CN211868679U - Synchronous belt machining equipment - Google Patents

Abstract

The utility model provides a synchronous belt processing device, which comprises a workbench, a feeding mechanism, a cutting mechanism, a feeding mechanism, a transferring mechanism and a pressing mechanism, wherein the feeding mechanism, the cutting mechanism, the feeding mechanism, the transferring mechanism and the pressing mechanism are arranged on the workbench; the feeding mechanism is used for conveying the synchronous belt; the cutting mechanism is used for cutting off the synchronous belt; the feeding mechanism is used for conveying the copper sleeve to the pressing mechanism; the transfer mechanism is used for penetrating two end parts of the synchronous belt into the copper sleeve; the pressing mechanism is used for pressing the copper sleeve on two end parts of the synchronous belt. The utility model discloses a hold-in range processing equipment can automatic intercepting predetermined length's hold-in range, still can be automatic on the hold-in range crimping copper sheathing, improved production efficiency, reduced the cost of labor, and can guarantee the quality of hold-in range.

Description

Synchronous belt machining equipment

Technical Field

The utility model relates to a hold-in range processing field, concretely relates to hold-in range processing equipment.

Background

Need intercepting certain length during the hold-in range processing, then press the copper sheathing at the hold-in range both ends of intercepting. Among the prior art, the intercepting of hold-in range and pressure copper sheathing are all accomplished by the manual work, behind the length of artifical survey hold-in range, again by artifical intercepting, then reuse manual press presses the shape card with the copper sheathing on the hold-in range, and efficiency is lower, and the cost of labor is higher, and the quality is difficult to guarantee.

SUMMERY OF THE UTILITY MODEL

Problem based on prior art, the utility model provides a hold-in range processing equipment.

The utility model provides a synchronous belt processing device, which comprises a workbench, a feeding mechanism, a cutting mechanism, a feeding mechanism, a transferring mechanism and a pressing mechanism, wherein the feeding mechanism, the cutting mechanism, the feeding mechanism, the transferring mechanism and the pressing mechanism are arranged on the workbench;

the feeding mechanism is used for conveying the synchronous belt;

the blanking mechanism is used for cutting off the synchronous belt;

the feeding mechanism is used for conveying the copper sleeve to the pressing mechanism;

the transfer mechanism is used for penetrating two end parts of the synchronous belt into the copper sleeve;

the pressing mechanism is used for pressing the copper sleeve on two end parts of the synchronous belt.

Further, the feeding mechanism comprises a first fixing frame, a material tray and a conveying device;

the first fixing frame is arranged on the workbench;

the material tray and the conveying device are arranged on the first fixing frame; wherein,

the charging tray is used for setting a synchronous belt, and the conveying device is used for outputting the synchronous belt arranged on the charging tray.

Further, the conveying device comprises a rotating motor, a rotating main wheel and a rotating auxiliary wheel;

the rotating motor is arranged on the first fixing frame;

the rotating main wheel is arranged on a motor shaft of the rotating motor;

the rotating auxiliary wheel is rotatably arranged on the first fixing frame, and a gap is formed between the rotating auxiliary wheel and the rotating main wheel; wherein,

after the synchronous belt passes through the gap between the main rotating wheel and the auxiliary rotating wheel, a motor shaft of the rotating motor rotates to output the synchronous belt.

Further, the material cutting mechanism comprises a first fixing plate, a second fixing plate, a material cutting cylinder, a movable cutter and a fixed cutter;

the blanking cylinder is arranged on the first fixing plate;

the movable knife is arranged on a piston rod of the material cutting cylinder;

the fixed cutter is arranged on the second fixing plate; wherein,

the first fixing plate is close to the second fixing plate, so that a shearing space is formed between the movable cutter and the fixed cutter, and after the synchronous belt penetrates through the shearing space, the material cutting cylinder can drive the movable cutter and the fixed cutter to be matched with each other to cut off the synchronous belt.

Further, the feeding mechanism comprises a vibrating disc; the discharging channel of the vibrating disc is connected with the pressing mechanism; the vibrating disc is used for conveying the copper bush to the pressing mechanism.

Furthermore, the transferring mechanism comprises a first clamping jaw air cylinder, a first transferring module, a second clamping jaw air cylinder and a second transferring module;

the first clamping jaw air cylinder is used for clamping a synchronous belt so as to enable one end of the synchronous belt to penetrate into one side of the copper sleeve;

the second clamping jaw air cylinder is used for clamping a synchronous belt so as to enable the other end of the synchronous belt to penetrate into the other side of the copper sleeve;

the first transfer module is connected with the first clamping jaw air cylinder and used for moving the first clamping jaw air cylinder;

the second transfer module is connected with the second clamping jaw air cylinder and used for moving the second clamping jaw air cylinder.

Furthermore, the transfer mechanism also comprises a first mounting plate, a second mounting plate and a pushing cylinder;

the first clamping jaw air cylinder is arranged on the first transfer module;

the first transfer module and the second clamping jaw air cylinder are arranged on the first mounting plate;

the first mounting plate is arranged on the second mounting plate in a sliding mode;

the pushing cylinder is arranged on the second mounting plate, and a piston rod of the pushing cylinder is connected with the first mounting plate and used for pushing the first mounting plate to slide;

the second mounting plate is arranged on the workbench in a sliding mode;

the second moves and carries the module setting and is in on the workstation and hookup the second mounting panel is used for promoting the second mounting panel slides, and then promotes the removal of second clamping jaw cylinder.

Further, the first transfer module comprises a first driving motor, a first screw rod and a first sliding block;

the first driving motor and the first screw rod are arranged on the first mounting plate, and a motor shaft of the first driving motor is connected with the first screw rod so as to drive a moving nut of the first screw rod to move; the first sliding block is arranged on the moving nut of the first screw rod; the first clamping jaw air cylinder is arranged on the first sliding block;

the second transfer module comprises a second driving motor, a second screw rod and a second sliding block;

the second driving motor and the second screw rod are arranged on the workbench, and a motor shaft of the second driving motor is connected with the second screw rod so as to drive a moving nut of the second screw rod to move; the second sliding block is arranged on a moving nut of the second screw rod; the second slider is coupled to the second mounting plate.

Further, the pressing mechanism comprises a second fixing frame, an upper pressing knife, a side pressing push rod, an upper pressing cylinder, a side pressing cylinder, a positioning piece and a guide piece, wherein the upper pressing cylinder, the side pressing cylinder, the positioning piece and the guide piece are arranged on the second fixing frame;

the guide piece is provided with a guide channel, the inlet of the guide channel is connected with the feeding mechanism, and the feeding mechanism can input the copper bush to the guide channel;

the positioning piece is provided with a positioning groove which is positioned at the outlet of the guide channel;

the side pressure push rod is connected with a piston rod of the side pressure cylinder and penetrates into the guide channel so as to push the copper sleeve entering the guide channel out of the positioning groove of the positioning piece under the pushing of the side pressure cylinder;

the upper pressing knife is connected with a piston rod of the upper pressing cylinder and used for extruding the copper sleeve under the pushing of the upper pressing cylinder so as to press the copper sleeve on two ends of the synchronous belt.

Further, the workbench is provided with a discharge groove, and the discharge groove is located below the pressing mechanism.

The utility model discloses a hold-in range processing equipment can automatic intercepting predetermined length's hold-in range, still can be automatic on the hold-in range crimping copper sheathing, improved production efficiency, reduced the cost of labor, and can guarantee the quality of hold-in range.

Drawings

Fig. 1 is a schematic structural diagram of a synchronous belt processing apparatus according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a feeding mechanism and a blanking mechanism in a synchronous belt processing device according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a transfer mechanism in a synchronous belt processing apparatus according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a pressing mechanism in a synchronous belt processing device according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that all directional indicators (such as up, down, left, right, front, back, horizontal, vertical, etc.) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. under a certain posture (as shown in the drawings), if the certain posture changes, the directional indicator changes accordingly, the "connection" may be a direct connection or an indirect connection, and the "setting", and "setting" may be directly or indirectly set.

In addition, descriptions in the present application as to "first", "second", and the like are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Fig. 1 is a schematic structural diagram of a synchronous belt processing apparatus according to an embodiment of the present invention, in this embodiment, the synchronous belt processing apparatus includes a worktable 10, and a feeding mechanism 40, a cutting mechanism 50, a feeding mechanism 20, a transferring mechanism 60, and a pressing mechanism 30, which are disposed on the worktable 10; the feeding mechanism 40 is used for conveying the synchronous belt 70; the blanking mechanism 50 is used for cutting off the synchronous belt 70; the feeding mechanism 20 is used for conveying the copper sleeve 80 to the pressing mechanism 30; the transfer mechanism 60 is used for penetrating two end parts of the synchronous belt 70 into the copper sleeve 80; the press-fit mechanism 30 is used to press-fit the copper bush 80 onto both end portions of the timing belt 70.

In an alternative embodiment, for example, as shown in fig. 2, the feeding mechanism 40 includes a first fixing frame 41, a tray 42 and a conveying device 40; the first fixing frame 41 is arranged on the workbench 10; the tray 42 and the conveying device 40 are arranged on the first fixing frame 41; the tray 42 is provided with a timing belt 70, and the transport device 40 is configured to output the timing belt 70 provided on the tray 42.

In an alternative embodiment, such as the present embodiment, shown in fig. 2, the conveyor 40 comprises a rotary motor 43, a rotary main wheel 45 and a rotary auxiliary wheel 44; the rotating motor 43 is arranged on the first fixing frame 41; the rotation main wheel 45 is arranged on a motor shaft of the rotation motor 43; the auxiliary rotating wheel 44 is rotatably arranged on the first fixed frame 41 and forms a gap with the main rotating wheel 45; after the synchronous belt 70 passes through the gap between the main rotating wheel 45 and the auxiliary rotating wheel 44, the motor shaft of the rotating motor 43 rotates to enable the main rotating wheel 45 and the auxiliary rotating wheel 44 to be matched with each other to output the synchronous belt 70.

In an alternative embodiment, for example, in the present embodiment, as shown in fig. 2, the material cutting mechanism 50 includes a first fixing plate 52, a second fixing plate 55, a material cutting cylinder 51, a movable blade 53 and a fixed blade 54; the blanking cylinder 51 is arranged on the first fixing plate 52; the movable knife 53 is arranged on a piston rod of the material cutting cylinder 51; the fixed knife 54 is disposed on the second fixing plate 55; the first fixing plate 52 is close to the second fixing plate 55 to form a cutting space between the movable blade 53 and the fixed blade 54, and after the synchronous belt 70 passes through the cutting space, the material cutting cylinder 51 can drive the movable blade 53 and the fixed blade 54 to cut off the synchronous belt 70 in a matching manner. In the present embodiment, the first fixing plate 52 and the second fixing plate 55 are disposed on the first fixing frame 41, and the movable blade 53 and the fixed blade 54 are located at the discharging side of the main rotating wheel 45 and the sub rotating wheel 44 so as to cut the timing belt 70.

In an alternative embodiment, such as the present embodiment, shown in fig. 1, the feed mechanism 20 includes a vibratory pan 201; the discharging channel 202 of the vibrating disc 201 is connected with the pressing mechanism 30; wherein, the vibrating disk 201 is used for conveying the copper bush 80 to the pressing mechanism 30.

In an alternative embodiment, for example, in the present embodiment, as shown in fig. 3, the transferring mechanism 60 includes a first clamping jaw cylinder 61, a first transferring module 63, a second clamping jaw cylinder 62, and a second transferring module 69; the first clamping jaw air cylinder 61 is used for clamping the synchronous belt 70 so as to penetrate one end of the synchronous belt 70 into one side of the copper sleeve 80; the second clamping jaw air cylinder 62 is used for clamping the synchronous belt 70 so as to penetrate the other end of the synchronous belt 70 into the other side of the copper sleeve 80; the first transfer module 63 is connected with the first clamping jaw cylinder 61 and used for moving the first clamping jaw cylinder 61; the second transfer module 69 is coupled to the second jaw cylinder 62 for moving the second jaw cylinder 62.

In an alternative embodiment, for example, in the present embodiment, as shown in fig. 3, the transfer mechanism 60 further includes a first mounting plate 65, a second mounting plate 66, and a pushing cylinder 67; the first clamping jaw air cylinder 61 is arranged on the first transfer module 63; the first transfer module 63 and the second clamping jaw air cylinder 62 are arranged on the first mounting plate 65; the first mounting plate 65 is slidably disposed on the second mounting plate 66; the pushing cylinder 67 is arranged on the second mounting plate 66, and a piston rod of the pushing cylinder is connected with the first mounting plate 65 and used for pushing the first mounting plate 65 to slide; the second mounting plate 66 is slidably arranged on the workbench 10; the second transfer module 69 is disposed on the working platform 10 and coupled to the second mounting plate 66, for pushing the second mounting plate 66 to slide, and further pushing the second clamping jaw cylinder 62 to move. In this embodiment, the first transfer module 63 and the second transfer module 69 are matched to flexibly move the first clamping jaw cylinder 61 and the second clamping jaw cylinder 62, so that the first clamping jaw cylinder 61 and the second clamping jaw cylinder 62 can more grab the synchronous belt 70 to penetrate into the copper sleeve 80.

In an alternative embodiment, for example, in this embodiment, as shown in fig. 3, the first transferring module 63 includes a first driving motor 631, a first lead screw 632, and a first sliding block 633; the first driving motor 631 and the first lead screw 632 are arranged on the first mounting plate 65, and a motor shaft of the first driving motor 631 is coupled with the first lead screw 632 to drive the moving nut of the first lead screw 632 to move; the first slider 633 is arranged on the moving nut of the first lead screw 632; the first jaw cylinder 61 is provided on the first slider 633; the second transfer module 69 comprises a second driving motor 691, a second screw rod 692 and a second slide block 693; a second driving motor 691 and a second lead screw 692 are arranged on the workbench 10, and a motor shaft of the second driving motor 691 is connected with the second lead screw 692 to drive the moving nut of the second lead screw 692 to move; the second slider 693 is provided on the moving nut of the second screw rod 692; the second slider 693 is coupled to the second mounting plate 66.

In an alternative embodiment, for example, in the present embodiment, as shown in fig. 4, the pressing mechanism 30 includes a second fixing frame 31, an upper pressing blade 34, a lateral pressing push rod 36, and an upper pressing cylinder 33, a lateral pressing cylinder 32, a positioning member 35, and a guiding member 37 disposed on the second fixing frame 31; the guide piece 37 is provided with a guide channel, the inlet 371 of the guide channel is connected with the feeding mechanism 20, and the feeding mechanism 20 can input the copper bush 80 to the guide channel; the positioning member 35 is provided with a positioning groove 351, and the positioning groove 351 is positioned at the outlet of the guide channel; the side pressure push rod 36 is connected with a piston rod of the side pressure cylinder 32, and the side pressure push rod 36 penetrates into the guide channel to push the copper sleeve 80 entering the guide channel out of the positioning groove 351 of the positioning piece 35 under the pushing of the side pressure cylinder 32; the upper pressing blade 34 is coupled with a piston rod of the upper pressing cylinder 33, and is used for extruding the copper bush 80 under the pushing of the upper pressing cylinder 33, so as to press-fit the copper bush 80 on both ends of the synchronous belt 70. Further, the discharge passage 202 of the vibration plate 201 is connected to the inlet 371 of the guide passage.

In an alternative embodiment, for example the present embodiment, as shown in fig. 1, the work table 10 is provided with a discharge chute 11, the discharge chute 11 being located below the stitching mechanism 30.

In this embodiment, when the machining device of the synchronous belt 70 is in operation, the vibrating disc 201 of the feeding mechanism 20 conveys the copper sleeve 80 into the guide channel of the guide member 37, the side pressure cylinder 32 pushes the copper sleeve 80 into the positioning groove 351 of the positioning member 35 through the side pressure push rod 36, after one end of the synchronous belt 70 arranged on the tray 42 passes through between the rotating main wheel 45 and the rotating auxiliary wheel 44 and between the moving blade 53 and the stationary blade 54, the rotating motor 43 rotates to continue outputting the synchronous belt 70, meanwhile, the first clamping jaw cylinder 61 clamps the front end of the synchronous belt 70 to the positioning groove 351 and penetrate into one side of the copper sleeve 80, after the synchronous belt 70 is output to a predetermined length, the rotating motor 43 stops rotating, the second clamping jaw cylinder 62 clamps the part of the synchronous belt 70 close to the moving blade 53 and the stationary blade 54, the cutting cylinder 51 pushes the moving blade 53 close to the stationary blade 54 to cut off the synchronous belt 70 in cooperation with the stationary blade 54, the second clamping jaw 62 sends the rear end of the synchronous belt 70 to the positioning groove 351 and, then the upper pressing cylinder 33 pushes the upper pressing knife 34 to squeeze the copper sleeve 80, so that the copper sleeve 80 is pressed on two ends of the synchronous belt 70, and finally the synchronous belt 70 is released by the first clamping jaw cylinder 61 and the second clamping jaw cylinder 62 simultaneously, so that the synchronous belt 70 falls into the discharge groove 11 under the action of gravity and is discharged from the discharge groove 11.

In the embodiment, the synchronous belt 70 processing equipment is controlled by an intelligent terminal such as a computer, and the work flow of the synchronous belt 70 processing equipment is controlled by a preset control program. In this embodiment, the predetermined length of the timing belt 70 may be accomplished by a length measuring sensor or the like, which is a measuring device commonly used in the art.

In this embodiment, hold-in range 70 processing equipment can automatic intercepting the hold-in range 70 of predetermined length, still can be automatic on hold-in range 70 crimping copper sheathing 80, improved production efficiency, reduced the cost of labor, and can avoid the artifical condition that the distance is unanimous inadequately when penetrating hold-in range 70 the both sides of copper sheathing 80, also can avoid the condition that each hold-in range 70 product pressfitting dynamics is different when pressing copper sheathing 80, guaranteed the uniformity and the qualification nature of hold-in range 70 product.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the same way in the protection scope of the present invention.

Claims (10)

1. A synchronous belt processing device is characterized by comprising a workbench, and a feeding mechanism, a cutting mechanism, a feeding mechanism, a transferring mechanism and a pressing mechanism which are arranged on the workbench;

the feeding mechanism is used for conveying the synchronous belt;

the blanking mechanism is used for cutting off the synchronous belt;

the feeding mechanism is used for conveying the copper sleeve to the pressing mechanism;

the transfer mechanism is used for penetrating two end parts of the synchronous belt into the copper sleeve;

the pressing mechanism is used for pressing the copper sleeve on two end parts of the synchronous belt.

2. The synchronous belt processing apparatus of claim 1, wherein the feeding mechanism comprises a first fixing frame, a tray and a conveying device;

the first fixing frame is arranged on the workbench;

the material tray and the conveying device are arranged on the first fixing frame; wherein,

the charging tray is used for setting a synchronous belt, and the conveying device is used for outputting the synchronous belt arranged on the charging tray.

3. The synchronous belt processing apparatus as claimed in claim 2, wherein the conveying means comprises a rotary motor, a rotary main wheel and a rotary sub-wheel;

the rotating motor is arranged on the first fixing frame;

the rotating main wheel is arranged on a motor shaft of the rotating motor;

the rotating auxiliary wheel is rotatably arranged on the first fixing frame, and a gap is formed between the rotating auxiliary wheel and the rotating main wheel; wherein,

after the synchronous belt passes through the gap between the main rotating wheel and the auxiliary rotating wheel, a motor shaft of the rotating motor rotates to output the synchronous belt.

4. The synchronous belt processing equipment as in claim 1, wherein the blanking mechanism comprises a first fixing plate, a second fixing plate, a blanking cylinder, a movable knife and a fixed knife;

the blanking cylinder is arranged on the first fixing plate;

the movable knife is arranged on a piston rod of the material cutting cylinder;

the fixed cutter is arranged on the second fixing plate; wherein,

the first fixing plate is close to the second fixing plate, so that a shearing space is formed between the movable cutter and the fixed cutter, and after the synchronous belt penetrates through the shearing space, the material cutting cylinder can drive the movable cutter and the fixed cutter to be matched with each other to cut off the synchronous belt.

5. The synchronous belt processing apparatus of claim 1, wherein the feed mechanism comprises a vibratory pan; the discharging channel of the vibrating disc is connected with the pressing mechanism; the vibrating disc is used for conveying the copper bush to the pressing mechanism.

6. The synchronous belt processing apparatus of claim 1, wherein the transfer mechanism comprises a first gripper cylinder, a first transfer module, a second gripper cylinder, and a second transfer module;

the first clamping jaw air cylinder is used for clamping a synchronous belt so as to enable one end of the synchronous belt to penetrate into one side of the copper sleeve;

the second clamping jaw air cylinder is used for clamping a synchronous belt so as to enable the other end of the synchronous belt to penetrate into the other side of the copper sleeve;

the first transfer module is connected with the first clamping jaw air cylinder and used for moving the first clamping jaw air cylinder;

the second transfer module is connected with the second clamping jaw air cylinder and used for moving the second clamping jaw air cylinder.

7. The synchronous belt processing apparatus of claim 6, wherein the transfer mechanism further comprises a first mounting plate, a second mounting plate, and a push cylinder;

the first clamping jaw air cylinder is arranged on the first transfer module;

the first transfer module and the second clamping jaw air cylinder are arranged on the first mounting plate;

the first mounting plate is arranged on the second mounting plate in a sliding mode;

the pushing cylinder is arranged on the second mounting plate, and a piston rod of the pushing cylinder is connected with the first mounting plate and used for pushing the first mounting plate to slide;

the second mounting plate is arranged on the workbench in a sliding mode;

the second moves and carries the module setting and is in on the workstation and hookup the second mounting panel is used for promoting the second mounting panel slides, and then promotes the removal of second clamping jaw cylinder.

8. The synchronous belt processing apparatus of claim 7, wherein the first transfer module comprises a first drive motor, a first lead screw, and a first slide block;

the first driving motor and the first screw rod are arranged on the first mounting plate, and a motor shaft of the first driving motor is connected with the first screw rod so as to drive a moving nut of the first screw rod to move; the first sliding block is arranged on the moving nut of the first screw rod; the first clamping jaw air cylinder is arranged on the first sliding block;

the second transfer module comprises a second driving motor, a second screw rod and a second sliding block;

the second driving motor and the second screw rod are arranged on the workbench, and a motor shaft of the second driving motor is connected with the second screw rod so as to drive a moving nut of the second screw rod to move; the second sliding block is arranged on a moving nut of the second screw rod; the second slider is coupled to the second mounting plate.

9. The synchronous belt processing device as claimed in claim 1, wherein the press-fit mechanism comprises a second fixed frame, an upper press knife, a lateral press push rod, and an upper press cylinder, a lateral press cylinder, a positioning element and a guiding element which are arranged on the second fixed frame;

the guide piece is provided with a guide channel, the inlet of the guide channel is connected with the feeding mechanism, and the feeding mechanism can input the copper bush to the guide channel;

the positioning piece is provided with a positioning groove which is positioned at the outlet of the guide channel;

the side pressure push rod is connected with a piston rod of the side pressure cylinder and penetrates into the guide channel so as to push the copper sleeve entering the guide channel out of the positioning groove of the positioning piece under the pushing of the side pressure cylinder;

the upper pressing knife is connected with a piston rod of the upper pressing cylinder and used for extruding the copper sleeve under the pushing of the upper pressing cylinder so as to press the copper sleeve on two ends of the synchronous belt.

10. The synchronous belt processing apparatus as in claim 1, wherein the table is provided with a discharge chute located below the stitching mechanism.

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