CN220448818U - Mechanism layout of power system and environment-friendly equipment with mechanism layout - Google Patents

Abstract

The utility model discloses a mechanism layout of a power system and environmental protection equipment with the mechanism layout, wherein a plurality of stepping plates are slidably connected in a fixed bottom frame along the length direction, all the stepping plates are divided into a plurality of stepping units, and the stepping plates of the stepping units are arranged at intervals; each stepping unit is provided with a backward driving part, and the backward driving part simultaneously drives the stepping plates in the group of stepping units to simultaneously move towards the tail end of the fixed bottom frame; the device also comprises an advancing driving part, and the advancing driving part simultaneously drives all stepping plates in the fixed bottom frame to move towards the head end of the fixed bottom frame. The mechanism layout of the power system can effectively utilize the stepping driving principle to drive the materials accommodated above the power system in a moving way; different stepping units are formed by grouping, so that the driving efficiency is effectively improved; the driving of the stepping plate is divided into forward driving and backward driving, and the thrust can be effectively and sequentially applied from the two ends of the stepping plate, so that the stepping plate can be more efficiently pushed and moved.

Description

Mechanism layout of power system and environment-friendly equipment with mechanism layout

Technical Field

The utility model relates to the field of environmental protection equipment, in particular to a mechanism layout of a power system and environmental protection equipment with the mechanism layout.

Background

There is a stepping conveying device, as shown in fig. 1 and 2, which has 9 stepping plates in total, and each stepping plate needs an oil cylinder to provide power for advancing and retreating. The existing equipment needs 9 oil cylinders in total. The action program comprises the following steps: 9 oil cylinders advance simultaneously to push the stepping plate to advance simultaneously, the stepping plate is pushed to a specified position, then the oil cylinders retract sequentially, and the stepping plate is retracted sequentially, so that the advancing of materials is realized. 9 oil cylinders are needed in the prior art, and the manufacturing cost is high; 9 oil cylinders are sequentially retreated, so that the efficiency is low; the 9 independent oil cylinders need to independently retreat and synchronously advance together, and the control technology requirement is high. As shown in fig. 2, since each stepper plate has a longer length and slides along the length direction under the condition of load weight, in the prior art, each stepper plate is correspondingly driven by an oil cylinder, the driving position of the stepper plate cannot be changed, and as shown in fig. 2, the oil cylinder is arranged close to the left side, so when the oil cylinder drives the stepper plate leftwards, the force point is driven close to the left end of the stepper plate, namely, the force point is driven to the head end, and the stepper plate is easier to pull the stepper plate to slide leftwards; on the contrary, when moving rightwards, the force point is far away from the right end, and the force point belongs to end driving pushing, so that pushing is difficult when pushing rightwards.

In view of the above, it is necessary to provide a mechanism layout of a power system and an environmental protection device having the same to solve the above problems.

Disclosure of Invention

The utility model aims to solve the technical problems and provide a mechanism layout of a power system and environment-friendly equipment with the mechanism layout.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the mechanism layout of the power system comprises a fixed bottom frame, wherein a plurality of stepping plates are arranged in the fixed bottom frame in a sliding connection manner along the length direction, and the mechanism layout is characterized in that all the stepping plates are divided into a plurality of stepping units which are alternately driven; each stepping unit is provided with a backward driving part and further comprises a forward driving part for driving all stepping plates to move in the forward direction.

Further, each step unit consists of a plurality of step plates, and the step plates of one step unit are uniformly arranged at intervals to form a plurality of step plates of other step units; the application point of the backward driving part to the stepping plate is close to the tail end of the stepping plate, and the backward driving part simultaneously drives the stepping plates in the group of stepping units to simultaneously move towards the tail end of the fixed bottom frame; the application point of the forward driving part to the stepping plate is close to the head end of the stepping plate, and the forward driving part simultaneously drives all the stepping plates in the fixed bottom frame to move towards the head end of the fixed bottom frame.

Further, nine stepping plates are arranged in the fixed bottom frame, and the fixed bottom frame is sequentially provided with a first stepping plate, a second stepping plate, a third stepping plate, a fourth stepping plate, a fifth stepping plate, a sixth stepping plate, a seventh stepping plate, an eighth stepping plate and a ninth stepping plate.

Further, the nine stepping plates are divided into three groups of stepping units, namely a first unit, a second unit and a third unit, and each stepping unit is provided with three stepping plates;

the first unit comprises a first stepping plate, a fourth stepping plate and a seventh stepping plate;

the second unit comprises a second stepping plate, a fifth stepping plate and an eighth stepping plate;

the third unit comprises a third stepping plate, a sixth stepping plate and a ninth stepping plate.

Further, a plurality of cross beams are arranged in the fixed bottom frame and perpendicular to the length direction of the stepping plate, and the cross beams are used as mounting beams at one end of the oil cylinder.

Further, the advance drive part includes forward beam, advance hydro-cylinder, advance guide rail, advance dog, advance beam sliding connection and arrange in advance in the guide rail, every advance the dog that all is fixed to be equipped with on the step plate to advance the dog and be located forward beam and be close to head end one side, advance hydro-cylinder one end and advance beam hinge, the other end and crossbeam hinge, advance hydro-cylinder and advance the dog and divide into the both sides that are located forward beam.

Further, the back drive portion includes back roof beam, back hydro-cylinder, back guide rail, fixture block, the fixture block is equipped with two on every stepper plate to two fixture blocks are the centre gripping and set up in back roof beam both sides, back roof beam both ends sliding connection sets up in the back guide rail, back hydro-cylinder one end is connected with the crossbeam is articulated, and the other end is connected with back roof beam is articulated.

Furthermore, the advancing guide rail and the retreating guide rail are fixedly arranged on two sides of the fixed bottom frame, and the direction of the advancing guide rail and the retreating guide rail is the same as the length direction of the stepping plate.

Furthermore, the inside hollow structure that is of step plate, step plate up end are equipped with a plurality of rake teeth along length direction interval uniformly, and the rake teeth is the facade towards the head end, and the rake teeth is the gentle inclined plane of slope towards the tail end, the venthole has been seted up on the facade.

An environmental protection device comprises a bottom plate structure which is formed by the mechanism layout of the power system and is used for driving materials to move from the tail end to the head end.

Compared with the prior art, the utility model has the beneficial effects that: the mechanism layout of the power system can effectively utilize the stepping driving principle to drive the materials accommodated above the power system in a moving way; different stepping units are formed by grouping, so that the driving efficiency is effectively improved; the driving of the stepping plate is divided into forward driving and backward driving, and thrust can be effectively applied from the two ends of the stepping plate, so that the stepping plate can be pushed and moved more easily.

Drawings

FIG. 1 is a perspective view of a stepped powertrain layout structure of the prior art;

FIG. 2 is a bottom view of a stepped powertrain layout configuration of the prior art;

FIG. 3 is a bottom view of a mechanism layout of a power system of the present application and environmental protection equipment having the same;

FIG. 4 is a side view of a mechanism layout of a power system of the present application and environmental protection equipment having the same;

FIG. 5 is a diagram of the internal structure of the stepper plate of the present application;

in the figure: 1. fixing the bottom frame; 2. a step plate; 3. a step unit; 4. a backward driving part; 5. a forward driving section; 6. a first stepper plate; 7. a second stepper plate; 8. a third stepper plate; 9. a fourth stepper plate; 10. a fifth stepper plate; 11. a sixth stepper plate; 12. a seventh stepper plate; 13. an eighth stepper plate; 14. a ninth step plate; 15. a first unit; 16. a second unit; 17. a third unit; 18. a cross beam; 19. a forward beam; 20. advancing an oil cylinder; 22. advancing the guide rail; 23. a forward stop; 24. a back beam; 25. a back-off oil cylinder; 26. a back guide rail; 27. a clamping block; 28. rake teeth; 29. elevation; 30. an inclined plane; 31. and an air outlet hole.

Detailed Description

The technical solutions of the present utility model will be clearly and completely described in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments.

The utility model provides a mechanism layout of driving system and have its environmental protection equipment, as shown in fig. 3, fig. 4, including fixed underframe 1, along length direction sliding connection in the fixed underframe 1 be equipped with a plurality of step plates 2, be equipped with many crossbeams 18 in the fixed underframe 1 perpendicular to step plate 2 length direction. The stepping plates 2 slide in the fixed bottom frame 1 along the length direction, the stepping plates 2 are mutually spliced and matched in the width direction to form a sealed bottom plate, the upper part of the bottom plate is used for containing materials to be conveyed, the materials are conveyed by the stepping movement of the stepping plates 2, all the stepping plates 2 are divided into a plurality of stepping units 3, each stepping unit 3 consists of a plurality of stepping plates 2, and a plurality of stepping plates 2 forming other stepping units 3 are arranged at uniform intervals between the stepping plates 2 of one stepping unit 3.

Specifically, as shown in fig. 4, nine stepping plates 2 are disposed in the fixed bottom frame 1, and are a first stepping plate 6, a second stepping plate 7, a third stepping plate 8, a fourth stepping plate 9, a fifth stepping plate 10, a sixth stepping plate 11, a seventh stepping plate 12, an eighth stepping plate 13, and a ninth stepping plate 14 in sequence. The edges of each stepping plate 2 are mutually overlapped to form a structure capable of mutually sliding and moving, and nine stepping plates 2 are divided into three groups;

specifically, the nine stepping plates 2 are divided into three groups of stepping units 3, namely a first unit 15, a second unit 16 and a third unit 17 in sequence, and each stepping unit 3 is provided with three stepping plates 2;

the first unit 15 comprises a first stepping plate 6, a fourth stepping plate 9 and a seventh stepping plate 12;

the second unit 16 comprises a second stepping plate 7, a fifth stepping plate 10 and an eighth stepping plate 13;

the third unit 17 includes a third stepping plate 8, a sixth stepping plate 11, and a ninth stepping plate 14.

As shown in fig. 2, two stepping plates 2 are arranged between the first stepping plate 6 and the fourth stepping plate 9 at intervals, the two stepping plates are a second stepping plate 7 and a third stepping plate 8, the second stepping plate 7 is a stepping plate 2 of a second unit 16, and the third stepping plate 8 is a stepping plate 2 of a third unit 17; as shown in the above arrangement principle, the two stepping plates 2 of each group can be sequentially divided into three groups, and the stepping plates 2 of other stepping units 3 are arranged between the two adjacent stepping plates 2 of each group at intervals, so that a staggered format is formed.

The forward driving part 5 is used when driving the stepping plates 2 to move forward, namely all the stepping plates 2 are moved to the head end by the forward driving part 5 when moving forward, the application point of the forward driving part 5 to the stepping plates 2 is close to the head end of the stepping plates 2, and the forward driving part 5 simultaneously drives all the stepping plates 2 in the fixed bottom frame 1 to move to the head end of the fixed bottom frame 1. Since the point of application of force to the stepper plate 2 is close to the head end of the stepper plate 2, the point of application of force can easily pull the stepper plate 2 to move toward the head end.

Specifically, the forward driving part 5 includes a forward beam 19, a forward oil cylinder 20, a forward guide rail 22, and a forward stop block 23, where the forward beam 19 is slidably connected in the forward guide rail 22, so that the forward beam 19 can slide reciprocally in the forward guide rail 22 in a direction indicated by a dashed arrow in the figure, each of the stepping plates 2 is fixedly provided with the forward stop block 23, and the forward stop block 23 is located on one side of the forward beam 19 near the head end, one end of the forward oil cylinder 20 is hinged to the forward beam 19, the other end is hinged to the cross beam 18, and the forward oil cylinder 20 and the forward stop block 23 are separated into two sides located on the forward beam 19. As shown in fig. 3, the front oil cylinders 20 are two groups, one ends of the front oil cylinders are fixed on the cross beam 18, the cross beam 18 is used as a mounting beam of one end of an oil cylinder, the other end of the cross beam is simultaneously hinged on the front beam 19, the two front oil cylinders 20 are arranged at a certain distance, the front beam 19 can be uniformly pushed to move forwards, the front stop block 23 is welded on each stepping plate 2, and the action sequence is as follows: the forward cylinder 20 stretches to push the forward beam 19 to move towards the head end, the front end of the forward beam 19 is clamped on the forward stop block 23 of each stepping plate 2, and all the stepping plates 2 are pushed to advance, so that forward movement of materials is realized. It will be appreciated that, due to the longer length of the device, other beams for strengthening only the structural strength are provided along the length of the bottom of the fixed frame, and the overall structure of these beams for strengthening only is similar to that of the beam 18 for providing the cylinder, and other beams not provided with the cylinder are not shown in fig. 3.

Further, each step unit 3 has a back driving part 4, the application point of the back driving part 4 to the step plate 2 is close to the tail end of the step plate 2, and the back driving part 4 drives the step plates 2 in the group of step units 3 to move towards the tail end of the fixed bottom frame 1 at the same time; similar to the forward driving section 5, the backward driving section 4 drives the point of application of the stepping plate 2 to the trailing end, so that the stepping plate 2 can be pulled to move to the trailing end at the trailing end of the stepping plate 2.

Specifically, the back driving part 4 includes a back beam 24, a back cylinder 25, a back guide rail 26, and a clamping block 27, where two clamping blocks 27 are provided on each stepping plate 2, and the two clamping blocks 27 are clamped on two sides of the back beam 24, two ends of the back beam 24 are slidably connected and disposed in the back guide rail 26, one end of the back cylinder 25 is hinged to the cross beam 18, and the other end is hinged to the back beam 24. As shown in fig. 3, a set of backward driving parts 4 are provided in each of the first unit 15, the second unit 16, and the third unit 17, so that the corresponding stepping plate 2 in each unit can be driven to move to the tail simultaneously by the corresponding backward driving part 4.

Taking the first unit 15 as an example, specifically, the first stepping plate 6, the fourth stepping plate 9 and the seventh stepping plate 12 form the first unit 15, the clamping blocks 27 arranged on the stepping plate 2 are two clamping blocks 27 welded on two sides of the back beam 24, so that the clamping blocks 27 limit the back beam 24, two ends of the back beam 24 are arranged in the back guide rail 26, the back beam 24 can reciprocate in the direction of a dotted line as shown in fig. 3, the moving power is that two back oil cylinders 25 are driven, specifically, one ends of the two back oil cylinders 25 are hinged with the back beam 24, and the other ends of the two back oil cylinders are hinged with the cross beam 18. The forward guide rail 22 and the backward guide rail 26 are fixedly arranged at two sides of the fixed bottom frame 1, and the directions of the forward guide rail and the backward guide rail are the same as the length direction of the stepping plate 2. The action sequence is as follows: the backward cylinder 25 stretches to push the backward beam 24 to move rightwards, and the backward beam 24 correspondingly pushes the first stepping plate 6, the fourth stepping plate 9 and the seventh stepping plate 12 to move rightwards through the clamping blocks 27 on two sides, so that the stepping plate 2 corresponding to the stepping unit 3 is pushed to retreat.

As a further embodiment of the structure of the step plate 2, as shown in fig. 5, the inside of the step plate 2 is a hollow structure, a plurality of rake teeth 28 are uniformly spaced in the extending direction of the upper end surface of the step plate 2, the rake teeth 28 are vertical surfaces 29 towards the head end, the rake teeth 28 are inclined surfaces 30 with gentle slopes towards the tail end, and air outlet holes 31 are formed in the vertical surfaces 29. When the device is used for fermenting materials, the ventilation is needed inside, so that the oxygen content of the material fermentation is conveniently maintained, and air is introduced into a hollow structure in the figure to circulate the air inside, so that the good fermentation of the materials is maintained, and in order to improve the pushing efficiency of the stepping plate 2 to the materials in the moving process, the rake teeth 28 are uniformly distributed on the upper plane which is smooth originally in the length direction, and it is understood that when the stepping plate 2 moves towards the head end, the vertical face 29 faces towards the head end, so that the vertical face 29 can be clamped at the bottom of the materials, the friction force between the materials and the stepping plate 2 is increased, and the conveying efficiency of the materials is further improved; on the contrary, as the stepping plate 2 is driven to retreat in a grouping way, the material contacts with the gentle inclined surface 30 at the bottom during retreating, so that relative sliding is convenient to generate, and the phenomenon that the material is conveyed and returned is effectively avoided; and the air outlet hole 31 is arranged on the inner side, so that compressed air can be effectively sent into the equipment.

An environmental protection device comprises a bottom plate structure which is formed by the mechanism layout of the power system and is used for driving materials to move from the tail end to the head end.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (10)

1. The mechanism layout of the power system comprises a fixed bottom frame (1), wherein a plurality of stepping plates (2) are arranged in the fixed bottom frame (1) in a sliding connection manner along the length direction, and the mechanism layout is characterized in that all the stepping plates (2) are divided into a plurality of stepping units (3), and the stepping units (3) are driven alternately; each step unit (3) has a backward drive section (4), and further includes a forward drive section (5) that drives all the step plates to move in the forward direction.

2. A mechanism layout of a power system according to claim 1, characterized in that each step unit (3) is composed of a plurality of step plates (2), and that the step plates (2) of a certain step unit (3) are provided with a plurality of step plates (2) composing other step units (3) at uniform intervals; the application point of the backward driving part (4) to the stepping plate (2) is close to the tail end of the stepping plate (2), and the backward driving part (4) drives the stepping plates (2) in the group of stepping units (3) to move towards the tail end of the fixed bottom frame (1) at the same time; the application point of the advancing driving part (5) to the stepping plate (2) is close to the head end of the stepping plate (2), and the advancing driving part (5) simultaneously drives all the stepping plates (2) in the fixed bottom frame (1) to move towards the head end of the fixed bottom frame (1).

3. The mechanism layout of the power system according to claim 2, wherein nine stepping plates (2) are arranged in the fixed bottom frame (1), and the nine stepping plates are sequentially a first stepping plate (6), a second stepping plate (7), a third stepping plate (8), a fourth stepping plate (9), a fifth stepping plate (10), a sixth stepping plate (11), a seventh stepping plate (12), an eighth stepping plate (13) and a ninth stepping plate (14).

4. A mechanism layout of a power system according to claim 3, characterized in that nine of the stepping plates (2) are divided into three groups of stepping units (3), a first unit (15), a second unit (16), a third unit (17) in sequence, each stepping unit (3) being provided with three stepping plates (2);

the first unit (15) comprises a first stepping plate (6), a fourth stepping plate (9) and a seventh stepping plate (12);

the second unit (16) comprises a second stepping plate (7), a fifth stepping plate (10) and an eighth stepping plate (13);

the third unit (17) comprises a third stepping plate (8), a sixth stepping plate (11) and a ninth stepping plate (14).

5. The mechanism layout of a power system according to claim 4, wherein a plurality of cross beams (18) are arranged in the fixed bottom frame (1) perpendicular to the length direction of the stepping plate (2), and the cross beams (18) serve as mounting beams at one end of the oil cylinder.

6. The mechanism layout of a power system according to claim 5, wherein the forward driving part (5) comprises a forward beam (19), a forward oil cylinder (20), a forward guide rail (22) and a forward stop block (23), the forward beam (19) is slidably connected in the forward guide rail (22), the forward stop block (23) is fixedly arranged on each stepping plate (2), the forward stop block (23) is positioned on one side of the forward beam (19) close to the head end, one end of the forward oil cylinder (20) is hinged with the forward beam (19), the other end of the forward oil cylinder is hinged with the cross beam (18), and the forward oil cylinder (20) and the forward stop block (23) are respectively positioned on two sides of the forward beam (19).

7. The mechanism layout of a power system according to claim 6, wherein the back driving part (4) comprises a back beam (24), a back cylinder (25), a back guide rail (26) and clamping blocks (27), two clamping blocks (27) are arranged on each stepping plate (2), the two clamping blocks (27) are clamped on two sides of the back beam (24), two ends of the back beam (24) are slidably connected and arranged in the back guide rail (26), one end of the back cylinder (25) is hinged with the cross beam (18), and the other end of the back cylinder is hinged with the back beam (24).

8. The mechanism layout of the power system according to claim 7, wherein the forward guide rail (22) and the backward guide rail (26) are fixedly arranged at two sides of the fixed bottom frame (1) and have the same direction as the length direction of the stepping plate (2).

9. The mechanism layout of the power system according to claim 1, wherein the inside of the stepping plate (2) is of a hollow structure, a plurality of rake teeth (28) are uniformly arranged on the upper end face of the stepping plate (2) at intervals along the length direction, the rake teeth (28) face a vertical face (29) towards the head end, the rake teeth (28) face a slope (30) with gentle slope towards the tail end, and air outlets (31) are formed in the vertical face (29).

10. An environmental protection equipment, characterized in that the equipment comprises a bottom plate structure which is formed by the mechanism layout of the power system of any one of claims 1-8 and is used for driving materials to move from a tail end to a head end.