these two movable iron cores against the braking spring on the multi-end side of the braking arm Has been proposed (see, for example, Patent Document 1).

  In addition, as a brake device, the inner peripheral surface of a driving sheave as a braked body is a braking surface, and is composed of two sets of braking arms, a braking piece, a braking spring, and a set of electromagnetic devices. The braking spring is arranged inside the driving sheave, one end of the braking arm is pivoted inside the driving sheave, the other end is arranged outside the driving sheave, and the electromagnetic device is arranged outside the driving sheave. An electromagnetic brake device has been proposed (see, for example, Patent Document 2).

Further, as an elevator hoisting machine, a saddle-like rotator in which an electric motor rotor and a driving sheave are integrally formed is provided in the frame body, and the inner periphery of the saddle-like rotator as a braked body is provided. An electromagnetic brake device having a braking surface as a braking surface has been proposed (see, for example, Patent Document 3).
JP 2003-343608 A (see paragraph 0007) Japanese Patent Laid-Open No. 10-203761 (see Embodiment 1, FIG. 1) Japanese Patent Laying-Open No. 2001-322781 (see paragraph 0007)

  The electromagnetic brake device proposed in Patent Document 1 has two sets of mechanisms for applying braking, but one set of mechanisms for releasing the braking is used in common for the two sets of braking applying mechanisms. . That is, what has a brake addition and cancellation | release mechanism and functions independently as a brake is not two sets of structures. Therefore, there is a problem that it cannot be applied when two sets of functions as a brake are required.

  The brake device proposed in Patent Document 2 is composed of two sets of braking arms, braking pieces, a braking spring, and a set of electromagnetic devices for releasing braking, with the inner peripheral surface of the drive sheave as a braking surface. The brake piece and the brake spring are arranged inside the drive sheave, one end of the brake arm is pivoted inside the drive sheave, and the other end of the brake arm is arranged outside the drive sheave. The device is arranged outside the driving sheave, but the braking spring is installed inside the driving sheave as a rotating body. For this reason, like the proposal of patent document 1, there existed a problem that it was not applicable when two sets of functions as a brake were required.

  Furthermore, in the electromagnetic brake device for an elevator hoisting machine proposed in Patent Document 3, the brake is a brake arm system, one end of the brake arm is pin-supported on a support plate, and a brake piece is placed between the brake arms. An armature is disposed as a movable iron piece including the above, and a braking spring is disposed between the rotating end of the braking arm and the support plate, and an electromagnet is disposed so as to electromagnetically attract the armature. That is, components such as a braking arm, a braking spring, and an electromagnet as an electromagnetic device are installed inside a bowl-shaped rotating body that is a rotating body. For this reason, it is compact and installed in a limited place with high density, but it is suitable for assembly and adjustment work such as assembly of parts as a brake, stroke adjustment of brake pieces, stroke adjustment of armature and electromagnet, adjustment of spring force, etc. There was a problem that it took time.

  An object of the present invention is to provide an electromagnetic brake device applicable even when two sets of functions as a brake are required.

  Another object of the present invention is to provide an electromagnetic brake device that can be easily assembled and adjusted.

According to a first aspect of the present invention, there are provided first and second braking arms each having a braking piece disposed on a braking surface of a body to be braked and having one end portion rotatably supported, and the braking piece presses the braking surface and Arranged to operate in the direction connecting the braking spring provided at the other end of the first and second braking arms and the other end of the first and second braking arms so as to brake the braked body And an electromagnet composed of a yoke and an electromagnetic coil, and an iron piece provided to face the magnetic pole surface of the electromagnet, and against the spring force of the brake spring by the electromagnetic attraction force when the electromagnet is energized, And an electromagnetic brake device configured to drive the second braking arm, release the pressing force of the braking piece, and release the braking of the braked body, wherein the electromagnetic device includes one fixed electromagnet and together consist of two movable iron piece, the through the upper hear dynamic iron first及Second brake arms driven respectively, the electromagnet is characterized in that it consists of a yoke used in common with respect to the two electromagnetic coils and the two electromagnetic coils.

  Thus, it is composed of a braking arm provided with a braking piece, a braking spring that applies a pressing force to the braking piece and applies a braking force, and an electromagnetic device that releases the braking force, and has a braking addition and release mechanism and independently as a brake. An electromagnetic brake device having two sets of functions is obtained.

According to a second aspect of the present invention, there are provided first and second braking arms each having a braking piece disposed on a braking surface of a braked body and one end portion of which is rotatably supported, and the braking piece presses the braking surface and A brake spring provided at the other end of the first and second brake arms and the other end of the first and second brake arms are arranged to operate in a direction connecting the other ends of the first and second brake arms so as to brake the brake body. An electromagnet composed of a yoke and an electromagnetic coil, and an iron piece provided opposite to the magnetic pole surface of the electromagnet, and against the spring force of the braking spring by the electromagnetic attraction force when the electromagnet is energized, In an electromagnetic brake device configured to drive a second braking arm, release the pressing force of the braking piece, and release the braking of the braked body,
The electromagnetic device is composed of two movable electromagnets and one movable iron piece, and drives the first and second braking arms via the movable electromagnets. The two electromagnets are respectively an electromagnetic coil and an electromagnetic coil. It consists of a yoke and is characterized in that these two electromagnets face the fixed iron piece.
Thus, it is composed of a braking arm provided with a braking piece, a braking spring that applies a pressing force to the braking piece and applies a braking force, and an electromagnetic device that releases the braking force, and has a braking addition and release mechanism and independently as a brake. An electromagnetic brake device having two sets of functions is obtained.
According to a third aspect of the present invention , in the first or second aspect , the electromagnetic device outputs an electromagnetic attractive force in a pulling direction or a pushing direction with respect to a direction connecting the other end portions of the first and second braking arms. It is characterized by doing so.

Thus, as in the first or second aspect , the brake is provided with a braking arm, a braking spring for applying a pressing force to the braking piece to add a braking force, and an electromagnetic device for releasing the braking force. Two sets of electromagnetic brake devices that have independent functions as brakes are obtained, and in particular, the spring force of the brake spring is viewed from the side connecting the other ends of the first and second brake arms. Thus, it is effective when the brake arm is added in the pushing direction or the pulling direction.

According to a fourth aspect of the present invention , in the third aspect of the present invention, the electromagnetic device according to the third aspect is provided with an output rod that outputs an electromagnetic attractive force in a pulling direction or a pushing direction with respect to a direction connecting the first and second braking arms. The output rod drives the other end portions of the first and second braking arms, respectively.

  Thus, it is composed of a braking arm provided with a braking piece, a braking spring that applies a pressing force to the braking piece and applies a braking force, and an electromagnetic device that releases the braking force, and has a braking addition and release mechanism and independently as a brake. An electromagnetic brake device having two sets of functions is obtained. In particular, the inner brake surface of the braked body is braked, and the spring force of the brake spring is applied to the other ends of the first and second brake arms. This is effective when it is added in the pushing direction or the pulling direction with respect to the braking arm as seen from the connecting side.

According to a fifth aspect of the present invention , in the fourth aspect of the present invention, the electromagnetic device according to the fourth aspect further includes an output rod that outputs an electromagnetic attractive force in a pushing direction or a pulling direction with respect to a direction in which the first and second braking arms are connected. The other end portions of the first and second braking arms are driven from the output rod via a rotating lever, respectively.

  Thus, it is composed of a braking arm provided with a braking piece, a braking spring that applies a pressing force to the braking piece and applies a braking force, and an electromagnetic device that releases the braking force, and has a braking addition and release mechanism and independently as a brake. An electromagnetic brake device having two sets of functions is obtained. In particular, the inner brake surface of the braked body is braked, and the spring force of the brake spring is applied to the other ends of the first and second brake arms. This is effective when it is added in the pulling direction or pushing direction with respect to the braking arm as seen from the connecting side. Further, the adjustment of the stroke between the braking piece and the braking surface and the stroke between the armature and the electromagnet can be made without being influenced by the spring force of the braking spring by using the rotating lever, so that the adjustment work can be facilitated.

According to a sixth aspect of the present invention , in the fifth aspect , the output rod is disposed outside the electromagnet.

  As a result, the output rod of the electromagnetic device as the braking release mechanism does not penetrate the hole provided in the magnetic pole surface that generates the electromagnetic attractive force, so that the effective magnetic pole area does not decrease and the electromagnetic attractive force as the output does not decrease.

According to a seventh aspect of the present invention, in the third aspect of the present invention, the electromagnetic device according to the third aspect is provided with a rotating lever that outputs an electromagnetic attraction force in a pulling direction or a pushing direction with respect to a direction connecting the first and second braking arms. The other end portions of the first and second braking arms are each driven by a rotating lever .

Thus, it is composed of a braking arm provided with a braking piece, a braking spring that applies a pressing force to the braking piece and applies a braking force, and an electromagnetic device that releases the braking force, and has a braking addition and release mechanism and independently as a brake. An electromagnetic brake device having two sets of functions is obtained. In particular, the inner brake surface of the braked body is braked, and the spring force of the brake spring is applied to the other ends of the first and second brake arms. This is effective when it is added in the pushing direction or the pulling direction with respect to the braking arm as seen from the connecting side.
Further, in claim 8 , a bowl-shaped frame body provided with a stator winding on the inner peripheral surface of the opening edge, a main shaft provided so as to protrude from the bottom surface of the frame body to the recess side, and the frame A rod-shaped rotating body having a drive sheave pivoted on the main shaft and disposed on the outer periphery of the outer ring portion of the rod-shaped rotating body, facing the stator winding. An armature, a braking surface provided on an inner peripheral surface of the outer ring portion, a support plate having an edge portion mounted on an opening edge portion of the frame body, and an electromagnetic brake device that brakes the braking surface. In the electromagnetic brake device of an elevator hoisting machine, the electromagnetic device of the electromagnetic brake device is composed of one fixed electromagnet and two movable iron pieces, and the first and second braking arms via the movable iron pieces. The electromagnet has two electromagnetic coils and two electromagnetic coils. Consists yoke used commonly, one end portion of the first and second brake arms of the electromagnetic brake device is Kururuji in Kururuji pin to the support plate, the other end beyond the opening edge part end The brake spring and the electromagnetic device are arranged outside the frame body, and are arranged outside the frame body so as to perform braking operation in opposite directions to each other. The brake is pressed against the braking surface, and the other end of the braking arm is driven by an electromagnetic device so that the braking piece is separated from the braking surface to release the braking.

  As a result, an elevator hoisting machine that has a braking addition and release mechanism and functions independently as a brake is provided with two sets of electromagnetic brake devices, and the assembly work is simple and the adjustment work is easy. Machine electromagnetic brake device is obtained.

According to a ninth aspect of the present invention, there is provided a bowl-shaped frame body provided with a stator winding on the inner peripheral surface of the opening edge, a main shaft provided so as to protrude from the bottom surface of the frame body toward the recess, and the frame A rod-shaped rotating body having a drive sheave pivoted on the main shaft and disposed on the outer periphery of the outer ring portion of the rod-shaped rotating body, facing the stator winding. An armature, a braking surface provided on an inner peripheral surface of the outer ring portion, a support plate having an edge portion mounted on an opening edge portion of the frame body, and an electromagnetic brake device that brakes the braking surface. In the electromagnetic brake device for an elevator hoist, the electromagnetic device of the electromagnetic brake device includes two movable electromagnets and one movable iron piece, and the first and second brakes via the movable electromagnets. Each arm is driven, and the two electromagnets are each composed of an electromagnetic coil and a yoke. The two electromagnets are opposed to the fixed iron piece, one end of the first and second braking arms of the electromagnetic brake device is pivoted to the support plate by a pivot pin, and the other end is opened to the opening. The brake spring and the electromagnetic device are arranged outside the frame body beyond the edge, and are arranged outside the frame body, and are configured by two sets that perform braking operation in opposite directions to each other. The braking piece is brought into pressure contact with the braking surface by force to perform braking, and the other end portion of the braking arm is driven by an electromagnetic device so that the braking piece is separated from the braking surface to release the braking.
As a result, an elevator hoisting machine that has a braking addition and release mechanism and functions independently as a brake is provided with two sets of electromagnetic brake devices, and the assembly work is simple and the adjustment work is easy. Machine electromagnetic brake device is obtained.

  ADVANTAGE OF THE INVENTION According to this invention, the electromagnetic brake device provided with two sets of braking addition and cancellation | release mechanisms which function independently as a brake device can be provided.

  Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a front view of an inner surface braking electromagnetic brake device according to a first embodiment of the present invention, and FIGS. 2 and 3 are front views showing separate electromagnetic devices of the electromagnetic device shown in FIG.

  In FIG. 1, reference numeral 1 denotes a brake drum as a body to be braked, and brake pieces 2a and 2b are brought into contact with an inner peripheral braking surface 1a of the brake drum 1, respectively. Reference numerals 3a and 3b denote a pair of braking arms, which have the braking pieces 2a and 2b and rotatably support the one end 3c. Reference numerals 4a and 4b denote braking springs, which are disposed on the other end 3d of the braking arms 3a and 3b so that the braking pieces 2a and 2b apply a pressing force to the braking surface 1a. The spring force of the brake springs 4a and 4b is applied in the direction of pushing the brake arms 3a and 3b when viewed from the side connecting the other end portions 3d of the brake arms 3a and 3b.

  An electromagnetic device 5 is provided in the vicinity of the other end 3d of the first and second braking arms 3a and 3b so as to release the pressing force of the braking springs 4a and 4b, and is one fixed electromagnet. 6 and two movable iron pieces 7a and 7b. The electromagnet 6 includes two electromagnetic coils 9a and 9b and a yoke 8 commonly used for the electromagnetic coils 9a and 9b. The yoke 8 has magnetic pole faces 10a and 10b at two locations. Electromagnetic coils 9a and 9b are arranged for each magnetic pole surface 10a and 10b, and have substantially two functions as electromagnets. Further, two movable iron pieces 7a and 7b are arranged opposite to the magnetic pole surfaces 10a and 10b, and the movable iron pieces 7a and 7b are connected to the other end 3d of the braking arms 3a and 3b so as to be driven. It has become.

  The operation of this electromagnetic brake device is as follows. At the time of braking, the braking pieces 2a and 2b press the braking surface 1a of the brake drum 1 via the braking arms 3a and 3b by the braking springs 4a and 4b, and the braking state is established. When the brake is released, the electromagnetic coils 9a and 9b are energized to generate magnetic flux, and when the movable iron pieces 7a and 7b are electromagnetically attracted to the magnetic pole surface, the braking arms 3a and 3b are resisted against the spring force of the braking springs 4a and 4b. When driven, the braking pieces 2a and 2b are separated from the braking surface 1a and the braking is released. That is, the electromagnetic attracting force of the electromagnet 6 is output in the direction in which the electromagnetic device 5 is retracted with respect to the direction connecting the other end portions 3d of the first and second braking arms 3a, 3b.

  In short, there are two sets of braking addition mechanisms by the braking springs 4a and 4b via the braking pieces 2a and 2b and the braking arms 3a and 3b, and the yokes 8 commonly used for the two sets of braking addition mechanisms, The brake release mechanisms composed of the electromagnetic coils 9a and 9b and the movable iron pieces 7a and 7b correspond to each of them, and have two sets that function independently as a brake. As shown in FIG. 2, the electromagnetic device 5 may combine the two electromagnetic coils 9A and 9b shown in FIG.

  Furthermore, the electromagnetic device 5 may be composed of two movable electromagnets 6a and 6b and one fixed iron piece 7, as shown in FIG. As in FIG. 1, the electromagnetic device 5 is provided in the vicinity of the other end 3d of the first and second braking arms 3a and 3b so as to release the pressing force of the braking springs 4a and 4b, and the electromagnet 6a, 6b consists of yokes 8a, 8b and electromagnetic coils 9a, 9b, and a fixed iron piece 7 is arranged opposite to the magnetic pole surfaces 10a, 10b of the electromagnets 6a, 6b. When the electromagnets 6a and 6b are energized, a magnetic flux is generated, and an electromagnetic attractive force acts on the fixed iron piece 7 to attract the electromagnets 6a and 6b. The other end 3d of the braking arms 3a and 3b is driven by the movable electromagnets 6a and 6b. The electromagnetic device 5 is configured so that the electromagnetic attractive force of the electromagnets 6a and 6b is output in a direction in which the electromagnetic device 5 is retracted with respect to a direction connecting the other end portions 3d of the first and second braking arms 3a and 3b.

  FIGS. 4 to 6 show a second embodiment of the present invention. FIG. 4 is a front view of an inner surface braking electromagnetic brake device according to the second embodiment of the present invention. FIGS. It is a front view which shows each separate electromagnetic device of the shown electromagnetic device. Note that the same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as necessary.

  An electromagnetic device 5 is provided in the vicinity of the other end 3d of the first and second braking arms 3a and 3b so as to release the pressing force of the braking springs 4a and 4b, and is provided with one fixed electromagnet 6. And two movable iron pieces 7a and 7b and rods 11a and 11b. The electromagnet 6 includes two electromagnetic coils 9a and 9b and a yoke 8 commonly used for the electromagnetic coils 9a and 9b. The yoke 8 has magnetic pole faces 10a and 10b at two locations. Electromagnetic coils 9a and 9b are arranged for each magnetic pole surface 10a and 10b, and have substantially two functions as electromagnets. Further, two movable iron pieces 7a and 7b are arranged facing the magnetic pole surfaces 10a and 10b, and the movable iron pieces 7a and 7b are connected to the rods 11a and 11b. The rods 11a and 11b are provided around the outside of the electromagnet 6, and the operations of the movable iron pieces 7a and 7b are output to the opposite movable iron pieces 7a and 7b, respectively. The rods 11a and 11b are connected to and driven by the other end portions 3d of the braking arms 3a and 3b via rotary levers 12a and 12b, respectively.

  The operation of this electromagnetic brake device is as follows. At the time of braking, the braking pieces 2a and 2b press the braking surface 1a of the brake drum 1 through the braking arms 3a and 3b by the braking springs 4a and 4b, and the braking state is brought about. When the brake is released, the electromagnetic coils 9a and 9b are energized to generate magnetic flux, and when the movable iron pieces 7a and 7b are electromagnetically attracted to the magnetic pole surfaces 10a and 10b, the braking is performed via the rods 11a and 11b and the rotating levers 12a and 12b. The braking arms 3a and 3b are driven against the spring force of the springs 4a and 4b, the braking pieces 2a and 2b are separated from the braking surface 1a, and the braking is released. That is, the electromagnetic attracting force of the electromagnet 6 is output in the direction in which the electromagnetic device 5 is pushed out with respect to the direction connecting the other end portions 3d of the first and second braking arms 3a, 3b. .

  In short, there are two sets of braking addition mechanisms by the braking springs 4a and 4b via the braking pieces 2a and 2b and the braking arms 3a and 3b, and the yoke 8 commonly used for these two sets of braking addition mechanisms. The brake release mechanisms composed of the electromagnetic coils 9a and 9b, the movable iron pieces 7a and 7b, the rods 11a and 11b, and the rotating levers 12a and 12b correspond to each of them, and two sets that function independently as a brake are configured. .

  As shown in FIG. 5, the electromagnetic device 5 may combine the two electromagnetic coils 9a and 9b in FIG. 4 into one electromagnetic coil 9.

  Furthermore, the electromagnetic device 5 may be composed of two movable electromagnets 6a and 6b and one fixed iron piece 7 as shown in FIG. As in FIG. 4, the electromagnetic device 5 is provided in the vicinity of the other end 3d of the first and second braking arms 3a and 3b so as to release the pressing force of the braking springs 4a and 4b, and the electromagnet 6a, 6b consists of yokes 8a, 8b and electromagnetic coils 9a, 9b, and a fixed iron piece 7 is arranged opposite to the magnetic pole surfaces 10a, 10b of the electromagnets 6a, 6b. When the electromagnets 6 a and 6 b are energized, a magnetic flux is generated, and the movable electromagnets 6 a and 6 b are electromagnetically attracted to the fixed iron piece 7. The movable electromagnets 6a and 6b are connected to rods 11a and 11b, and the rods 11a and 11b are provided around the outside of the movable electromagnets 6a and 6b. Then, the operations of the movable electromagnets 7a and 7b are respectively output to the movable electromagnets 6a and 6b on the opposite side, and the other end 3d of the braking arms 3a and 3b is driven via the rotating levers 12a and 12b. The electromagnetic device 5 is configured to output the electromagnetic attractive force of the electromagnets 6a and 6b in a direction of pushing in with respect to a direction connecting the other end portions 3d of the first and second braking arms 3a and 3b. .

  FIG. 7 is a front view of an outer peripheral surface braking type electromagnetic brake device according to a third embodiment of the present invention.

Note that the same parts as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as necessary.

  In FIG. 7, reference numeral 1 denotes a brake drum as a body to be braked, and brake pieces 2a and 2b are brought into contact with the outer peripheral braking surface 1b of the brake drum 1, respectively. Reference numerals 3a and 3b denote a pair of braking arms, which include the braking pieces 2a and 2b and rotatably support the one end 3c. Reference numerals 4a and 4b denote braking springs, which are disposed on the other end 3d of the braking arms 3a and 3b so that the braking pieces 2a and 2b apply a pressing force to the braking surfaces 1a and 1b. The spring force of the brake springs 4a and 4b is applied in the direction of pulling in the brake arms 3a and 3b when viewed from the side connecting the other end portions 3d of the brake arms 3a and 3b.

  An electromagnetic device 5 is provided in the vicinity of the other end 3d of the first and second braking arms 3a and 3b so as to release the pressing force of the braking springs 4a and 4b, and is one fixed electromagnet. 6 and two movable iron pieces 7a and 7b and rods 11a and 11b. The electromagnet 6 includes two electromagnetic coils 9a and 9b and a yoke 8 commonly used for the electromagnetic coils 9a and 9b. The yoke 8 has magnetic pole faces 10a and 10b at two locations. Electromagnetic coils 9a and 9b are arranged for each magnetic pole surface 10a and 10b, and have substantially two functions as electromagnets. Further, two movable iron pieces 7a and 7b are arranged facing the magnetic pole surfaces 10a and 10b, and the movable iron pieces 7a and 7b are connected to the rods 11a and 11b. The rods 11a and 11b bypass the outside of the electromagnet 6, and the operations of the movable iron pieces 7a and 7b are output to the opposite movable iron pieces 7b and 7a, respectively. The rods 11a and 11b are connected to and driven by the other end portions 3d of the braking arms 3a and 3b.

  The operation of this electromagnetic brake device is as follows. At the time of braking, the braking pieces 2a and 2b press the braking surface 1b of the brake drum 1 via the braking arms 3a and 3b by the braking springs 4a and 4b, and the braking state is brought about. When the brake is released, the electromagnetic coils 9a and 9b are energized to generate magnetic flux, and when the movable iron pieces 7a and 7b are electromagnetically attracted to the magnetic pole surfaces 10a and 10b, the springs of the braking springs 4a and 4b via the rods 11b and 11a. The braking arms 3a and 3b are driven against the force, the braking pieces 2a and 2b are separated from the braking surface 1b, and the braking is released. That is, the electromagnetic attracting force of the electromagnet 6 is output in the direction in which the electromagnetic device 5 is pushed out with respect to the direction connecting the other end portions 3d of the first and second braking arms 3a, 3b. . In short, there are two sets of braking addition mechanisms by the braking springs 4a and 4b via the braking pieces 2a and 2b and the braking arms 3a and 3b, and the yoke 8 commonly used for these two sets of braking addition mechanisms. The brake release mechanisms composed of the electromagnetic coils 9a and 9b, the movable iron pieces 7a and 7b, and the rods 11a and 11b correspond to each of them, and have two sets that function independently as a brake.

  The electromagnetic device 5 may be composed of two movable electromagnets 6a and 6b and one fixed iron piece 7 shown in FIG. 6 of the second embodiment.

  FIG. 8 is a front view of an outer peripheral surface braking electromagnetic brake device according to the fourth embodiment of the present invention. Note that the same parts as those of the third embodiment in FIG.

  An electromagnetic device 5 is provided in the vicinity of the other end 3d of the first and second braking arms 3a and 3b so as to release the pressing force of the braking springs 4a and 4b, and is one fixed electromagnet. 6 and two movable iron pieces 7a and 7b. The electromagnet 6 includes two electromagnetic coils 9a and 9b and a yoke 8 commonly used for the electromagnetic coils 9a and 9b. The yoke 8 has magnetic pole faces 10a and 10b at two locations. Electromagnetic coils 9a and 9b are arranged for each magnetic pole surface 10a and 10b, and have substantially two functions as electromagnets. Further, two movable iron pieces 7a and 7b are arranged opposite to the magnetic pole surfaces 10a and 10b, and the movable iron pieces 7a and 7b are respectively connected to the other end portions of the braking arms 3a and 3b via rotating levers 12a and 12b. It is connected to 3d and driven.

  The operation of this electromagnetic brake device is as follows. At the time of braking, the braking pieces 2a, 2b press the braking surface 1b of the brake drum 1 via the braking arms 3a, 3b by the braking springs 4a, 4b, and the braking state is established. When the brake is released, the electromagnetic coils 9a and 9b are energized to generate magnetic flux, and when the movable iron pieces 7a and 7b are electromagnetically attracted to the magnetic pole surface, the spring force of the braking springs 4a and 4b is obtained via the rotating levers 12a and 12b. Accordingly, the braking arms 3a and 3b are driven, the braking pieces 2a and 2b are separated from the braking surface 1b, and the braking is released. In other words, the electromagnetic attracting force of the electromagnet 6 is output in a direction in which the electromagnetic device 5 is retracted with respect to a direction connecting the other end portions 3d of the first and second braking arms 3a and 3b.

  In short, there are two sets of braking addition mechanisms by the braking springs 4a and 4b via the braking pieces 2a and 2b and the braking arms 3a and 3b, and the yoke 8 commonly used for the two sets of braking addition mechanisms. The brake release mechanisms composed of the electromagnetic coils 9a and 9b and the movable iron pieces 7a and 7b correspond to each of them, and have two sets configured to function independently as a brake. The electromagnetic device 5 may be composed of two movable electromagnets 6a and 6b and one fixed iron piece 7 shown in FIG. 3 of the first embodiment.

  FIGS. 9 to 12 show a fifth embodiment of the present invention. FIG. 9 is a front view of an elevator hoisting machine equipped with an inner peripheral surface braking electromagnetic brake according to the first embodiment. FIG. FIG. 11 is a plan view showing an electromagnetic device portion of the electromagnetic brake of FIG. 9, and FIG. 12 is a view corresponding to FIG. 11 showing another form of the electromagnetic device of the electromagnetic brake of FIG.

  9 to 11, reference numeral 21 denotes a frame having a bowl-shaped recess 21a. The opening edge 22 of the recess 21a, the bottom surface 23 of the recess 21a, the leg 24 formed on the lower side, and the legs A suspension hole 26 of the main rope 25 that penetrates the portion 24 and communicates with the recess 21a is provided. Reference numeral 27 denotes a support plate having a convex portion 28 in the lower portion, and one end portion 29a of the braking arm 29 is pivoted on the convex portion 28, and the opening edge 22 of the frame body 21 with the convex portion 28 inside. It is provided so as to cover the whole. Reference numeral 30 denotes a fastener, which is composed of a bolt inserted into the edge of the support plate 27 and screwed into the opening edge 22 of the frame body 21.

  A main shaft 31 is provided so as to protrude from the bottom surface 23 of the frame body 21 toward the recess 21a. A stator winding 32 is provided on the inner peripheral surface of the opening edge 22 of the frame 21. Reference numeral 33 denotes a saddle-like rotator, which has a saddle shape similar to the recess 21a of the frame body 21. The saddle-like rotator 33 is integrally provided with a drive sheave 34. Is pivotally supported on the outer periphery of the main shaft 31 via a bearing 34a.

  Reference numeral 35 denotes an armature disposed on the outer periphery of the outer ring portion 33a of the bowl-shaped rotating body 33 so as to face the stator winding 32 provided on the outer peripheral surface on the opening edge portion 22 side of the frame body 21. The armature 35 and the stator winding 32 constitute an electric motor. Reference numeral 36 denotes a braking surface provided on the inner periphery of the outer ring portion 33 a of the bowl-shaped rotating body 33.

  Two electromagnetic brakes 37 are arranged symmetrically about the main shaft 31 and perform braking operations in opposite directions. One end portion 29a of the braking arm 29 is pivotally supported on the convex portion 28 of the support plate 27 by a pivot pin 28a, and the other end portion 29b of the braking arm 29 passes through a groove portion 27a provided inside the support plate 27. It is disposed outside the frame body 21 beyond the end of the opening edge 22. Reference numeral 27b denotes a cover member made of a flexible elastic body such as rubber that covers the gap between the groove portion 27a of the support plate 27 and the braking arm 29, and is for preventing dust and the like from being mixed. Reference numeral 38 denotes a braking piece, which is disposed in the recess 21a of the saddle-like rotator 33 and is spherically supported by the intermediate portion 29c of the braking arm 29, and is supported by either one or both ends of the braking piece 38. It is supported by 39 and arrange | positioned so that the braking surface 36 may be pressed. The support spring 39 adjusts the inclination of the braking piece 38 and adjusts the gap with the braking surface 36.

  A brake spring 40 is provided between the support rod 41 and the spring rod 43 provided through the support base 41 provided on the upper portion of the frame 21 and connected to the other end 29b of the brake arm 29. It is fixed with a nut 45. In other words, the spring force of the brake spring 40 is applied in the pushing direction with respect to the brake arm 29 when viewed from the side connecting the other end portion 29b of the brake arm 29, and the brake piece 38 presses the brake surface 36. ing. An electromagnetic device 46 is installed as described in FIGS. 1 to 3 of the first embodiment.

  That is, the electromagnetic device 46 is provided in the vicinity of the other end 29b of the braking arm 29 so as to release the pressing force of the braking spring 40, and has one fixed electromagnet 47 and two movable iron pieces 48a, 48b. The electromagnet 47 is installed directly on the frame body 21 or via a support base 49. The electromagnet 47 includes two electromagnetic coils 50a and 50b and a yoke 51 commonly used for the electromagnetic coils 50a and 50b. The yoke 51 has magnetic pole faces 55a and 55b at two locations. The electromagnetic coils 50a and 50b are disposed for the magnetic pole surfaces 55a and 55b, respectively, and have substantially two functions as electromagnets. Two movable iron pieces 48a and 48b are arranged opposite to the magnetic pole surfaces 55a and 55b. The movable iron pieces 48a and 48b are individually screwed to the rod 52 and fixed by a locking nut 53. One end of the rod 52 is coupled to the other end portion 29 b of the braking arm 29, and the other end of the rod 52 is slidably supported by a bearing 54 provided at the central portion of the electromagnet 47. When the electromagnet 47 is energized, a magnetic flux is generated, and an electromagnetic attractive force acts on the movable iron pieces 48a and 48b to attract the movable iron pieces 48a and 48b. The other end 29b of the braking arm 29 is driven by the movable iron pieces 48a and 48b. That is, the electromagnetic attracting force of the electromagnet 47 is output in the direction in which the electromagnetic device 46 is pulled in with respect to the direction connecting the other end 29b of the braking arm 29.

  The spring force of the brake spring 40 is adjusted by turning the nut 45 to adjust the deflection of the brake spring 40. Further, by rotating the movable iron pieces 48a and 48b, the movable iron pieces 48a and 48b move in the direction of the electromagnet 47, and the stroke S1 between the movable iron pieces 48a and 48b and the electromagnet 47 can be adjusted. The stroke S2 between 36 can be adjusted. In other words, when the stroke S1 between the movable iron pieces 48a and 48b and the electromagnet 47 is defined, the stroke S2 between the brake piece 38 and the braking surface 36 is changed to the stroke S1 between the movable iron pieces 48a and 48b and the electromagnet 47. It is set in consideration of the ratio (l1 / l2). Conversely, if the stroke S2 between the braking piece 38 and the braking surface 36 is defined, the stroke S1 between the movable iron pieces 48a, 48b and the electromagnet 47 is set.

  In short, there are two sets of braking addition mechanisms by the braking spring 40 via the braking pieces 38 and the braking arms 29, and against these two sets of braking addition mechanisms, a braking release mechanism comprising an electromagnet 47 and movable iron pieces 48a and 48b is provided. Corresponding to each, there are two sets of components that function independently as a brake.

  In the elevator hoisting machine configured as described above, it is installed on the fixed part of the elevator hoistway via the legs 24 of the frame body 21, and the main rope 25 is inserted into the suspension hole 26 to drive the sheave. It is wound around 34 and suspended. The electromagnet 47 is energized to attract the movable iron pieces 48 a and 48 b against the pressing force of the braking spring 40, and the braking piece 38 is separated from the braking surface 36 of the hook-shaped rotating body 33 via the braking arm 29. When the braking of the driving sheave 34 is released and the electric motor constituted by the stator winding 32 and the armature 35 is energized, the driving sheave 34 rotates and the main rope 25 is driven by the frictional force, Although not shown, the car and the counterweight are raised and lowered in opposite directions.

  Further, the electromagnet 47 is de-energized, and the braking piece 38 is pressed against the braking surface 36 of the saddle-shaped rotator 33 by the pressing force of the braking spring 40 to brake the driving sheave 34. And the counterweight is held stopped.

  In the elevator hoisting machine configured as described above, the electromagnetic brake 37 is disposed in the recess 21a of the saddle-like rotator 33 and presses the braking surface 36, and supports the braking piece 38. One end portion 29a is opposed to the braking arm 29 supported by the support plate 27 by a pivot pin 28a, the braking spring 40 pressing the other end portion 29b of the braking arm 29, and the force of the braking spring 40. The other end 29b of the braking arm 29, the braking spring 40, and the electromagnetic device 46 are disposed outside the frame body 21.

  As a result, the other end portion 29b of the braking arm 29, the braking spring 40, and the electromagnetic device 46 are installed in the external open space of the frame body 21. Since only one end 29a of the arm 29 is disposed, the work space is widened. Therefore, the assembly work of parts as the electromagnetic brake 37, the adjustment work of the stroke S2 of the braking piece, the stroke S1 between the movable iron pieces 48a, 48b and the electromagnet 47 are performed. Adjustment work and spring force adjustment work become easier.

  In the above description, the electromagnet 47 having two electromagnetic coils is fixed by the electromagnetic device 46, and the iron pieces 48a and 48b are movably arranged. However, as described in FIG. 2 of the first embodiment, FIG. The two electromagnetic coils 50a and 50b may be combined into one electromagnetic coil.

  As shown in FIG. 12, as explained in FIG. 3 of the first embodiment, the movable iron pieces 48a and 48b and the electromagnet 47 in FIG. It may be fixed as one iron piece 48, and two electromagnets 47 may be movably arranged and electromagnets 47a and 47b each having electromagnetic coils 50a and 50b. That is, the electromagnets 47a and 47b are composed of yokes 51a and 51b and electromagnetic coils 50a and 50b, and the fixed iron piece 48 is disposed so as to face the magnetic pole surfaces 55a and 55b of the electromagnets 47a and 47b. The electromagnets 47a and 47b are individually screwed to the rod 52 and fixed by a locking nut 53. One end of the rod 52 is coupled to the other end portion 29 b of the braking arm 29, and the other end of the rod 52 is slidably supported by a bearing 54 provided at the center portion of the fixed iron piece 48.

  When the electromagnets 47a and 47b are energized, a magnetic flux is generated, and an electromagnetic attractive force acts on the fixed iron piece 48 to attract the electromagnets 47a and 47b. The other end 29b of the braking arm 29 is driven by the movable electromagnets 47a and 47b.

  The electromagnetic device 46 is configured to output the electromagnetic attractive force of the electromagnets 47a and 47b in a direction in which the electromagnetic device 46 is retracted with respect to the direction connecting the other end 29b of the braking arm 29.

  13 to 24 show a sixth embodiment of the present invention. FIG. 13 is a front view of an elevator hoisting machine equipped with an inner surface braking electromagnetic brake according to an embodiment different from FIG. 13 is a plan view of FIG. 13, FIG. 16 is a front view showing an electromagnetic device portion of the electromagnetic brake of FIG. 13, FIG. 17 is a side view of FIG. 16, and FIG. FIG. 19 is a DD view of FIG. 17, FIG. 20 is a view corresponding to FIG. 15 showing another form of the electromagnetic device of the electromagnetic brake of FIG. 13, and FIG. 21 is an electromagnetic view of the electromagnetic brake of FIG. FIG. 22 is a side view of FIG. 21, FIG. 23 is an EE view of FIG. 22, and FIG. 24 is an FF view of FIG. In addition, the same code | symbol is attached | subjected about FIG. 9 thru | or 12 of 5th Embodiment.

  Reference numeral 37 denotes an electromagnetic brake, and the braking force application mechanism using the braking spring 40, the braking arm 29, and the braking piece 38 is the same as that in the fifth embodiment, and a description thereof will be omitted. Reference numeral 40 denotes a brake spring, which is a spring rod that passes through a support base 42 provided on the upper portion of the frame body 21 and has one end pivotally supported by a pivot pin 42a and the other end coupled to the other end 29b of the brake arm 29. 43 and the support base 42 and fixed by a spring retainer 44 and a nut 45. That is, the spring force of the brake spring 40 is applied in a direction to push the brake arm 29 when viewed from the side connecting the other end portion 29b of the brake arm 29, and the brake element 38 presses the brake surface 36. ing. An electromagnetic device 46 is basically installed as described in FIGS. 4 to 6 of the second embodiment.

  That is, the electromagnetic device 46 is provided in the vicinity of the other end 29b of the braking arm 29 so as to release the pressing force of the braking spring 40, and has one fixed electromagnet 47 and two movable iron pieces 48a, 48b, rods 61a and 61b, and push plates 63a and 63b. The electromagnet 47 is installed directly on the upper portion of the frame body 21 or via a support base 62. The electromagnet 47 includes two electromagnetic coils 49a and 49b and a yoke 51 commonly used for the electromagnetic coils 49a and 49b. The yoke 51 has magnetic pole faces 55a and 55b at two locations. Electromagnetic coils 49a and 49b are arranged for the magnetic pole surfaces 55a and 55b, respectively, and have substantially two functions as electromagnets. Two movable iron pieces 48a and 48b are arranged so as to face the magnetic pole surfaces 55a and 55b. The movable iron pieces 48a and 48b are connected to one end of rods 61a and 61b provided around the outside of the electromagnet 47. The other ends of the rods 61a and 61b are coupled to the push plates 63a and 63b, and the operations of the movable iron pieces 48a and 48b are output to the opposite movable iron pieces 48b and 48a, respectively. Reference numeral 66 denotes a rotation lever provided on the support base 42. A contact rod 67 is screwed to one end and fixed with a lock nut 68, and the contact rod 67 is connected to the push plates 63a and 63b. The other end of the rotating lever 68 is connected to the other end 29 b of the braking arm 29. That is, the push plates 63a and 63b are connected to and driven by the other end portion 29b of the braking arm 29 via the rotation lever 66, respectively.

  Reference numeral 64 denotes a spring for preventing rattling of the rods 61a and 61b connecting the movable iron pieces 48a and 48b, and is mounted between the support base 62 and the spring. Reference numeral 65 denotes a support rod provided on the support base, and the movable iron pieces 48 a and 48 b are slidably supported by the support rod 65.

  When the electromagnet 47 is energized, a magnetic flux is generated, and an electromagnetic attractive force acts on the movable iron pieces 48a and 48b to attract the movable iron pieces 48a and 48b, and the rods 61a and 61b, the push plates 63a and 63b, and the rotating lever 66 are used. The other end 29b of the braking arm 29 is driven. That is, the electromagnetic attracting force of the electromagnet 47 is output in the direction in which the electromagnetic device 46 is pushed out with respect to the direction connecting the other end 29b of the braking arm 29.

  The spring force of the brake spring 40 is adjusted by turning the nut 45 to adjust the deflection of the brake spring 40. Further, by adjusting the length of the contact rod 67, the stroke S1 between the movable iron pieces 48a, 48b and the electromagnet 47 can be adjusted, and at the same time, the stroke S2 between the braking piece 38 and the braking surface 36 can be adjusted. In other words, when the stroke S1 between the movable iron pieces 48a and 48b and the electromagnet 47 is defined, the stroke S2 between the brake piece 38 and the braking surface 36 is changed to the stroke S1 between the movable iron pieces 48a and 48b and the electromagnet 47. It is set in consideration of the ratio (l1 / l2). Conversely, if the stroke S2 between the braking piece 38 and the braking surface 36 is defined, the stroke S1 between the movable iron pieces 48a, 48b and the electromagnet 47 is set.

  In short, there are two sets of braking addition mechanisms by the braking spring 40 via the braking pieces 38 and the braking arms 29, and against these two sets of braking addition mechanisms, a braking release mechanism comprising an electromagnet 47 and movable iron pieces 48a and 48b is provided. Corresponding to each, there are two sets of components that function independently as a brake.

  In the elevator hoisting machine configured as described above, it is installed on the fixed part of the elevator hoistway via the legs 24 of the frame body 21, and the main rope 25 is inserted into the suspension hole 26 to drive the sheave. It is wound around 34 and suspended. The electromagnet 47 is energized to attract the movable iron pieces 48 a and 48 b against the pressing force of the braking spring 40, and the braking piece 38 is separated from the braking surface 36 of the hook-shaped rotating body 33 via the braking arm 29. When the braking of the driving sheave 34 is released and the electric motor constituted by the stator winding 32 and the armature 35 is energized, the driving sheave 34 rotates and the main rope 25 is driven by the frictional force, Although not shown, the car and the counterweight are raised and lowered in opposite directions.

  Further, the electromagnet 47 is de-energized, and the braking piece 38 is pressed against the braking surface 36 of the saddle-shaped rotator 33 by the pressing force of the braking spring 40 to brake the driving sheave 34. And the counterweight is held stopped.

  In the elevator hoisting machine configured as described above, the electromagnetic brake 37 is disposed in the recess 21a of the saddle-like rotator 33 and presses the braking surface 36, and supports the braking piece 38. One end portion 29a is opposed to the braking arm 29 supported by the support plate 27 by a pivot pin 28a, the braking spring 40 pressing the other end portion 29b of the braking arm 29, and the force of the braking spring 40. The other end 29b of the braking arm 29, the braking spring 40, and the electromagnetic device 46 are disposed outside the frame body 21.

  As a result, the other end portion 29b of the braking arm 29, the braking spring 40, and the electromagnetic device 46 are installed in the external open space of the frame body 21. Since only one end 29a of the arm 29 is disposed, the work space is widened. Therefore, the assembly work of the parts as the electromagnetic brake 37, the stroke S2 adjustment work of the brake piece, the stroke S1 adjustment between the movable iron pieces 48a and 48b and the electromagnet 47 are adjusted. Work and adjustment of spring force become easy.

  In the above description, the electromagnet 47 having two electromagnetic coils is fixed by the electromagnetic device 46, and the iron pieces 48a and 48b are movably disposed. However, as described in FIG. 6 of the second embodiment, the two electromagnetic coils 49a, 49b may be integrated into one electromagnetic coil.

  Further, as shown in FIGS. 20 to 24, as described in FIG. 6 of the second embodiment 2 and FIG. 12 of the fifth embodiment, the movable iron pieces 48a and 48b and the electromagnet 47 in FIG. Then, the two movable iron pieces 48a and 48b are fixed as one iron piece 48, and the two electromagnets 47 are movably arranged to be electromagnets 47a and 47b each having electromagnetic coils 49a and 49b. good. That is, the electromagnets 47a and 47b are composed of yokes 50a and 50b and electromagnetic coils 49a and 49b, and the fixed iron piece 48 is disposed so as to face the magnetic pole surfaces 55a and 55b of the electromagnets 47a and 47b. The movable electromagnets 47a and 47b are connected to one ends of rods 61a and 61b that are provided around the outside of the fixed iron pieces 48a and 48b, and the other ends of the rods 61a and 61b are coupled by a push plate 63, so that the movable electromagnets 47a and 47b are connected. Are output to the movable electromagnets 47b and 47a on the opposite side. The push plates 63a and 63b are connected to the other end portion 29b of the braking arm 29 via the rotation lever 62 and driven. The movable electromagnets 47b and 47a are slidably supported by the support rod 65 as in FIG.

  When the electromagnets 47a and 47b are energized, a magnetic flux is generated, and an electromagnetic attractive force acts on the fixed iron pieces 48a and 48b to attract the movable electromagnets 47a and 47b. The rods 61a and 61b, the push plates 63a and 63b, and the rotary lever 66 are moved. Thus, the other end 29b of the braking arm 29 is driven. That is, the electromagnetic attracting force of the electromagnetic 47 is output in the direction in which the electromagnetic device 46 is pushed out with respect to the direction connecting the other end 29b of the braking arm 29.

1 is a front view of an inner surface braking electromagnetic brake device according to a first embodiment of the present invention. FIG. 2 is a front view showing another electromagnetic device of the electromagnetic device shown in FIG. FIG. 5 is a front view showing still another electromagnetic device of the electromagnetic device shown in FIG. It is a front view of the inner peripheral surface braking electromagnetic brake device according to the second embodiment of the present invention. It is a front view which shows another electromagnetic device of the electromagnetic device shown in FIG. It is a front view which shows another electromagnetic device of the electromagnetic device shown in FIG. FIG. 7 is a front view of an outer peripheral surface braking type electromagnetic brake device according to a third embodiment of the present invention. It is a front view of the outer peripheral surface braking type electromagnetic brake device which becomes the 4th embodiment of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view of an elevator hoist equipped with an inner peripheral surface braking electromagnetic brake according to a first embodiment. It is AA sectional drawing of FIG. It is a top view which shows the electromagnetic device part of the electromagnetic brake of FIG. FIG. 12 is a view corresponding to FIG. 11 showing another form of the electromagnetic device of the electromagnetic brake of FIG. 9. It is a front view of the elevator hoisting machine provided with the inner peripheral surface braking electromagnetic brake of the embodiment different from FIG. It is BB sectional drawing of FIG. FIG. 14 is a plan view of FIG. 13. It is a front view which shows the electromagnetic device part of the electromagnetic brake of FIG. FIG. 17 is a side view of FIG. 16. It is CC view of FIG. FIG. 18 is a DD view of FIG. 17. FIG. 15 is a view corresponding to FIG. 15 and showing another form of the electromagnetic device of the electromagnetic brake of FIG. 13. It is a front view which shows the electromagnetic device part of the electromagnetic brake of FIG. It is a side view of FIG. It is the EE view of FIG. It is the FF view of FIG.

Explanation of symbols

1a, 1b, 36 Brake surface 2a, 2b, 38 Brake piece 3a, 3b, 29 Brake arm 3d, 29b Brake arm other end 4a, 4b, 40 Brake spring 8, 8a, 8b yoke 9a, 9b Electromagnetic coil 6 6a, 6b, 47 Electromagnets 10a, 10b, 55a, 55b Magnetic pole surfaces 7, 7a, 7b, 48, 48a, 48b Iron pieces 11a, 11b, 61a, 61b Output rods 12a, 12b, 66 Rotating lever 22 Opening edge 32 Fixed Child winding 21 Frame 21a Recess 31 Spindle 34 Drive sheave 33 Hook-like rotating body 35 Armature 27 Support plate 37 Electromagnetic brake device 28a Pivoting pin 46 Electromagnetic device

Claims (9)

First and second braking arms having a braking piece disposed on a braking surface of the braked body and having one end portion rotatably supported, and the braking piece presses the braking surface to brake the braked body It arrange | positions so that it may operate | move in the direction which connects the braking spring provided in the other end part of said 1st and 2nd braking arms, and the other end part of said 1st and 2nd braking arms, From a yoke and an electromagnetic coil And the first and second brake arms are driven against the spring force of the brake spring by the electromagnetic attractive force when the electromagnet is energized. And an electromagnetic brake device including an electromagnetic device that releases the pressing force of the braking piece and releases the braking of the braked body,
With the above electromagnetic device constituted by one fixed electromagnet and two movable iron piece, through the upper hear dynamic iron drives each of the first and second brake arms above, the electromagnet is two electromagnetic An electromagnetic brake device comprising a coil and a yoke commonly used for the two electromagnetic coils . First and second braking arms each having a braking piece disposed on a braking surface of a braked body and having one end rotated and supported, and the braking piece presses the braking surface to brake the braked body It arrange | positions so that it may operate | move in the direction which connects the braking spring provided in the other end part of said 1st and 2nd braking arms, and the other end part of said 1st and 2nd braking arms, From a yoke and an electromagnetic coil And the first and second brake arms are driven against the spring force of the brake spring by the electromagnetic attractive force when the electromagnet is energized. And an electromagnetic brake device including an electromagnetic device that releases the pressing force of the braking piece and releases the braking of the braked body,
The electromagnetic device is composed of two movable electromagnets and one movable iron piece, and drives the first and second braking arms via the movable electromagnets. The two electromagnets are respectively an electromagnetic coil and an electromagnetic coil. An electromagnetic brake device comprising a yoke, wherein the two electromagnets face the fixed iron piece . 3. The electromagnetic device according to claim 1, wherein the electromagnetic device outputs an electromagnetic attraction force in a pulling direction or a pushing direction with respect to a direction connecting the other end portions of the first and second braking arms. electromagnetic brake system. The electromagnetic device is provided with an output rod that outputs an electromagnetic attraction force in a pulling direction or a pushing direction with respect to a direction connecting the first and second braking arms, and the first and second braking arms are provided by the output rod. 4. The electromagnetic brake device according to claim 3, wherein each of the other end portions of the motor is driven . 5. The electromagnetic brake device according to claim 4, wherein the other end portions of the first and second braking arms are driven from the output rod via a rotating lever . 6. The electromagnetic brake device according to claim 5, wherein the output rod is disposed outside the electromagnet. The electromagnetic device is provided with a rotating lever that outputs an electromagnetic attraction force in a pulling direction or a pushing direction with respect to a direction connecting the first and second braking arms, and the first and second braking arms are provided by the rotating lever. 4. The electromagnetic brake device according to claim 3, wherein each of the other end portions of the motor is driven. Arranged in a bowl-like frame body provided with a stator winding on the inner peripheral surface of the opening edge, a main shaft provided so as to protrude from the bottom surface of this frame body to the recess side, and the above-mentioned frame body A saddle-shaped rotating body having a drive sheave pivoted on the main shaft, an armature disposed on the outer periphery of the outer ring portion of the saddle-shaped rotating body so as to face the stator winding, and the outer ring Of an elevator hoisting machine comprising a braking surface provided on an inner peripheral surface of a part, a support plate having an edge mounted on an opening edge of the frame, and an electromagnetic brake device that brakes the braking surface. In the brake system,
  The electromagnetic device of the electromagnetic brake device is composed of one fixed electromagnet and two movable iron pieces, and the first and second braking arms are driven through the movable iron piece, and the electromagnet has two pieces. It consists of an electromagnetic coil and a yoke commonly used for the two electromagnetic coils, and one end of the first and second braking arms of the electromagnetic brake device is pivoted to the support plate by a pivot pin. The other end portion is disposed outside the frame body beyond the edge of the opening edge, and the braking spring and the electromagnetic device are disposed outside the frame body, and the two sets perform braking operation in opposite directions to each other. The brake piece is pressed against the braking surface by the force of the braking spring and braked, and the other end portion of the braking arm is driven by the electromagnetic device so that the braking piece is separated from the braking surface to release the braking. Elevator hoisting machine characterized by Electromagnetic brake system. Arranged in a bowl-like frame body provided with a stator winding on the inner peripheral surface of the opening edge, a main shaft provided so as to protrude from the bottom surface of this frame body to the recess side, and the above-mentioned frame body A saddle-shaped rotating body having a drive sheave pivoted on the main shaft, an armature disposed on the outer periphery of the outer ring portion of the saddle-shaped rotating body so as to face the stator winding, and the outer ring Of an elevator hoisting machine comprising a braking surface provided on an inner peripheral surface of a part, a support plate having an edge mounted on an opening edge of the frame, and an electromagnetic brake device that brakes the braking surface. In the brake system,
  The electromagnetic device of the electromagnetic brake device is composed of two movable electromagnets and one movable iron piece, and drives the first and second braking arms via the movable electromagnets, respectively. Is composed of an electromagnetic coil and a yoke, so that the two electromagnets are opposed to the fixed iron piece, and one end portions of the first and second braking arms of the electromagnetic brake device are connected to the support plate by a pivot pin. The other end is disposed outside the frame body beyond the edge of the opening edge, and the braking spring and the electromagnetic device are disposed outside the frame body to perform braking operation in opposite directions. It consists of two sets, and the braking piece is pressed against the braking surface by the force of the braking spring for braking, and the other end of the braking arm is driven by the electromagnetic device to release the braking piece from the braking surface to release the braking. D that is characterized by Electromagnetic brake system of the activator for the hoisting machine.

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