CN215805033U - Intelligent shock attenuation air compressor machine for ceramic machining - Google Patents

Abstract

The utility model provides an intelligent shock-absorbing air compressor for ceramic processing, which comprises a machine body, a connecting bottom frame and a telescopic rod. A buffer shell is fixedly connected to the outer side of the machine body at the bottom end of the frame, a buffer net frame is fixedly connected to the inner side of the buffer shell, a connecting rod is fixedly connected to the bottom end of the machine body, and a roller is fixedly connected to the bottom end of the connecting rod. Through the first buffer block and the second buffer block, when the roller is in contact with the roller, the effect of shock absorption and buffering is achieved on the roller, and through the buffer pad, the connecting rod is damped and buffered, and the buffer bottom plate is raised and lowered under the control of the telescopic rod. , the effect of shock absorption is achieved through the foam cushion on the bottom surface of the buffer base plate, and when the enclosing frame is raised and lowered, the first buffer block and the second buffer block contact the roller, which is beneficial to the buffer block to dampen the roller.

Description

Intelligent shock attenuation air compressor machine for ceramic machining

Technical Field

The utility model relates to the technical field of air compressors, in particular to an intelligent damping air compressor for ceramic processing.

Background

An air compressor is a device for compressing gas. The air compressor is constructed similarly to a water pump. Most air compressors are of a reciprocating piston type, rotating blades or rotating screws, and in the ceramic processing and production process, air pressure of an air compressor is used as energy for a press, a pattern machine, a cutting machine, an edge grinding machine and a plasma cutting machine, so that normal production of ceramics is guaranteed.

The existing air compressor has the advantages that the vibration amplitude of the air compressor body is too large due to continuous compressed air in the use process, but the whole structure does not have a buffering mechanism, so that the service life of the air compressor is greatly reduced, meanwhile, the bottom of the air compressor is provided with rollers, the rollers are directly contacted with the ground, the air compressor cannot buffer during working, and the whole air compressor also generates noise during working.

In order to solve the problems, the utility model with the application number of 202020748757.X provides a damping type air compressor for ceramic processing, and a spring is sleeved outside a limiting rod, so that when a supporting plate is contacted with the ground, the spring can buffer the vibration of an air compressor body, and the service life of the air compressor body is greatly prolonged; however, in practical use, the device is in contact with the ground through the rollers in the whole structure, the supporting plate and the spring which are arranged in the device can only perform damping and buffering on a part of the position of the bottom of the machine, and a part of vibration is conducted through the rollers in contact with the ground, so that the damping and buffering effects are poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an intelligent damping air compressor for ceramic processing, which is achieved by the following specific technical means:

the utility model provides an intelligent shock attenuation air compressor machine for ceramic machining, including the machine main part, connect underframe and telescopic link, connect underframe fixed connection at the bottom position placed in the middle of the machine main part, telescopic link fixed connection is in the bottom of connecting the underframe, the outside fixedly connected with buffering shell of machine main part, the inboard fixedly connected with buffering rack of buffering shell, the bottom fixedly connected with connecting rod of machine main part, the bottom fixedly connected with gyro wheel of connecting rod, the bottom fixedly connected with buffering bottom plate of telescopic link, the both ends fixedly connected with of buffering bottom plate encloses the frame, the inboard embedding of enclosing the frame is provided with first buffer block and second buffer block, the inboard embedding of enclosing the frame is provided with the blotter, the top fixedly connected with butt joint section of thick bamboo of buffering bottom plate, the inside embedding of butt joint section of thick bamboo is provided with the pole that cup joints, buffer spring has cup jointed on the body of rod.

Further preferred embodiments: the buffer case surrounds the outer position of the machine body.

Further preferred embodiments: the buffer net rack is fixedly arranged at two ends of the inner side of the buffer shell, and the buffer net rack is in a soft plastic grid shape.

Further preferred embodiments: the vertical range of first buffer block and second buffer block sets up, and both are horizontal setting of first buffer block and second buffer block, and the front end sets up arc rubber head, and the spring embedding is passed through in the surround in the outer end of first buffer block and second buffer block simultaneously.

Further preferred embodiments: the blotter sets up to the plastic pad, distributes the contact position between surround frame and connecting rod simultaneously.

Further preferred embodiments: the outside bottom surface of buffer bottom plate is provided with the foam cushion layer, and the surrounding frame is the horizontal setting at buffer bottom plate's both ends, and the surrounding frame is whole to surround the setting to the gyro wheel simultaneously, and the connecting rod runs through the top setting of surrounding frame.

Further preferred embodiments: the top end of the sleeve rod is fixedly connected to the bottom surface of the buffer shell, and the sleeve rod is embedded with a compression spring.

Further preferred embodiments: the bottom end of the buffer spring is simultaneously abutted against the top end of the butt joint barrel.

Has the advantages that:

this kind of intelligent shock attenuation air compressor machine is used in ceramic machining, through the buffering rack that buffering shell and inboard set up, the effectual vibrations that produce the machine main part when moving are cushioned, reach the absorbing effect to machine main part itself.

This kind of intelligent shock attenuation air compressor machine is used in ceramic machining through first buffer block and second buffer block, in the time of contacting the gyro wheel to reach the effect of shock attenuation buffering to the gyro wheel.

This kind of intelligent shock attenuation air compressor machine is used in ceramic machining passes through the blotter to carry out the shock attenuation buffering to the connecting rod.

This kind of intelligent shock attenuation air compressor machine for ceramic machining, buffer plate goes up and down under the control of telescopic link, thereby reaches absorbing effect through the foam cushion layer of buffer plate bottom surface, and the enclosure frame when going up and down for first buffer block and second buffer block contact the gyro wheel, thereby are favorable to the buffer block to carry out the shock attenuation to the gyro wheel.

This kind of intelligent shock attenuation air compressor machine for ceramic manufacture through set up between buffer bottom plate and machine main part and cup joint pole and buffer spring to reach the effect of shock attenuation buffering.

Drawings

Fig. 1 is a plan view of the overall structure of the present invention.

FIG. 2 is an enlarged view of the structure at A in FIG. 1 according to the present invention.

Fig. 3 is an enlarged view of the structure at B in fig. 1 according to the present invention.

In FIGS. 1-3: machine main part 1, buffering shell 2, buffering rack 3, connection underframe 4, telescopic link 5, connecting rod 6, gyro wheel 7, enclosure frame 8, buffer bottom plate 9, first buffer block 10, first buffer block 11, blotter 12, cup joint pole 13, buffer spring 14, butt joint section of thick bamboo 15.

Detailed Description

As shown in figures 1 to 3:

the utility model provides an intelligent shock-absorbing air compressor for ceramic processing, which comprises a machine main body 1, a connecting bottom frame 4 and a telescopic rod 5, wherein the connecting bottom frame 4 is fixedly connected at the middle position of the bottom end of the machine main body 1, the telescopic rod 5 is fixedly connected at the bottom end of the connecting bottom frame 4, the outer side of the machine main body 1 is fixedly connected with a buffer shell 2, the inner side of the buffer shell 2 is fixedly connected with a buffer net rack 3, the bottom end of the machine main body 1 is fixedly connected with a connecting rod 6, the bottom end of the connecting rod 6 is fixedly connected with a roller 7, the bottom end of the telescopic rod 5 is fixedly connected with a buffer bottom plate 9, two ends of the buffer bottom plate 9 are fixedly connected with an enclosing frame 8, the inner side of the enclosing frame 8 is embedded with a first buffer block 10 and a second buffer block 11, the inner side of the enclosing frame 8 is embedded with a buffer pad 12, the top end of the buffer bottom plate 9 is fixedly connected with a butt-joint barrel 15, the inner part of the butt-joint barrel 15 is embedded with a butt-joint rod 13, a buffer spring 14 is sleeved on the rod body of the sleeved rod 13.

The buffer case 2 surrounds the outside of the device body 1.

Wherein, the fixed setting of buffering rack 3 is in the inboard both ends position of buffering shell 2, and buffering rack 3 sets up to soft plastic grid form, and through buffering shell 2 and the buffering rack 3 of inboard setting, the effectual vibrations that produce when running machine main part 1 are cushioned, reach the absorbing effect to machine main part 1 itself.

Wherein, the vertical range setting of first buffer block 10 and second buffer block 11, and first buffer block 10 and second buffer block 11 both are horizontal setting, and the front end sets up arc rubber head, and the spring embedding is passed through in surrounding frame 8 in the outer end of first buffer block 10 and second buffer block 11 simultaneously, through first buffer block 10 and second buffer block 11, when contacting gyro wheel 7 to reach the effect of shock attenuation buffering to gyro wheel 7.

Wherein, blotter 12 sets up to the plastic pad, distributes simultaneously in the contact position between bounding frame 8 and connecting rod 6, through blotter 12 to carry out the shock attenuation buffering to connecting rod 6.

Wherein, the outside bottom surface of buffer bottom plate 9 is provided with the foam cushion layer, it transversely sets up to enclose frame 8 at the both ends of buffer bottom plate 9 to be the level, it wholly surrounds the setting to gyro wheel 7 to enclose frame 8 simultaneously, connecting rod 6 runs through the top setting of enclosing frame 8, buffer bottom plate 9 goes up and down under the control of telescopic link 5, thereby foam cushion layer through buffer bottom plate 9 bottom surface reaches absorbing effect, and it goes up and down to enclose frame 8 in the time of going on, make first buffer block 10 and second buffer block 11 contact gyro wheel 7, thereby be favorable to the buffer block to carry out the shock attenuation to gyro wheel 7.

Wherein, the top of the sleeve joint rod 13 is fixedly connected to the bottom surface of the buffer shell 2, and the sleeve joint rod 13 is embedded with a compression spring.

Wherein, buffer spring 14 bottom supports simultaneously and docks a section of thick bamboo 15 top, through set up cup joint pole 13 and buffer spring 14 between buffer bottom plate 9 and machine main part 1 to reach the effect of shock attenuation buffering.

The working principle is as follows:

the concrete using mode and the effect of this embodiment, machine main part 1 is in the operation, the shock attenuation is buffered through buffering rack 3 to the vibrations that produce itself, machine main part 1 is in quiescent condition, external control device control telescopic link 5 is flexible, drive the surrounding frame 8 decline of buffer bottom plate 9 and both ends position, when surrounding frame 8 and buffer bottom plate 9 descend, buffer bottom plate 9 contacts ground, cooperation buffer spring 14 and cup joint pole 13 play absorbing effect, and surrounding frame 8 is when descending, surround gyro wheel 7, at this moment first buffer block 10 and second buffer block 11 contact gyro wheel 7, thereby shock to on the gyro wheel 7 is cushioned and the shock attenuation.

Claims (8)

1. An intelligent shock-absorbing air compressor for ceramic processing, comprising a machine body (1), a connecting bottom frame (4) and a telescopic rod (5), and the connecting bottom frame (4) is fixedly connected to the machine body (1) The bottom end is in the center position, and the telescopic rod (5) is fixedly connected to the bottom end of the connecting bottom frame (4). A buffer net frame (3) is fixedly connected, a connecting rod (6) is fixedly connected to the bottom end of the machine main body (1), a roller (7) is fixedly connected to the bottom end of the connecting rod (6), and the bottom end of the telescopic rod (5) is fixedly connected. A buffer bottom plate (9) is fixedly connected to the end, an enclosing frame (8) is fixedly connected to both ends of the buffer bottom plate (9), and a first buffer block (10) and a second buffer block ( 11), a buffer pad (12) is embedded in the inner side of the enclosing frame (8), a docking cylinder (15) is fixedly connected to the top of the buffer bottom plate (9), and a socket rod (13) is embedded in the docking cylinder (15). ), a buffer spring (14) is sleeved on the rod body of the socket rod (13). 2 . The intelligent shock-absorbing air compressor for ceramic processing according to claim 1 , wherein the buffer shell ( 2 ) surrounds the outer position of the machine main body ( 1 ). 3 . 3. The intelligent shock-absorbing air compressor for ceramic processing according to claim 1, characterized in that: the buffer net frame (3) is fixedly arranged at both ends of the inner side of the buffer shell (2), and the buffer net frame (3) Set as a soft plastic grid. 4. The intelligent shock-absorbing air compressor for ceramic processing according to claim 1, wherein the first buffer block (10) and the second buffer block (11) are arranged vertically, and the first buffer block (10) and the second buffer block (11) are arranged vertically. Both the block (10) and the second buffer block (11) are arranged laterally, the front end is provided with an arc-shaped rubber head, and the outer ends of the first buffer block (10) and the second buffer block (11) are embedded in the surrounding through springs. in box (8). 5 . The intelligent shock-absorbing air compressor for ceramic processing according to claim 1 , wherein the buffer pad ( 12 ) is configured as a plastic pad, and is distributed on the surrounding frame ( 8 ) and the connecting rod ( 6 ) at the same time. 6 . contact position between. 6. The intelligent shock-absorbing air compressor for ceramic processing according to claim 1, characterized in that: the outer bottom surface of the buffer bottom plate (9) is provided with a foam cushion, and the enclosing frame (8) is on the buffer bottom plate (9). Both ends of the ) are arranged horizontally and laterally, while the enclosing frame (8) encloses the roller (7) as a whole, and the connecting rod (6) is arranged through the top of the enclosing frame (8). 7. The intelligent shock-absorbing air compressor for ceramic processing according to claim 1, characterized in that: the top of the socket rod (13) is fixedly connected to the bottom surface of the buffer shell (2) at the same time, and the socket rod (13) A compression spring is embedded inside. 8 . The intelligent shock-absorbing air compressor for ceramic processing according to claim 1 , wherein the bottom end of the buffer spring ( 14 ) abuts on the top end of the docking cylinder ( 15 ) at the same time. 9 .

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