CN213174975U - Non-delay synchronous rotating device with bevel gear - Google Patents

Abstract

The utility model provides a take bevel gear's no time delay synchronous revolution device, including rectangle fixed frame, bracket assembly, bracket rotary mechanism, be equipped with bracket rotary mechanism on the rectangle fixed frame, rectangle fixed frame lower part is equipped with bracket assembly, bracket rotary mechanism is connected with bracket assembly power, bracket rotary mechanism drives bracket assembly and rotates, the beneficial effects of the utility model reside in that: the structure layout is simple and reasonable, the appearance is attractive and practical, the cost is lower, the mounting and dismounting difficulty is low, and the cost performance is high; the bracket assembly and the bracket rotating mechanism are fixedly connected integrally and are in mechanical transmission, the opening and closing of all brackets are controlled by one motor and are always in a free state, the opening and closing of the whole action are consistent, the uniqueness, consistency and reliability of the opening and closing state are ensured, and the safety of equipment is greatly improved; the volume is less relatively, reduces area, and the installation flexibility is higher, is applicable to more storing land uses.

Description

Non-delay synchronous rotating device with bevel gear

[ technical field ] A method for producing a semiconductor device

The utility model relates to a storage article device especially relates to a take bevel gear's no time delay synchronous revolution device.

[ background of the invention ]

The method for storing the articles by adopting the three-dimensional structure is a method for efficiently utilizing the same occupied space to store large and medium-sized articles, wherein the beneficial effects obtained by using the three-dimensional structure in the field of parking equipment are particularly remarkable, and at least two automobiles can be parked on the occupied space of one parking space by utilizing the three-dimensional structure. The three-dimensional structures of stored articles are various, wherein the three-dimensional structures of mechanical transmission type are widely applied, but the three-dimensional structures of the current mechanical transmission type have the following defects: 1. at present, hanging structures such as cantilevers or lifting ropes or chains are adopted for hanging objects in the upper space of part of three-dimensional structures to suspend in the upper space, the three-dimensional structures largely use anti-falling hooks for preventing the objects from falling, the objects are prevented from falling obliquely when the hanging structures break down, the anti-falling hooks are divided into electromagnetic anti-falling hooks and purely mechanical anti-falling hooks, the electromagnetic anti-falling hooks are controlled by a plurality of groups of driving devices to be opened and closed, the consistency is poor due to various factors such as weather reasons, the failure rate is high, the objects can fall obliquely when serious, and the equipment, personnel and the objects on the lower layer are easily damaged; the opening and closing of the purely mechanical anti-falling hook are always in a free state, fixed control connection is not available, the hook is easily in a failure state due to the fact that animals or people are factors, the working state of the hook is easily changed by external force and is not easy to be perceived, and potential safety hazards are formed; the falling prevention hooks are adopted for protection, each falling prevention hook is controlled to be opened and closed through independent power, the consistency is poor, the opening and the closing are inconsistent due to the fact that one or more falling prevention hooks have problems, articles can incline and fall, and casualties and losses are caused; 2. the upper space of the partial three-dimensional structure is used for bearing and storing articles by adopting a storage plate or a storage rack, when the storage plate or the storage rack with the structure is lifted, a lifting channel of the storage plate or the storage rack needs to be arranged in/out of the three-dimensional structure or the volume of the three-dimensional structure needs to be increased, and the three-dimensional structure has large floor area and higher cost.

[ Utility model ] content

The utility model aims to solve the above-mentioned problem that present mechanical transmission class spatial structure exists, and provide a take bevel gear's no time delay synchronous revolution device.

The utility model discloses a realize through following technical scheme: the utility model provides a take bevel gear's no time delay synchronous revolution device, includes rectangle fixed frame, bracket assembly, bracket rotary mechanism, be equipped with bracket rotary mechanism on the rectangle fixed frame, rectangle fixed frame lower part is equipped with bracket assembly, bracket rotary mechanism and bracket assembly power are connected, bracket rotary mechanism drives bracket assembly and rotates.

Further, the bracket assembly comprises a plurality of bracket, the bracket distributes in rectangle fixed frame lower part, the bracket includes support frame, axis of rotation, bearing, first bevel gear, layer board, the support frame installation is fixed in rectangle fixed frame lower part, be equipped with the axis of rotation in the support frame, the upper and lower both sides of support frame are passed respectively at the axis of rotation both ends, the axis of rotation is equipped with the bearing with the junction of support frame, the one end that the support frame upside was passed to the axis of rotation is equipped with first bevel gear, the axis of rotation is connected with bracket rotary mechanism power through first bevel gear, the one end that the support frame downside was passed to the axis of rotation is equipped with the layer board, the.

Further, the bracket rotating mechanism comprises a motor, a first gear, a second gear, a first transmission shaft, a second bevel gear, a third bevel gear and a fourth bevel gear, the motor is fixedly arranged above one supporting beam of the rectangular fixed frame, the output shaft of the motor is provided with the first gear, the first transmission shaft is arranged between the motor and the supporting beam of the rectangular fixed frame below the motor, the first transmission shaft is provided with the second gear, the second gear is positioned under the first gear, the first gear and the second gear are mutually meshed or are in power connection through a transmission belt, the motor drives the first transmission shaft to rotate through the first gear and the second gear, the two ends of the first transmission shaft are respectively provided with the second gear, two adjacent supporting beams of the supporting beam of the rectangular fixed frame, on which the second bevel gear is arranged, are respectively provided with the second transmission shaft, the motor is characterized in that one end of each second transmission shaft, which is located at the motor, is provided with a third bevel gear, the second bevel gears at two ends of each first transmission shaft are meshed with the third bevel gears on the two second transmission shafts respectively, each first transmission shaft drives the two second transmission shafts to synchronously rotate through the second bevel gears and the third bevel gears, the rotating directions of the two second transmission shafts are opposite, all the brackets are located under the first transmission shafts or the second transmission shafts, the shaft body part of each first transmission shaft or the second transmission shaft corresponding to the position above each bracket is provided with a fourth bevel gear, the fourth bevel gears are meshed with the first bevel gears corresponding to the positions below the brackets respectively, the first transmission shafts and the second transmission shafts drive all the brackets to synchronously rotate through the fourth bevel gears and the first bevel gears, and the rotating directions of the two adjacent brackets are opposite.

The beneficial effects of the utility model reside in that: the structure layout is simple and reasonable, the appearance is attractive and practical, the cost is lower, the mounting and dismounting difficulty is low, and the cost performance is high; the bracket component and the bracket rotating mechanism are fixedly connected integrally and are in mechanical transmission, the opening and closing of all brackets are controlled by one motor, the brackets are always in a free state, the opening and closing of the whole action are consistent, the uniqueness, consistency and reliability of the opening and closing state are ensured, the potential safety hazard caused by poor consistency and reliability of the anti-falling hook is thoroughly avoided, and the safety of equipment is greatly improved; need not additionally to set up the volume of lift passageway or increase equipment, the volume is less relatively, reduces area, and the installation flexibility is higher, is applicable to more storing land uses.

[ description of the drawings ]

FIG. 1 is a schematic structural view of a non-delay synchronous rotating device with bevel gears according to the present invention;

fig. 2 is a partial structural schematic view of a bracket assembly and a bracket rotating mechanism of the non-delay synchronous rotating device with bevel gears according to the present invention;

fig. 3 is a schematic structural view of the non-delay synchronous rotating device with bevel gear according to the present invention supporting an article;

reference numerals: 1. a rectangular fixed frame; 2. a bracket assembly; 21. a bracket; 211. a support frame; 212. a rotating shaft; 213. a bearing; 214. a first bevel gear; 215. a support plate; 3. a carriage rotating mechanism; 31. a motor; 32. a first gear; 33. a second gear; 34. a first drive shaft; 35. a second drive shaft; 36. a second bevel gear; 37. a third bevel gear; 38. and a fourth bevel gear.

[ detailed description ] embodiments

The invention will be further described with reference to the accompanying drawings and specific embodiments:

as shown in fig. 1, 2 and 3, a non-delay synchronous rotating device with bevel gears comprises a rectangular fixed frame 1, a bracket assembly 2 and a bracket rotating mechanism 3, wherein the bracket rotating mechanism 3 is arranged on the rectangular fixed frame 1, the bracket assembly 2 is arranged on the lower portion of the rectangular fixed frame 1, the bracket rotating mechanism 3 is in power connection with the bracket assembly 2, and the bracket rotating mechanism 3 drives the bracket assembly 2 to rotate.

Further, the bracket assembly 2 is composed of a plurality of brackets 21, the brackets 21 are distributed at the lower part of the rectangular fixed frame 1, each bracket 21 comprises a support frame 211, a rotating shaft 212, a bearing 213, a first bevel gear 214 and a support plate 215, the support frame 211 is fixedly installed at the lower part of the rectangular fixed frame 1, the rotating shaft 212 is arranged in the support frame 211, two ends of the rotating shaft 212 respectively penetrate through the upper side and the lower side of the support frame 211, the bearing 213 is arranged at the joint of the rotating shaft 212 and the support frame 211, the first bevel gear 214 is arranged at one end of the rotating shaft 212 penetrating through the upper side of the support frame 211, the rotating shaft 212 is in power connection with the bracket rotating mechanism 3 through the first bevel gear 214, the support plate 215 is arranged at one end of the rotating shaft.

Further, the bracket rotating mechanism 3 includes a motor 31, a first gear 32, a second gear 33, a first transmission shaft 34, a second transmission shaft 35, a second bevel gear 36, a third bevel gear 37, and a fourth bevel gear 38, the motor 31 is installed and fixed above one supporting beam of the rectangular fixed frame 1, the first gear 32 is disposed on an output shaft of the motor 31, the first transmission shaft 34 is disposed between the motor 31 and the supporting beam of the rectangular fixed frame 1 below the motor 31, the second gear 33 is disposed on the first transmission shaft 34, the second gear 33 is located right below the first gear 32, the first gear 32 and the second gear 33 are engaged with each other or connected by a power transmission belt, the motor 31 drives the first transmission shaft 34 to rotate through the first gear 32 and the second gear 33, the second gears 36 are disposed at two ends of the first transmission shaft 34, two adjacent support beams of the rectangular fixed frame 1 provided with the motor 31 are respectively provided with a second transmission shaft 35, one end of the second transmission shaft 35, which is positioned at the motor 31, is provided with a third bevel gear 37, the second bevel gears 36 at two ends of the first transmission shaft 34 are respectively meshed with the third bevel gears 37 on the two second transmission shafts 35, the first transmission shaft 34 drives the two second transmission shafts 35 to synchronously rotate through the second bevel gears 36 and the third bevel gears 37, the rotating directions of the two second transmission shafts 35 are opposite, all the brackets 21 are positioned under the first transmission shaft 34 or the second transmission shaft 35, the shaft body part of the first transmission shaft 34 or the second transmission shaft 35 corresponding to the right above each bracket 21 is provided with a fourth bevel gear 38, the fourth bevel gears 38 are respectively meshed with the first bevel gears 214 corresponding to the right below, and the first transmission shaft 34 and the second transmission shaft 35 drive all the brackets through the fourth bevel gears 38 and the first bevel gears 214 The frames 21 rotate synchronously, and the rotation directions of two adjacent brackets 21 are opposite.

Appropriate changes and modifications to the embodiments described above will become apparent to those skilled in the art from the disclosure and teachings of the foregoing description. Therefore, the present invention is not limited to the specific embodiments disclosed and described above, and some modifications and changes to the present invention should fall within the protection scope of the claims of the present invention. Furthermore, although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.

Claims (3)

1. The utility model provides a take no time delay synchronous revolution device of bevel gear which characterized in that: including rectangle fixed frame, bracket assembly, bracket rotary mechanism, be equipped with bracket rotary mechanism on the rectangle fixed frame, rectangle fixed frame lower part is equipped with bracket assembly, bracket rotary mechanism is connected with bracket assembly power, bracket rotary mechanism drives bracket assembly and rotates.

2. The non-delay synchronous rotating apparatus with bevel gear according to claim 1, characterized in that: the bracket component comprises a plurality of bracket, the bracket distributes in rectangle fixed frame lower part, the bracket includes support frame, axis of rotation, bearing, first bevel gear, layer board, the support frame installation is fixed in rectangle fixed frame lower part, be equipped with the axis of rotation in the support frame, the upper and lower both sides of support frame are passed respectively at the axis of rotation both ends, the axis of rotation is equipped with the bearing with the junction of support frame, the one end that the support frame upside was passed in the axis of rotation is equipped with first bevel gear, the axis of rotation is connected with bracket rotary mechanism power through first bevel gear, the one end that the support frame downside was passed in the axis of rotation is equipped with the layer board.

3. The non-delay synchronous rotating apparatus with bevel gear according to claim 2, characterized in that: the bracket rotating mechanism comprises a motor, a first gear, a second gear, a first transmission shaft, a second bevel gear, a third bevel gear and a fourth bevel gear, the motor is fixedly arranged above one supporting beam of the rectangular fixed frame, the output shaft of the motor is provided with the first gear, the first transmission shaft is arranged between the motor and the supporting beam of the rectangular fixed frame below the motor, the first transmission shaft is provided with the second gear, the second gear is positioned under the first gear, the first gear and the second gear are mutually meshed or are in power connection through a transmission belt, the motor drives the first transmission shaft to rotate through the first gear and the second gear, the two ends of the first transmission shaft are respectively provided with the second bevel gear, two adjacent supporting beams of the supporting beam of the rectangular fixed frame provided with the motor are respectively provided with the second transmission shaft, the motor is characterized in that one end of each second transmission shaft, which is located at the motor, is provided with a third bevel gear, the second bevel gears at two ends of each first transmission shaft are meshed with the third bevel gears on the two second transmission shafts respectively, each first transmission shaft drives the two second transmission shafts to synchronously rotate through the second bevel gears and the third bevel gears, the rotating directions of the two second transmission shafts are opposite, all the brackets are located under the first transmission shafts or the second transmission shafts, the shaft body part of each first transmission shaft or the second transmission shaft corresponding to the position above each bracket is provided with a fourth bevel gear, the fourth bevel gears are meshed with the first bevel gears corresponding to the positions below the brackets respectively, the first transmission shafts and the second transmission shafts drive all the brackets to synchronously rotate through the fourth bevel gears and the first bevel gears, and the rotating directions of the two adjacent brackets are opposite.

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