CN219217867U - Automatic driving type anti-slip power system of pile turning machine - Google Patents

Abstract

The utility model relates to an anti-striking sliding force system of an automatic traveling type pile turning machine, and belongs to the technical field of pile turning machines. The technical scheme is that the bidirectional impeller mainly aims at the problem that an impeller which is arranged in the existing product in a bidirectional way is easy to stop running due to dislocation and slipping of a loaded half shaft, and the bidirectional impeller comprises an electric sliding rail, a sliding part is connected to the electric sliding rail in a sliding mode, a lifting structure is arranged at the bottom of the sliding part, a material turning structure for turning materials is arranged at the bottom end of the lifting structure, and the material turning structure consists of a loading shell, a driving mechanism, the half shaft and the impeller. According to the utility model, the driving mechanism consisting of the double transmission structure is used for driving the half shafts provided with the impellers, so that the synchronous transmission of the half shafts can still be realized under the condition that the half shafts are dislocated, the phenomenon that the local impellers stop running is avoided, the running efficiency of equipment is ensured, and the practical effect of the equipment is enhanced.

Description

Automatic driving type anti-slip power system of pile turning machine

Technical Field

The utility model relates to the technical field of pile turning machines, in particular to an anti-slip force system of an automatic traveling pile turning machine.

Background

The pile turning machine is commonly used equipment in a strip pile type or bin type fermentation treatment process. The method is widely applied to fermentation decomposition and water removal operations of organic fertilizer factories, compound fertilizer factories, sludge garbage yards, gardening yards, agaricus bisporus planting yards and the like, and can be used for regularly stirring and crushing piled long strip-shaped materials and decomposing organic matters under aerobic conditions.

The turning machine is classified into several types according to the moving modes thereof, and an automatic traveling type is one of them. At present, in a driving structure adopted by a traditional pile turning machine when driving an impeller thereof, only a simple bevel gear set drives half shafts arranged on two sides to enable the impeller arranged on the half shafts to move, but with long-term operation of equipment, the phenomenon that the half shafts are dislocated in the moving process is generated, so that detachment and slipping are generated between the bevel gear sets, and the phenomenon that local impellers of the bevel gear set stop operating is generated, so that the operation efficiency of the equipment is influenced.

Therefore, how to process the pile turning machine is a technical problem that needs to be solved currently by those skilled in the art.

Disclosure of Invention

The utility model aims to solve the problems in the background technology and provides an anti-slip force system of an automatic traveling type pile turning machine.

The technical scheme of the utility model is as follows: the utility model provides an automatic driving type pile turning machine prevents beating sliding force system, includes electronic slide rail, sliding connection has the slider on the electronic slide rail, and elevation structure is installed to the bottom of slider, and elevation structure's bottom is provided with the stirring structure that is used for turning the material, stirring structure comprises loading shell, actuating mechanism, semi-axis and impeller, and wherein, semi-axis and impeller all include two, loading shell includes the casing that passes through bolted connection on elevation structure, and the front of casing passes through the screw connection and has the apron;

the driving mechanism comprises a double-shaft motor, driving bevel gears are arranged at the output ends of two sides of the double-shaft motor, driven bevel gears are arranged at two sides of the driving bevel gears, telescopic rods are arranged on the driven bevel gears, a plurality of driven bevel gears are arranged below the driven bevel gears and are respectively arranged on corresponding half shafts, the telescopic rods and the half shafts are in one-to-one correspondence, connecting plates and toothed chain assemblies are connected, and guide rods are movably connected to the connecting plates.

Preferably, extension pipes are arranged on the shell walls on two sides of the shell, a plurality of half shafts are respectively arranged in the corresponding extension pipes, and the impeller is arranged at the outer ends of the half shafts.

Preferably, the back of biax motor installs the connecting seat, and the back of connecting seat sets up on the back inner wall of casing.

Preferably, a plurality of telescopic rods are provided with support plates, and the back surfaces of the support plates are also arranged on the inner wall of the back surface of the shell.

Preferably, each toothed chain assembly comprises two gears, the two gears are respectively arranged on the corresponding telescopic rod and the corresponding half shaft, and the two gears are connected through a chain.

Preferably, the middle part of the connecting plate is provided with a hole, the guide rod is sleeved in the hole, and one end of the guide rod is fixedly connected to the inner wall of the side edge of the shell.

Preferably, the guide rod is sleeved with a spring, one end of the spring is arranged on the connecting plate, and the other end of the spring is arranged on the inner wall of the side edge of the shell.

Compared with the prior art, the utility model has the following beneficial technical effects:

the driving mechanism composed of the double transmission structure drives the half shafts assembled with the impellers, and further under the condition that the half shafts are dislocated, synchronous transmission of the half shafts can still be achieved, the phenomenon that the local impellers stop running is avoided, the running efficiency of the equipment is guaranteed, and the practical effect of the equipment is enhanced.

Drawings

FIG. 1 is a schematic view of a partial perspective view of an embodiment of the present utility model;

FIG. 2 is a schematic diagram of the axial side view of FIG. 1;

fig. 3 is an enlarged schematic view of a partial structure at a of fig. 1.

Reference numerals: 1. an electric slide rail; 2. a slider; 3. a lifting structure; 4. loading a shell; 41. a housing; 42. a cover plate; 5. a driving mechanism; 51. a biaxial motor; 52. a drive bevel gear; 53. a driven bevel gear; 54. a telescopic rod; 55. a connecting plate; 56. a toothed chain assembly; 57. a guide rod; 6. a half shaft; 7. an impeller.

Detailed Description

The technical scheme of the utility model is further described below with reference to the attached drawings and specific embodiments.

Example 1

As shown in fig. 2-3, the anti-slip force system of the automatic traveling type pile turning machine provided by the utility model comprises an electric sliding rail 1, wherein a sliding piece 2 is connected to the electric sliding rail 1 in a sliding manner. The lifting structure 3 is installed to the bottom of slider 2, and the bottom of lifting structure 3 is provided with the stirring structure that is used for stirring the material. The material turning structure is composed of a loading shell 4, a driving mechanism 5, a half shaft 6 and an impeller 7. Wherein, the half shaft 6 and the impeller 7 comprise two. The loading housing 4 includes a housing 41 coupled to the elevating structure 3 by bolts, and a cover plate 42 is coupled to the front surface of the housing 41 by screws.

The driving mechanism 5 comprises a double-shaft motor 51, and drive bevel gears 52 are arranged at the output ends of two sides of the double-shaft motor 51. Driven bevel gears 53 are provided on both sides of the drive bevel gear 52. The driven bevel gears 53 are each provided with a telescopic rod 54. A plurality of driven bevel gears 53 are provided on the corresponding half shafts 6, respectively. The telescopic rods 54 are in one-to-one correspondence with the half shafts 6, and are connected with connecting plates 55 and toothed chain assemblies 56, and each connecting plate 55 is movably connected with a guide rod 57.

In this embodiment, the output ends of two sides of the double-shaft motor 51 are both provided with a rotating shaft, and one ends of the rotating shaft, which are far away from the double-shaft motor 51, are respectively connected to the corresponding drive bevel gears 52.

The working principle of the anti-slip power system of the automatic traveling type pile turning machine based on the first embodiment is as follows: when the device is operated, the double-shaft motor 51 in the driving mechanism 5 is operated, and then the driving bevel gear 52 which is arranged in a bidirectional manner is driven to synchronously move. The driving bevel gear 52 and the driven bevel gear 53 are meshed for transmission, so that the driving bevel gear drives the telescopic rod 54 and the half shaft 6 to synchronously rotate. The motion of the half shaft 6 enables the impeller 7 arranged on the half shaft to move, so that the overturning of materials is realized. And a connecting plate 55 and a toothed chain component 56 are connected between the telescopic rod 54 and the half shaft 6. And the telescopic rod 54 and the half shaft 6 synchronously move, so that the arrangement of the connecting plate 55 and the toothed chain component 56 does not cause obstruction to the operation of the half shaft 6. If the dislocation of the half shaft 6 occurs, the extension rod 54 is stretched and adjusted through the connecting plate 56 during the moving process. The telescopic link 54 is provided with the connecting plate 56, so that the stretching adjustment distance of the telescopic link is consistent with the dislocation distance of the half shafts 6, and the toothed chain assembly 56 can still realize synchronous operation of the plurality of half shafts 6, and the phenomenon that the impeller 7 stirring partially stops operating due to slipping of the toothed chain assembly is avoided.

Example two

As shown in fig. 1-2, based on the first embodiment, this embodiment further includes: extension pipes are arranged on the two side walls of the shell 41, a plurality of half shafts 6 are respectively arranged in the corresponding extension pipes, and impellers 7 are arranged at the outer ends of the half shafts 6. The rear surface of the biaxial motor 51 is provided with a connection seat, and the rear surface of the connection seat is provided on the rear inner wall of the housing 41. The plurality of telescopic rods 54 are respectively provided with a support plate, and the back surfaces of the support plates are also arranged on the inner wall of the back surface of the shell 41.

In this embodiment, a notch is formed in the front wall of the housing 41, and the cover plate 42 is disposed at the notch in a screw connection manner, so that the notch is an access hole for overhauling the driving mechanism 5.

Example III

As shown in fig. 3, based on the first or second embodiment, the present embodiment further includes: each toothed chain assembly 56 comprises two gears which are respectively arranged on the corresponding telescopic rod 54 and the half shaft 6 and are connected through a chain. A hole is formed in the middle of the connecting plate 55, a guide rod 57 is sleeved in the hole, and one end of the guide rod 57 is fixedly connected to the inner wall of the side edge of the shell 41. The guide rod 57 is sleeved with a spring, one end of the spring is arranged on the connecting plate 55, and the other end of the spring is arranged on the inner wall of the side edge of the shell 41.

In this embodiment, the connecting plate 56 is fixed by a detent connection when connecting with the half shaft 6.

In this embodiment, the arrangement of the spring and the guide rod 57 not only plays a role in abutting the half shaft 6, avoiding the phenomenon that the half shaft is separated from slipping, but also can synchronously drive the connecting plate 56 to synchronously displace after the half shaft 6 is separated from slipping, so that the telescopic rod 54 is stretched at equal intervals.

The above-described embodiments are merely a few preferred embodiments of the present utility model, and many alternative modifications and combinations of the above-described embodiments will be apparent to those skilled in the art based on the technical solutions of the present utility model and the related teachings of the above-described embodiments.

Claims (7)

1. The utility model provides an automatic driving type turns over heap machine and prevents beating sliding force system, includes electronic slide rail (1), sliding connection has slider (2) on electronic slide rail (1), and elevation structure (3) are installed to the bottom of slider (2), and the bottom of elevation structure (3) is provided with the stirring structure that is used for turning the material, its characterized in that: the material turning structure is composed of a loading shell (4), a driving mechanism (5), a half shaft (6) and an impeller (7), wherein the half shaft (6) and the impeller (7) are both composed of two parts, the loading shell (4) comprises a shell (41) connected to the lifting structure (3) through bolts, and the front face of the shell (41) is connected with a cover plate (42) through bolts;

the driving mechanism (5) comprises a double-shaft motor (51), wherein driving bevel gears (52) are arranged at the output ends of two sides of the double-shaft motor (51), driven bevel gears (53) are arranged at two sides of the driving bevel gears (52), telescopic rods (54) are arranged on the driven bevel gears (53) in a plurality of upper parts, the driven bevel gears (53) are respectively arranged on corresponding half shafts (6) in a plurality of lower parts, the telescopic rods (54) correspond to the half shafts (6) one by one, connecting plates (55) and toothed chain components (56) are connected, and guide rods (57) are movably connected to the connecting plates (55).

2. The anti-slip force system of the automatic traveling type pile turning machine according to claim 1, wherein the anti-slip force system is characterized in that: extension pipes are arranged on two side shell walls of the shell (41), a plurality of half shafts (6) are respectively arranged in the corresponding extension pipes, and the impeller (7) is arranged at the outer ends of the half shafts (6).

3. The anti-slip force system of the automatic traveling type pile turning machine according to claim 1, wherein the anti-slip force system is characterized in that: the back of biax motor (51) is installed the connecting seat, and the back of connecting seat sets up on the back inner wall of casing (41).

4. The anti-slip force system of the automatic traveling type pile turning machine according to claim 1, wherein the anti-slip force system is characterized in that: and a plurality of telescopic rods (54) are respectively provided with a support plate, and the back surfaces of the support plates are also arranged on the inner wall of the back surface of the shell (41).

5. The anti-slip force system of the automatic traveling type pile turning machine according to claim 1, wherein the anti-slip force system is characterized in that: each toothed chain component (56) comprises two gears which are respectively arranged on the corresponding telescopic rod (54) and the corresponding half shaft (6), and the two gears are connected through a chain.

6. The anti-slip force system of the automatic traveling type pile turning machine according to claim 1, wherein the anti-slip force system is characterized in that: the middle part of the connecting plate (55) is provided with a hole, the guide rod (57) is sleeved in the hole, and one end of the guide rod (57) is fixedly connected to the inner wall of the side edge of the shell (41).

7. The anti-slip force system of the automatic traveling type pile turning machine according to claim 6, wherein the anti-slip force system is characterized in that: the guide rod (57) is sleeved with a spring, one end of the spring is arranged on the connecting plate (55), and the other end of the spring is arranged on the inner wall of the side edge of the shell (41).

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