CN218025046U - Wind-powered electricity generation hoist and mount protector - Google Patents

Abstract

The utility model belongs to the technical field of wind-powered electricity generation hoist and mount, concretely relates to wind-powered electricity generation hoist and mount protector, comprising a base plate, install the bearing frame on the bottom plate, and a support, pulley holder one and pulley holder two, the support passes through the connecting axle and rotates the connecting seat of connecting planking side-mounting, the planking body passes through the backup pad and connects the inner plate body, the inner plate body coupling has end plate and strengthening rib, the bracing piece one that planking body bottom surface was equipped with and the both ends of bracing piece two rotate and install hydraulic buffer, hydraulic buffer bottom is tied and is hung wire rope one and the two difference sliding connection pulley holders of wire rope one of connection, pulley holder two and the other end are tied and are hung on bobbin one and bobbin two, bobbin one, bobbin two is installed on the main shaft, the main shaft passes through speed reducer transmission connection motor. The beneficial effects of the utility model are that: the outer plate body is inclined synchronously along with the tower under the traction of the first steel wire rope and the second steel wire rope, and the end plates are matched to provide reliable support for the tower, so that the tower is prevented from deforming, wearing and colliding due to inertial deflection.

Description

Wind-powered electricity generation hoist and mount protector

Technical Field

The utility model belongs to the technical field of wind-powered electricity generation hoist and mount, concretely relates to wind-powered electricity generation hoist and mount protector.

Background

Wind power generation refers to converting kinetic energy of wind into electric energy. Wind energy is a clean and pollution-free renewable energy source, is utilized by people for a long time, mainly pumps water and grinds surfaces and the like through a windmill, is very environment-friendly by utilizing wind power for power generation, has huge wind energy content, and is increasingly valued by countries in the world.

The method has the advantages that the hoisting device is needed in the process of assembling wind power, the traditional hoisting modes are divided into two modes, one mode is that two groups of cranes are used for horizontally hoisting two ends of a tower drum, the mode has high operation requirements, and safety accidents are easy to happen when the hoisting speeds of the two cranes are different; the other mode is that one end of a tower is hoisted and connected by using one crane machine, the tower is hoisted, and the operation requirement is low in this mode, but when the tower is hoisted, one end of the tower is firstly obliquely lifted, the other end of the tower is supported on the ground, the contact surface between the tower and the ground is reduced, the pressure is increased, the deformation and the abrasion of the contact position are caused, in addition, the horizontal posture of the tower is changed into the vertical posture when the tower is hoisted, in the posture change process, the tower lacks of lateral support, the generated inertia can enable the tower to shift for a distance, and the tower is easy to collide with other objects during the shifting to cause damage.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model aims to: the utility model provides a wind-powered electricity generation hoist and mount protector, the problem that the inertia that solves a tower section of thick bamboo and lifts by crane the support that lacks the side direction when the gesture changes, produces can make a tower section of thick bamboo skew and bump with other objects.

For the purpose of realizing above, the utility model discloses a technical scheme: the utility model provides a wind-powered electricity generation hoist and mount protector, includes the bottom plate, bearing frame, support, pulley holder one and pulley holder two are installed to the top surface of bottom plate, the top of support is passed through the connecting axle and is rotated the connection connecting seat, the side of plate body outside the connecting seat installation, the inner wall connection of outer plate body has the backup pad, the one end of backup pad is connected with the inner plate body, the one end of inner plate body inner wall is connected with the end plate, be connected with the strengthening rib between end plate and the inner plate body, the both ends of outer plate body bottom surface are equipped with bracing piece one and bracing piece two respectively, the both ends of bracing piece one and bracing piece two are all rotated and are installed hydraulic buffer, hydraulic buffer's bottom is tied and is hung connection wire rope one and wire rope two, wire rope one and two other ends of two difference sliding connection pulley holders of wire rope, pulley holder two and wire rope one, wire rope two are tied respectively and are hung on a winding section of thick bamboo one and two, a winding section of thick bamboo is installed on the main shaft, main shaft transmission connection speed reducer just rotates and installs on the bearing frame, speed reducer transmission connection motor.

The utility model has the advantages that: when the tower barrel is hoisted, the outer plate body tilts synchronously along with the tower barrel under the traction of the first steel wire rope and the second steel wire rope, and the outer plate body is matched with the end plate to provide reliable support for the tower barrel, so that the tower barrel is prevented from deforming, wearing and colliding due to inertial deflection.

In order to provide stable support for the outer plate body;

as a further improvement of the above technical solution: the number of the supports is two, the supports are oppositely arranged on two sides of the outer plate body, the bottom sides of the supports are connected with one side face of the reinforcing rib, and the bottom face of the reinforcing rib is connected with the top face of the bottom plate.

The beneficial effect of this improvement does: the reinforcing rib can improve the structural stability of support, guarantees that the support carries out stable support to the external plate body.

For stable drawing of the outer plate body;

as a further improvement of the technical scheme: the number of the pulley seats I and the number of the pulley seats II are two, the pulley seats I and the pulley seats II are oppositely arranged on two sides of the outer plate body, the steel wire rope is wound and connected with the winding drum I, and the steel wire rope is wound and connected with the winding drum II.

The beneficial effect of this improvement does: the outer plate body is stably used under the traction of four groups of steel wire ropes.

In order to eliminate the adverse effect of vibration generated in the hoisting process on the first steel wire rope and the second steel wire rope;

as a further improvement of the technical scheme: the number of the hydraulic buffers is four, and the two ends of the first supporting rod and the second supporting rod are located on the outer side of the outer plate body.

The beneficial effect of this improvement does: the hydraulic buffer provides a buffer function, and avoids the damage of the steel wire rope due to instantaneous acting force.

For stable support of the tower;

as a further improvement of the above technical solution: the inner plate body is of a semicircular pipe structure, the two ends of the inner plate body are flush with the two ends of the outer plate body, the end plate is of a semicircular plate structure, and the top end of the end plate is flush with the top end of the inner plate body.

The beneficial effect of this improvement does: the lateral surface of a tower section of thick bamboo can the laminating be supported to the inner plate body, and when a tower section of thick bamboo slope, the end plate provides stable support for the bottom of a tower section of thick bamboo.

In order to improve the supporting strength of the inner plate body;

as a further improvement of the above technical solution: the backup pad comprises the square board that the axis of a plurality of interior plate bodys set up for surrounding axle circumference preface, and the both ends of backup pad and the both ends parallel and level of interior plate body.

The beneficial effect of this improvement does: the backup pad provides stable support for the inner plate body.

In order to improve the supporting strength of the end plate;

as a further improvement of the above technical solution: the strengthening rib comprises a plurality of plate bodies that use the axis of end plate as the equiphase setting of surrounding shaft circumference.

The beneficial effect of this improvement does: the reinforcing ribs provide stable support for the end plates.

The parts of the device not involved are the same as or can be implemented using prior art.

Drawings

Fig. 1 is a first schematic structural diagram of the present invention;

fig. 2 is a top view of the present invention;

fig. 3 is a side view of the present invention;

FIG. 4 is a second schematic structural view of the present invention;

in the figure: 1. a base plate; 2. a support; 3. reinforcing ribs; 4. a motor; 5. a speed reducer; 6. a bearing seat; 7. a first winding drum; 8. a second winding drum; 9. a first steel wire rope; 10. a second steel wire rope; 11. a first pulley seat; 12. a second pulley seat; 13. a connecting shaft; 14. an outer plate body; 15. a support plate; 16. an inner plate body; 17. an end plate; 18. reinforcing ribs; 19. a hydraulic buffer; 20. a first supporting rod; 21. a second supporting rod; 22. a main shaft; 23. a connecting seat.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings in order to make those skilled in the art better understand the technical solution of the present invention, and the description in this section is only exemplary and illustrative, and should not be construed as limiting the scope of the present invention in any way.

Example 1:

as shown in fig. 1-4: the utility model provides a wind-powered electricity generation hoist and mount protector, includes bottom plate 1, bearing frame 6, support 2, pulley holder one 11 and pulley holder two 12 are installed to the top surface of bottom plate 1, connecting seat 23 is connected in the rotation of connecting axle 13 on the top of support 2, connecting seat 23 installs the side at outer plate 14, outer plate 14's inner wall is connected with backup pad 15, the one end of backup pad 15 is connected with inner plate 16, the one end of inner plate 16 inner wall is connected with end plate 17, be connected with strengthening rib 18 between end plate 17 and the inner plate 16, the both ends of outer plate 14 bottom surface are equipped with bracing piece one 20 and bracing piece two 21 respectively, the both ends of bracing piece one 20 and bracing piece two 21 all rotate and install hydraulic buffer 19, connect wire rope one 9 and wire rope two 10 are tied to hang in the bottom of hydraulic buffer 19, wire rope one 9 and wire rope two 10 are respectively sliding connection pulley holder one 11, pulley holder two 12 and wire rope one 9, the other end of wire rope two 10 are tied to be tied to hang on a coiling section of thick bamboo two 8 respectively, a 7, a coiling section of thick bamboo two 8 are installed on main shaft 22, main shaft 22 is installed at the transmission, the transmission of main shaft 5 is connected on the motor reducer 6, 4 the motor reducer is connected.

The working principle of the technical scheme is as follows: firstly, the wind power tower cylinder is moved to the inner plate body 16 through two cranes, at the moment, the inner plate body 16 is in a horizontal state, one end of the end plate 17 is tightly attached to one end of the tower cylinder, then, a single crane is used for hoisting, along with the inclination of the tower cylinder, the motor 4 runs simultaneously, the main shaft 22 is driven by the speed reducer 5 to rotate in a speed reduction mode, the main shaft 22 drives the first winding cylinder 7 and the second winding cylinder 8 to rotate synchronously, one of the first steel wire rope 9 and the second steel wire rope 10 is tightened up while the other is lengthened, the outer plate body 14 rotates by taking the connecting shaft 13 as a supporting shaft, and further the inner plate body 16 and the end plate 17 are reliably supported when the tower cylinder is obliquely hoisted.

Example 2:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a wind power hoisting protection device includes a bottom plate 1, a bearing seat 6, a support 2, a first pulley seat 11 and a second pulley seat 12 are installed on a top surface of the bottom plate 1, a top end of the support 2 is rotatably connected to a connection seat 23 through a connection shaft 13, the connection seat 23 is installed on a side surface of an outer plate 14, an inner wall of the outer plate 14 is connected to a support plate 15, one end of the support plate 15 is connected to an inner plate 16, one end of an inner wall of the inner plate 16 is connected to an end plate 17, a reinforcing rib 18 is connected between the end plate 17 and the inner plate 16, two ends of a bottom surface of the outer plate 14 are respectively provided with a first support rod 20 and a second support rod 21, two ends of the first support rod 20 and the second support rod 21 are respectively rotatably installed with a hydraulic buffer 19, a bottom end of the hydraulic buffer 19 is connected to the first steel wire rope 9 and the second steel wire rope 10 in a hanging manner, the first steel wire rope 9 and the second steel wire rope 10 are respectively slidably connected to the first pulley seat 11, the second pulley seat 12, the other ends of the first steel wire rope 9 and the second steel wire rope 10 are respectively hung to a first winding drum 7 and a second winding drum 8, the first winding drum 7, the second winding drum 5, the main shaft 22 is installed on a transmission shaft transmission, and the main shaft transmission 5, and the main shaft transmission mechanism is connected to the main shaft transmission mechanism 5, and the main shaft transmission mechanism 5. The number of the support frames 2 is two, the support frames are oppositely arranged on two sides of the outer plate body 14, the bottom side of each support frame 2 is connected with one side face of the reinforcing rib 3, and the bottom face of each reinforcing rib 3 is connected with the top face of the bottom plate 1.

Example 3:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a wind power hoisting protection device includes a bottom plate 1, a bearing seat 6, a support 2, a first pulley seat 11 and a second pulley seat 12 are installed on a top surface of the bottom plate 1, the top end of the support 2 is rotatably connected with a connection seat 23 through a connection shaft 13, the connection seat 23 is installed on a side surface of an outer plate 14, an inner wall of the outer plate 14 is connected with a support plate 15, one end of the support plate 15 is connected with an inner plate 16, one end of an inner wall of the inner plate 16 is connected with an end plate 17, a reinforcing rib 18 is connected between the end plate 17 and the inner plate 16, two ends of a bottom surface of the outer plate 14 are respectively provided with a first support rod 20 and a second support rod 21, two ends of the first support rod 20 and the second support rod 21 are rotatably installed with a hydraulic buffer 19, a bottom end of the hydraulic buffer 19 is fastened with the first steel wire rope 9 and the second steel wire rope 10, the first steel wire rope 9 and the second steel wire rope 10 are respectively slidably connected with the first pulley seat 11, the second pulley seat 12, the other end of the first steel wire rope 10 are respectively fastened on a first winding drum 7 and a second winding drum 8, the main shaft 5, and the main shaft 5 is connected with a main shaft 5, and the main shaft 5 is connected with a motor 5. The number of the pulley seats I11 and the number of the pulley seats II 12 are two, the two pulley seats I and the two pulley seats II are respectively and oppositely arranged on two sides of the outer plate body 14, the steel wire rope I9 is connected with the winding drum I7 in a winding mode, and the steel wire rope II 10 is connected with the winding drum II 8 in a winding mode.

Example 4:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a wind power hoisting protection device includes a bottom plate 1, a bearing seat 6, a support 2, a first pulley seat 11 and a second pulley seat 12 are installed on a top surface of the bottom plate 1, the top end of the support 2 is rotatably connected with a connection seat 23 through a connection shaft 13, the connection seat 23 is installed on a side surface of an outer plate 14, an inner wall of the outer plate 14 is connected with a support plate 15, one end of the support plate 15 is connected with an inner plate 16, one end of an inner wall of the inner plate 16 is connected with an end plate 17, a reinforcing rib 18 is connected between the end plate 17 and the inner plate 16, two ends of a bottom surface of the outer plate 14 are respectively provided with a first support rod 20 and a second support rod 21, two ends of the first support rod 20 and the second support rod 21 are rotatably installed with a hydraulic buffer 19, a bottom end of the hydraulic buffer 19 is fastened with the first steel wire rope 9 and the second steel wire rope 10, the first steel wire rope 9 and the second steel wire rope 10 are respectively slidably connected with the first pulley seat 11, the second pulley seat 12, the other end of the first steel wire rope 10 are respectively fastened on a first winding drum 7 and a second winding drum 8, the main shaft 5, and the main shaft 5 is connected with a main shaft 5, and the main shaft 5 is connected with a motor 5. The number of the hydraulic buffers 19 is four, and both ends of the first support rod 20 and the second support rod 21 are located at the outer side of the outer plate 14.

Example 5:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a wind power hoisting protection device includes a bottom plate 1, a bearing seat 6, a support 2, a first pulley seat 11 and a second pulley seat 12 are installed on a top surface of the bottom plate 1, a top end of the support 2 is rotatably connected to a connection seat 23 through a connection shaft 13, the connection seat 23 is installed on a side surface of an outer plate 14, an inner wall of the outer plate 14 is connected to a support plate 15, one end of the support plate 15 is connected to an inner plate 16, one end of an inner wall of the inner plate 16 is connected to an end plate 17, a reinforcing rib 18 is connected between the end plate 17 and the inner plate 16, two ends of a bottom surface of the outer plate 14 are respectively provided with a first support rod 20 and a second support rod 21, two ends of the first support rod 20 and the second support rod 21 are respectively rotatably installed with a hydraulic buffer 19, a bottom end of the hydraulic buffer 19 is connected to the first steel wire rope 9 and the second steel wire rope 10 in a hanging manner, the first steel wire rope 9 and the second steel wire rope 10 are respectively slidably connected to the first pulley seat 11, the second pulley seat 12, the other ends of the first steel wire rope 9 and the second steel wire rope 10 are respectively hung to a first winding drum 7 and a second winding drum 8, the first winding drum 7, the second winding drum 5, the main shaft 22 is installed on a transmission shaft transmission, and the main shaft transmission 5, and the main shaft transmission mechanism is connected to the main shaft transmission mechanism 5, and the main shaft transmission mechanism 5. The interior plate body 16 is the semicircle tubular structure, the both ends of interior plate body 16 and the both ends parallel and level of outer plate body 14, end plate 17 is the semicircle plate structure, and the top of end plate 17 and the top parallel and level of interior plate body 16.

Example 6:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a wind power hoisting protection device includes a bottom plate 1, a bearing seat 6, a support 2, a first pulley seat 11 and a second pulley seat 12 are installed on a top surface of the bottom plate 1, a top end of the support 2 is rotatably connected to a connection seat 23 through a connection shaft 13, the connection seat 23 is installed on a side surface of an outer plate 14, an inner wall of the outer plate 14 is connected to a support plate 15, one end of the support plate 15 is connected to an inner plate 16, one end of an inner wall of the inner plate 16 is connected to an end plate 17, a reinforcing rib 18 is connected between the end plate 17 and the inner plate 16, two ends of a bottom surface of the outer plate 14 are respectively provided with a first support rod 20 and a second support rod 21, two ends of the first support rod 20 and the second support rod 21 are respectively rotatably installed with a hydraulic buffer 19, a bottom end of the hydraulic buffer 19 is connected to the first steel wire rope 9 and the second steel wire rope 10 in a hanging manner, the first steel wire rope 9 and the second steel wire rope 10 are respectively slidably connected to the first pulley seat 11, the second pulley seat 12, the other ends of the first steel wire rope 9 and the second steel wire rope 10 are respectively hung to a first winding drum 7 and a second winding drum 8, the first winding drum 7, the second winding drum 5, the main shaft 22 is installed on a transmission shaft transmission, and the main shaft transmission 5, and the main shaft transmission mechanism is connected to the main shaft transmission mechanism 5, and the main shaft transmission mechanism 5. The backup pad 15 comprises a plurality of square boards that the axis of interior plate body 16 set up for surrounding the equal preface of axle circumference, and the both ends of backup pad 15 and the both ends parallel and level of interior plate body 16.

Example 7:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, a wind power hoisting protection device includes a bottom plate 1, a bearing seat 6, a support 2, a first pulley seat 11 and a second pulley seat 12 are installed on a top surface of the bottom plate 1, the top end of the support 2 is rotatably connected with a connection seat 23 through a connection shaft 13, the connection seat 23 is installed on a side surface of an outer plate 14, an inner wall of the outer plate 14 is connected with a support plate 15, one end of the support plate 15 is connected with an inner plate 16, one end of an inner wall of the inner plate 16 is connected with an end plate 17, a reinforcing rib 18 is connected between the end plate 17 and the inner plate 16, two ends of a bottom surface of the outer plate 14 are respectively provided with a first support rod 20 and a second support rod 21, two ends of the first support rod 20 and the second support rod 21 are rotatably installed with a hydraulic buffer 19, a bottom end of the hydraulic buffer 19 is fastened with the first steel wire rope 9 and the second steel wire rope 10, the first steel wire rope 9 and the second steel wire rope 10 are respectively slidably connected with the first pulley seat 11, the second pulley seat 12, the other end of the first steel wire rope 10 are respectively fastened on a first winding drum 7 and a second winding drum 8, the main shaft 5, and the main shaft 5 is connected with a main shaft 5, and the main shaft 5 is connected with a motor 5. The reinforcing ribs 18 are formed by a plurality of plate bodies which are arranged in a circumferential sequence around the axis of the end plate 17.

The utility model discloses a theory of operation and use flow: firstly, the wind power tower cylinder is moved to the inner plate body 16 through two cranes, at the moment, the inner plate body 16 is in a horizontal state, one end of the end plate 17 is tightly attached to one end of the tower cylinder, then, a single crane is used for hoisting, along with the inclination of the tower cylinder, the motor 4 runs simultaneously, the main shaft 22 is driven by the speed reducer 5 to rotate in a speed reduction mode, the main shaft 22 drives the first winding cylinder 7 and the second winding cylinder 8 to rotate synchronously, one of the first steel wire rope 9 and the second steel wire rope 10 is tightened up while the other is lengthened, the outer plate body 14 rotates by taking the connecting shaft 13 as a supporting shaft, and further the inner plate body 16 and the end plate 17 are reliably supported when the tower cylinder is obliquely hoisted.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts of the present invention. The foregoing is only a preferred embodiment of the present invention, and it should be noted that there are objectively infinite specific structures due to the limited character expressions, and it will be apparent to those skilled in the art that a plurality of modifications, decorations or changes may be made without departing from the principle of the present invention, and the above technical features may be combined in a suitable manner; such modifications, variations, combinations, or adaptations of the invention using its spirit and scope, as defined by the claims, may be directed to other uses and embodiments.

Claims (7)

1. The utility model provides a wind-powered electricity generation hoist and mount protector which characterized in that: the steel wire rope winding machine comprises a bottom plate (1), wherein a bearing seat (6), a support (2), a pulley seat I (11) and a pulley seat II (12) are installed on the top surface of the bottom plate (1), the top end of the support (2) is rotatably connected with a connecting seat (23) through a connecting shaft (13), the connecting seat (23) is installed on the side surface of an outer plate body (14), the inner wall of the outer plate body (14) is connected with a supporting plate (15), one end of the supporting plate (15) is connected with an inner plate body (16), one end of the inner wall of the inner plate body (16) is connected with an end plate (17), a reinforcing rib (18) is connected between the end plate (17) and the inner plate body (16), two ends of the bottom surface of the outer plate body (14) are respectively provided with a supporting rod I (20) and a supporting rod II (21), two ends of the supporting rod I (20) and the supporting rod II (21) are rotatably installed with a hydraulic buffer (19), the bottom end of the hydraulic buffer (19) is connected with a steel wire rope I (9) and a steel wire rope II (10) in a hanging manner, the steel wire rope I (9) and the steel wire rope II (10) are respectively in a sliding connection manner, the pulley seat I (11), the steel wire rope II (9) and the other end (12) of the steel wire rope (7) are respectively, and a pulley cylinder (7) are respectively wound on the steel wire rope cylinder (7), the winding drum I (7) and the winding drum II (8) are installed on the main shaft (22), the main shaft (22) is in transmission connection with the speed reducer (5) and is installed on the bearing seat (6) in a rotating mode, and the speed reducer (5) is in transmission connection with the motor (4).

2. The wind power hoisting protection device according to claim 1, characterized in that: the number of the supports (2) is two, the supports are oppositely arranged on two sides of the outer plate body (14), the bottom side of each support (2) is connected with one side face of the corresponding reinforcing rib (3), and the bottom face of each reinforcing rib (3) is connected with the top face of the corresponding bottom plate (1).

3. The wind power hoisting protection device according to claim 1, characterized in that: the number of the pulley seats I (11) and the number of the pulley seats II (12) are two, the pulley seats I and the pulley seats II are oppositely arranged on two sides of the outer plate body (14), the steel wire rope I (9) is connected with the winding drum I (7) in a winding mode, and the steel wire rope II (10) is connected with the winding drum II (8) in a winding mode.

4. The wind power hoisting protection device according to claim 1, characterized in that: the number of the hydraulic buffers (19) is four, and two ends of the first supporting rod (20) and the second supporting rod (21) are located on the outer side of the outer plate body (14).

5. The wind power hoisting protection device according to claim 1, characterized in that: the interior plate body (16) is semicircle tubular structure, the both ends of interior plate body (16) and the both ends parallel and level of planking body (14), end plate (17) are semicircle board structure, and the top of end plate (17) and the top parallel and level of interior plate body (16).

6. The wind power hoisting protection device according to claim 1, characterized in that: backup pad (15) comprise for the square board that encircles the equiphase setting of axle circumference by a plurality of axis that fall plate body (16) within, and the both ends parallel and level of the both ends of backup pad (15) and interior plate body (16).

7. The wind power hoisting protection device according to claim 1, characterized in that: the reinforcing ribs (18) are composed of a plurality of plate bodies which are arranged in an equi-sequence mode around the circumferential direction of the shaft by taking the axis of the end plate (17) as the axis.

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