CN210972685U - Vertical steel belt type conveying mechanism - Google Patents

Abstract

The utility model discloses a vertical steel belt type conveying mechanism, which comprises a headstock tensioning device, a tailstock tensioning device, two guide rail assemblies and a steel belt assembly, wherein the headstock tensioning device and the tailstock tensioning device are correspondingly arranged, the two guide rail assemblies are symmetrically arranged, one ends of the two guide rail assemblies are respectively positioned at two sides of the headstock tensioning device, the other ends of the two guide rail assemblies are respectively positioned at two sides of the top end surface of the tailstock tensioning device, and the two guide rail assemblies are formed by connecting a plurality of guide rail parts; the headstock tensioning device, the tailstock tensioning device and the two guide rail assemblies form an annular loop; the steel belt assembly is arranged in the annular loop in a surrounding mode, and the tail tensioning device is used for driving the steel belt assembly to rotate in the annular loop. The utility model discloses operate steadily, the difficult dislocation of flange has reduced the wearing and tearing that cause the flange to practice thrift a large amount of gas consumptions.

Description

Vertical steel belt type conveying mechanism

Technical Field

The utility model relates to a perpendicular steel band formula conveying mechanism belongs to spinning machine conveying equipment technical field.

Background

The traditional collection all adopts the cylinder to push away the transport form of convex plate, and its air consumption is big, and the convex plate wearing and tearing are serious, and the convex plate is easy to be misplaced, and the convex plate operation is unstable.

Disclosure of Invention

For solving the not enough of prior art, the utility model provides a perpendicular steel band formula conveying mechanism operates steadily, and the protruding dish is difficult for the dislocation, has reduced the wearing and tearing that cause the protruding dish to use gas in a large number of sparingly.

The utility model discloses the technical scheme who adopts does:

a vertical steel belt type conveying mechanism comprises a headstock tensioning device, a tailstock tensioning device, two guide rail assemblies and a steel belt assembly, wherein the headstock tensioning device and the tailstock tensioning device are arranged correspondingly, the two guide rail assemblies are symmetrically arranged, one ends of the two guide rail assemblies are respectively positioned on two sides of the headstock tensioning device, the other ends of the two guide rail assemblies are respectively positioned on two sides of the top end surface of the tailstock tensioning device, and the two guide rail assemblies are formed by connecting a plurality of guide rail parts; the headstock tensioning device, the tailstock tensioning device and the two guide rail assemblies form an annular loop; the steel belt assembly is arranged in the annular loop in a surrounding mode, and the tail tensioning device is used for driving the steel belt assembly to rotate in the annular loop.

Preferably, the vehicle head tensioning mechanism comprises a vehicle head base plate, a vehicle head tensioning plate is arranged at the top of the vehicle head base plate, a first steel belt wheel shaft is arranged on each of two sides of the top of the vehicle head tensioning plate, steel belt wheels are arranged on the tops of the first steel belt wheels, a vehicle head guide rail support is arranged on the rear end face of the vehicle head tensioning plate between the two steel belt wheels, and a vehicle head guide rail for the steel belt assembly to pass through is arranged on the rear end face of the top of the vehicle head guide rail support.

Further preferably, a steel belt wheel shield is further arranged on one side of the two steel belt wheels, which is close to each other.

Preferably, the vehicle tail tensioning device comprises a vehicle tail bottom plate, a vehicle tail tensioning plate is arranged on the end face of the front end of the top of the vehicle tail bottom plate, two cushion blocks are respectively arranged on two sides of the top of the vehicle tail tensioning plate, a motor mounting plate is horizontally arranged on the tops of the cushion blocks, tensioning blocks are respectively arranged on the vehicle tail bottom plate at the rear end of the vehicle tail tensioning plate and correspond to the two cushion blocks at the rear end of the vehicle tail tensioning plate, threaded rods are respectively in threaded connection with block bodies of the tensioning blocks, and one ends of the threaded rods are abutted to the corresponding cushion blocks; two steel belt wheel shafts II are correspondingly arranged on two sides of the top of the tailstock tensioning plate, the tops of the two steel belt wheel shafts II are respectively inserted through the motor mounting plate, a steel belt driving wheel is arranged at the top of the steel belt wheel shaft II positioned above the motor mounting plate on the left side of the tailstock tensioning plate, and a steel belt driven wheel is arranged at the top of the steel belt wheel shaft II positioned above the motor mounting plate on the right side of the tailstock tensioning plate; a steel belt motor is arranged at the rear end of a motor mounting plate between a steel belt driving wheel and a steel belt driven wheel, an execution shaft of the steel belt motor is vertically arranged downwards and extends to the lower part of the motor mounting plate, a synchronous belt driving wheel is arranged at the tail end of the execution shaft of the steel belt motor, a synchronous belt driven wheel is arranged on a steel belt wheel shaft II, the top of which is provided with the steel belt driving wheel, corresponding to the synchronous belt driving wheel, and synchronous belts are arranged around the outer parts of the synchronous belt driving wheel and the synchronous belt driven wheel; the front end of the motor mounting plate between the steel belt driving wheel and the steel belt driven wheel is provided with a tail guide rail for the steel belt assembly to pass through.

Preferably, the steel strip assembly comprises a steel strip and a plurality of steel strip convex disc components arranged on the steel strip, the steel strip convex disc components comprise double-ingot convex discs and second pressing plates, the double-ingot convex discs are arranged at the top of the steel strip, and the second pressing plates are symmetrically arranged on two sides of the steel strip and are positioned right below the double-ingot convex discs; the steel band encircles and sets up in the periphery of two steel band pulleys, hold-in range action wheel and hold-in range follower, is formed with the draw-in groove that supplies the inboard clamp plate two of steel band to rotate the joint respectively on two steel band pulleys, hold-in range action wheel and hold-in range follower.

Preferably, the guide rail part comprises a groove-shaped guide rail, support plates are symmetrically arranged on the side walls of two sides inside a groove body of the groove-shaped guide rail, the support plates are also arranged on the side walls of two sides inside the groove body of the headstock guide rail and the tailstock guide rail, first press plates are symmetrically arranged on two sides of the guide rail, the bottom of the double-ingot convex disc is located on the support plates on two sides, two sides of the top of the double-ingot convex disc are pressed below the press plates, and the steel belt and the second press plates on two sides of the steel belt are clamped in the guide rail between the two support plates and rotate in the guide rail under the driving of.

Further preferably, two yarn shoveling devices are symmetrically arranged on two sides of the guide rail of one of the guide rail components of the left guide rail assembly, a support is arranged at the top of each yarn shoveling device on the inner side of the guide rail, a travel switch is arranged on each support, an execution end of the travel switch is arranged towards the guide rail, and the travel switch is electrically connected with the steel belt motor.

Preferably, a convex disc positioning photoelectric support is further arranged at the front end of the motor mounting plate between the steel belt driving wheel and the steel belt driven wheel.

Preferably, the steel belt motor is externally connected with a power-off alarm.

The beneficial effects of the utility model reside in that:

the two sides of the double-spindle convex disc are correspondingly clamped between the first pressing plate and the support plates on the corresponding sides respectively, the steel belt is clamped in the guide rail between the two support plates and rotates in the guide rail under the driving of the steel belt motor, the operation stability is improved, the air cylinder is not needed to push the convex disc, a large amount of air is used, and the abrasion to the convex disc is reduced while the operation is stable at a constant speed.

Drawings

FIG. 1 is a three-dimensional structure of the present invention;

FIG. 2 is a schematic structural view of a headstock tensioning device;

FIG. 3 is a schematic view of a vehicle tail tensioner;

FIG. 4 is a left side view of the vehicle tail tensioner;

FIG. 5 is a schematic view of the structure of the rail member;

FIG. 6 is a schematic structural view of a steel strip flange part;

the main reference numerals in the figures have the following meanings:

3.1, a headstock tensioning device, 3.1.1, a headstock bottom plate, 3.1.2, a headstock tensioning plate, 3.1.3, a steel belt wheel, 3.1.4, a first steel belt wheel shaft, 3.1.5, a steel belt wheel shield, 3.1.6, a headstock guide rail, 3.2, a tailstock tensioning device, 3.2.1, a tailstock bottom plate, 3.2.2, a tailstock tensioning plate, 3.2.3, a motor mounting plate, 3.2.4, a tensioning block, 3.2.5, a cushion block, 3.2.6, a second steel belt wheel shaft, 3.2.7, a steel belt driving wheel, 3.2.8, a steel belt driven wheel, 3.2.9, a steel belt motor, 3.2.10, a convex disc positioning photoelectric support, 3.2.11, a tailstock guide rail, 3.2.12, a synchronous belt driving wheel, 3.2.13, a synchronous belt driven wheel, 3.2.14, a synchronous belt, 3.3, a guide rail component, 3.3.3.1, a guide rail, 3.3.3.2, a first convex disc positioning photoelectric support, a 3.4, a convex disc support, a 3.3.4, a double-pulley switch, a 3.4, a steel belt switch, a 3.3.3.4, a steel belt switch, a spindle switch, a 3.3.4, a steel belt switch, a steel belt.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples.

As shown in fig. 1-6: the embodiment is a vertical steel belt type conveying mechanism, which comprises a headstock tensioning device 3.1, a tailstock tensioning device 3.2, two guide rail assemblies and a steel belt assembly, wherein the headstock tensioning device 3.1 and the tailstock tensioning device 3.2 are correspondingly arranged, the two guide rail assemblies are symmetrically arranged, one ends of the two guide rail assemblies are respectively positioned at two sides of the headstock tensioning device 3.1, the other ends of the two guide rail assemblies are respectively positioned at two sides of the top end surface of the tailstock tensioning device 3.2, and the two guide rail assemblies are formed by connecting a plurality of guide rail parts 3.3; the headstock tensioning device 3.1, the tailstock tensioning device 3.2 and the two guide rail assemblies form an annular loop; the steel belt assembly is arranged in the annular loop in a surrounding mode, and the tail tensioning device 3.2 is used for driving the steel belt assembly to rotate in the annular loop.

Referring to fig. 1 and 2, the headstock tensioning mechanism 3.1 includes a headstock bottom plate 3.1.1, a headstock tensioning plate 3.1.2 is disposed on the top of the headstock bottom plate 3.1.1, steel belt wheel shafts 3.1.4 are respectively disposed on two sides of the top of the headstock tensioning plate 3.1.2, steel belt wheels 3.1.3 are respectively disposed on the top of the steel belt wheel shafts 3.1.4, a headstock guide rail bracket 3.1.6 is disposed on the rear end face of the headstock tensioning plate 3.1.2 between the two steel belt wheels 3.1.3, and a grooved headstock guide rail 3.1.7 for the steel belt assembly to pass through is disposed on the rear end face of the top of the headstock guide rail bracket 3.1.6.

Referring to fig. 2, a steel pulley shield 3.1.5 is further disposed on a side where the two steel pulleys 3.1.3 are close to each other.

Referring to fig. 1, 3 and 4, the tailstock tensioning device 3.2 comprises a tailstock bottom plate 3.2.1, a tailstock tensioning plate 3.2.2 is arranged on the end surface of the front end of the top of the tailstock bottom plate 3.2.1, two cushion blocks 3.2.5 are respectively arranged on two sides of the top of the tailstock tensioning plate 3.2.2, a motor mounting plate 3.2.3 is horizontally arranged on the top of the cushion block 3.2.5, a screw rod is respectively connected with a block body of the tensioning block 3.2.4 in a threaded manner, and one end of the screw rod is abutted to the corresponding cushion block 3.2.5, and two cushion blocks 3.2.5 corresponding to the rear end of the tailstock tensioning plate 3.2.2 are respectively arranged on the tailstock bottom plate 3.2.1 at the rear end of the tailstock tensioning plate 3.2.2; two steel belt wheel shafts 3.2.6 are correspondingly arranged on two sides of the top of the tail tensioning plate 3.2.2, the tops of the two steel belt wheel shafts 3.2.6 are respectively inserted through the motor mounting plates 3.2.3, a steel belt driving wheel 3.2.7 is arranged on the top of the steel belt wheel shaft 3.2.6 on the left side of the tail tensioning plate 3.2.2 and above the motor mounting plates 3.2.3, and a steel belt driven wheel 3.2.8 is arranged on the top of the steel belt wheel shaft 3.2.6 on the right side of the tail tensioning plate 3.2.2 and above the motor mounting plates 3.2.3; a steel belt motor 3.2.9 is installed at the rear end of a motor installation plate 3.2.3 between a steel belt driving wheel 3.2.7 and a steel belt driven wheel 3.2.8, an execution shaft of a steel belt motor 3.2.9 is vertically arranged downwards and extends to the lower part of the motor installation plate 3.2.3, a synchronous belt driving wheel 3.2.12 is arranged at the tail end of the execution shaft of the steel belt motor 3.2.9, a synchronous belt driven wheel 3.2.13 is arranged on a steel belt pulley shaft II 3.2.6 of which the top is provided with the steel belt driving wheel 3.2.7 corresponding to the synchronous belt driving wheel 3.2.12, and a synchronous belt 3.2.14 is arranged outside the synchronous belt driving wheel 3.2.12 and the synchronous belt driven wheel 3.2.13 in a surrounding mode; a groove-shaped tail guide rail 3.2.11 for the steel belt assembly to pass through is arranged at the front end of the motor mounting plate 3.2.3 between the steel belt driving wheel 3.2.7 and the steel belt driven wheel 3.2.8.

Referring to fig. 6, the steel strip assembly comprises a steel strip 3.4.1 and a plurality of steel strip protruding disc components 3.4 arranged on the steel strip 3.4.1, the steel strip protruding disc components 3.4 comprise a double-ingot protruding disc 3.4.2 and a pressing plate two 3.4.3, the double-ingot protruding disc 3.4.2 is arranged on the top of the steel strip 3.4.1, and the pressing plate two 3.4.3 are symmetrically arranged on two sides of the steel strip 3.4.1 and are positioned right below the double-ingot protruding disc 3.4.2; the steel band 3.4.1 encircles and sets up in the periphery of two steel band pulleys 3.1.3, hold-in range action wheel 3.2.12 and hold-in range follower 3.2.13, is formed with the draw-in groove that supplies the inboard clamp plate two 3.4.3 of steel band 3.4.1 to rotate the joint respectively on two steel band pulleys 3.1.3, hold-in range action wheel 3.2.12 and hold-in range follower 3.2.13.

Referring to fig. 1 and 5, the guide rail part 3.3 includes a groove-shaped guide rail 3.3.1, support plates 3.3.6 are symmetrically arranged on two side walls inside a groove body of the groove-shaped guide rail 3.3.1, the support plates 3.3.6 are also arranged on two side walls inside the groove body of the headstock guide rail 3.1.7 and the tailstock guide rail 3.2.11, pressure plates 3.3.2 are symmetrically arranged on two sides of the guide rail 3.3.1, the bottom of the double-ingot convex disc 3.4.2 is arranged on the support plates 3.3.6 on two sides, two sides of the top of the double-ingot convex disc 3.4.2 are pressed below the pressure plates 3.3.2, and the steel belt 3.4.1 and the pressure plates two 3.4.3 on two sides of the steel belt 3.4.1 are clamped in the guide rail 3.3.1 between the two support plates 3.6 and rotate in the guide rail 3.3.1 under the driving of the steel belt 3.2.9. .

Referring to fig. 1 and 5, two yarn shoveling devices 3.3.3 are symmetrically arranged on two sides of a guide rail 3.3.1 of one guide rail component 3.3 of the left guide rail assembly, a bracket 3.3.4 is arranged at the top of the yarn shoveling device 3.3.3 inside the guide rail 3.3.1, a travel switch 3.3.5 is arranged on the bracket 3.3.4, an execution end of the travel switch 3.3.5 is arranged towards the guide rail 3.3.1, and the travel switch 3.3.5 is electrically connected with a steel belt motor 3.2.9.

Referring to fig. 3 and 4, a convex disc positioning photoelectric bracket 3.2.10 is further mounted at the front end of the motor mounting plate 3.2.3 between the steel belt driving wheel 3.2.7 and the steel belt driven wheel 3.2.8.

In this embodiment, the steel belt motor 3.2.9 is further externally connected with a power-off alarm, the steel belt motor 3.2.9 is powered off after the steel belt motor 3.2.9 is not touched by the yarn shoveling device 3.3.3 and the execution end of the travel switch 3.3.5, the power-off alarm gives an alarm after the power-off of the steel belt motor 3.2.9 to remind an operator to take off the bobbin, and the connection relationship between the steel belt motor 3.2.9, the travel switch 3.3.5 and the power-off alarm is the prior art which is well known and can be implemented by those skilled in the art, and is not described herein again.

In practical use, the guide rail assembly is fixed on two sides of a middle wall plate of a spinning machine through an external support, the tail tensioning plate 3.2.2 and the tail base plate 3.2.1 are not in a fixed state before the conveying mechanism does not run, the head tensioning plate 3.1.2 is fixed after the position is determined, the tail is abutted to the tail tensioning plate 3.2.2 through adjusting a screw rod on the tensioning block 3.2.4 to finely adjust the position of the tensioning plate 3.2.2, so that after the tightness of the steel belt 3.4.1 meets the requirement, the tail tensioning plate 3.2.2 is fixed to the tail base plate 3.2.1, the steel belt motor 3.2.9 is started, the steel belt motor 3.2.9 drives and drives the steel belt driving wheel 3.2.7 through the synchronous belt driving wheel 3.2.12, the synchronous belt driven wheel 3.2.13 and the synchronous belt 3.2.14, the steel belt driving wheel 3.2.7 drives the steel belt 3.4.1, and the steel belt 3.4.1 runs in a counterclockwise direction.

In practical use, two magnetic switches are arranged at the steel strip photoelectric bracket 3.2.10 at the tail of the vehicle so as to position the steel strip 3.4.1.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (9)

1. The utility model provides a perpendicular steel band formula conveying mechanism which characterized in that: the automobile tail tensioning device comprises a head tensioning device (3.1), a tail tensioning device (3.2), two guide rail assemblies and a steel belt assembly, wherein the head tensioning device (3.1) and the tail tensioning device (3.2) are correspondingly arranged, the two guide rail assemblies are symmetrically arranged, one ends of the two guide rail assemblies are respectively positioned at two sides of the head tensioning device (3.1), the other ends of the two guide rail assemblies are respectively positioned at two sides of the top end surface of the tail tensioning device (3.2), and the two guide rail assemblies are formed by connecting a plurality of guide rail parts (3.3); the headstock tensioning device (3.1), the tailstock tensioning device (3.2) and the two guide rail assemblies form an annular loop; the steel belt assembly is arranged in the annular loop in a surrounding mode, and the tail tensioning device (3.2) is used for driving the steel belt assembly to rotate in the annular loop.

2. The vertical steel belt conveying mechanism according to claim 1, wherein the head tensioning mechanism (3.1) comprises a head base plate (3.1.1), a head tensioning plate (3.1.2) is arranged on the top of the head base plate (3.1.1), a first steel belt wheel shaft (3.1.4) is arranged on each of two sides of the top of the head tensioning plate (3.1.2), a first steel belt wheel (3.1.3) is arranged on each of the tops of the first steel belt wheels (3.1.4), a head guide rail support (3.1.6) is arranged on the rear end face of the head tensioning plate (3.1.2) between the two steel belt wheels (3.1.3), and a head guide rail (3.1.7) for a steel belt assembly to pass through is arranged on the rear end face of the top of the head guide rail support (3.1.6).

3. A vertical steel belt conveyor according to claim 2, characterized in that the side of the two steel pulleys (3.1.3) adjacent to each other is provided with a steel pulley shield (3.1.5).

4. The vertical steel belt conveyor mechanism according to claim 2, wherein the tailstock tensioning device (3.2) comprises a tailstock bottom plate (3.2.1), a tailstock tensioning plate (3.2.2) is arranged on the front end face of the top of the tailstock bottom plate (3.2.1), two cushion blocks (3.2.5) are respectively arranged on two sides of the top of the tailstock tensioning plate (3.2.2), a motor mounting plate (3.2.3) is horizontally arranged on the top of the cushion block (3.2.5), two cushion blocks (3.2.5) corresponding to the rear end of the tailstock tensioning plate (3.2.2) are respectively arranged on the tailstock bottom plate (3.2.1) at the rear end of the tailstock tensioning plate (3.2.2) and provided with tensioning blocks (3.2.4), threaded rods are respectively screwed on the blocks of the tensioning blocks (3.2.4), and one end of each threaded rod abuts against the corresponding tailstock tensioning block (3.2.5); two steel belt wheel shafts II (3.2.6) are correspondingly arranged on two sides of the top of the tail tensioning plate (3.2.2), the tops of the two steel belt wheel shafts II (3.2.6) are respectively inserted through the motor mounting plates (3.2.3), a steel belt driving wheel (3.2.7) is arranged at the top of the steel belt wheel shaft II (3.2.6) on the left side of the tail tensioning plate (3.2.2) and above the motor mounting plates (3.2.3), and a steel belt driven wheel (3.2.8) is arranged at the top of the steel belt wheel shaft II (3.2.6) on the right side of the tail tensioning plate (3.2.2) and above the motor mounting plates (3.2.3); a steel belt motor (3.2.9) is installed at the rear end of a motor installation plate (3.2.3) between a steel belt driving wheel (3.2.7) and a steel belt driven wheel (3.2.8), an execution shaft of the steel belt motor (3.2.9) is vertically arranged downwards and extends to the lower part of the motor installation plate (3.2.3), a synchronous belt driving wheel (3.2.12) is arranged at the tail end of the execution shaft of the steel belt motor (3.2.9), a synchronous belt driven wheel (3.2.13) is arranged on a steel belt pulley shaft II (3.2.6) with the top provided with the steel belt driving wheel (3.2.7) and corresponds to the synchronous belt driving wheel (3.2.12), and a synchronous belt (3.2.14) is arranged around the outer parts of the synchronous belt driving wheel (3.2.12) and the synchronous belt driven wheel (3.2.13); the front end of a motor mounting plate (3.2.3) between the steel belt driving wheel (3.2.7) and the steel belt driven wheel (3.2.8) is provided with a tail guide rail (3.2.11) for the steel belt assembly to pass through.

5. The vertical steel belt conveyor according to claim 4, wherein the steel belt assembly comprises a steel belt (3.4.1) and a plurality of steel belt convex disc components (3.4) arranged on the steel belt (3.4.1), the steel belt convex disc components (3.4) comprise a double ingot convex disc (3.4.2) and a second pressing plate (3.4.3), the double ingot convex disc (3.4.2) is arranged on the top of the steel belt (3.4.1), and the second pressing plate (3.4.3) is symmetrically arranged on two sides of the steel belt (3.4.1) and is positioned right below the double ingot convex disc (3.4.2); the steel band (3.4.1) encircles and sets up in the periphery of two steel band wheels (3.1.3), hold-in range action wheel (3.2.12) and hold-in range follower (3.2.13), is formed with the draw-in groove that supplies the inboard clamp plate two (3.4.3) of steel band (3.4.1) to rotate the joint respectively on two steel band wheels (3.1.3), hold-in range action wheel (3.2.12) and hold-in range follower (3.2.13).

6. The vertical steel belt conveying mechanism according to claim 5, wherein the guide rail part (3.3) comprises a groove-shaped guide rail (3.3.1), support plates (3.3.6) are symmetrically arranged on two side walls inside a groove body of the groove-shaped guide rail (3.3.1), the support plates (3.3.6) are also arranged on two side walls inside the groove body of the headstock guide rail (3.1.7) and the tailstock guide rail (3.2.11), first pressing plates (3.3.2) are symmetrically arranged on two sides of the guide rail (3.3.1), the bottom of the double-ingot convex disc (3.4.2) is positioned on the two side support plates (3.3.6), two sides of the top of the double-ingot convex disc (3.4.2) are pressed below the first pressing plate (3.3.2), and the second pressing plates (3.4.3) on two sides of the steel belt (3.4.1) and the two pressing plates (3.4.3.3) on two sides of the steel belt (3.4.1) are clamped in the guide rail (3.3.1) between the two support plates (3.6) and rotate in the guide rail (3.2.9).

7. The vertical steel belt conveyor according to claim 6, wherein two yarn shoveling devices (3.3.3) are symmetrically arranged on both sides of the guide rail (3.3.1) of one of the guide rail components (3.3) of the left guide rail assembly, a bracket (3.3.4) is arranged on the top of the yarn shoveling device (3.3.3) inside the guide rail (3.3.1), a travel switch (3.3.5) is arranged on the bracket (3.3.4), the actuating end of the travel switch (3.3.5) is arranged towards the guide rail (3.3.1), and the travel switch (3.3.5) is electrically connected with the steel belt motor (3.2.9).

8. A vertical steel belt conveyor according to claim 4 wherein a cam positioning electro-optical support (3.2.10) is also mounted at the front end of the motor mounting plate (3.2.3) between the steel belt drive wheel (3.2.7) and the steel belt driven wheel (3.2.8).

9. The vertical steel belt conveyor according to claim 6 wherein the steel belt motor (3.2.9) is further externally connected with a power-off alarm.

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