CN114380058A - Powder vacuum conveying equipment - Google Patents

Abstract

The application relates to the technical field of powder conveying, in particular to vacuum powder conveying equipment which comprises a body and a damping mechanism, wherein the damping mechanism comprises a fixed block, a damping assembly and a supporting assembly, a first groove is formed in the fixed block, the damping block is arranged in the first groove in a sliding mode, and the body is arranged on the damping block; the damping assembly is arranged on the fixed block and connected with the damping block; the supporting component is arranged on the fixed block and connected with the damping block. The application has the effect of prolonging the service life of the equipment.

Description

Powder vacuum conveying equipment

Technical Field

The application relates to the technical field of powder conveying, in particular to a vacuum powder conveying device.

Background

The powder vacuum conveying equipment is equipment for producing vacuum conveying powder and granular materials through a vacuum pump.

At present, chinese patent with publication number CN211109934U discloses an anti-blocking vacuum feeder, which comprises a vacuum feeder body, wherein a top cover is fixed on the upper surface of the vacuum feeder body, a vacuum generator and a blowback device are correspondingly fixed on the top of the top cover, and the vacuum generator and the blowback device are fixedly connected through an air pipe.

In the process of implementing the application, the inventor finds that at least the following problems exist in the technology: because vacuum generator and blowback device can make the vacuum material loading machine produce certain vibrations when working, because the position of vacuum material loading machine is fixed, consequently the power that the vibrations produced can be used on the vacuum material loading machine, can lead to the damage of vacuum material loading machine after the number of times of vibrations has been many to lead to the life-span of vacuum material loading machine to shorten.

Disclosure of Invention

In order to prolong the service life of equipment, the application provides a powder vacuum conveying equipment.

The application provides a powder vacuum conveying equipment adopts following technical scheme:

a powder vacuum conveying device comprises a body and a damping mechanism, wherein the damping mechanism comprises a fixed block, a damping assembly and a supporting assembly, a first groove is formed in the fixed block, the damping block is arranged in the first groove in a sliding mode, and the body is arranged on the damping block; the damping assembly is arranged on the fixed block and connected with the damping block; the supporting component is arranged on the fixed block and connected with the damping block.

By adopting the technical scheme, when the body generates vibration, the force generated by the vibration can be applied to the damping block, and then the damping component can counteract a part of the force generated by the vibration; meanwhile, the supporting assembly can support and limit the damping block, so that the phenomenon that the damping assembly cannot work is reduced; the damping mechanism who sets up can improve equipment life.

Optionally, the damping assembly includes a first fixing rod, a second fixing rod and a spring, the first fixing rod is disposed on the fixing block, a second groove is formed in the first fixing rod, one end of the second fixing rod is slidably disposed in the second groove, and the other end of the second fixing rod is rotatably disposed with the damping block; one end of the spring is connected to the side wall of the second groove, and the other end of the spring is connected to the second fixing rod.

By adopting the technical scheme, when the vibration force generated by the vibration of the body acts on the damping block, the damping block can drive the second fixed rod to slide in the second groove; the spring is elastically deformed, and the force generated by the deformation of the spring is used for offsetting a part of the force generated by the vibration of the body.

Optionally, a first connecting mechanism connected with the first fixing rod is arranged on the fixing block, a placing groove communicated with the first groove is formed in the fixing block, the first fixing rod is clamped with the placing groove, and a connecting groove is formed in the first fixing rod; the first connecting mechanism comprises an adjusting block, a convex block, an adjusting screw and a first motor, a first cavity communicated with the placing groove is formed in the fixing block, the adjusting block is arranged in the first cavity in a sliding mode, and the convex block is arranged on the adjusting block and clamped with the connecting groove; the adjusting screw rod is rotatably arranged in the first cavity, penetrates through the adjusting block and is in threaded connection with the adjusting block; the first motor is arranged on the fixed block, and one end of the adjusting screw is connected with the first motor.

Through adopting above-mentioned technical scheme, start first motor, the output shaft of first motor drives adjusting screw and rotates, and adjusting screw drives the regulating block and slides in first cavity, makes lug on the regulating block and spread groove on the first dead lever part, then takes out first dead lever from the standing groove of first fixed block.

Optionally, a second connecting mechanism connected with the damping block is arranged on the second fixing rod, the second connecting mechanism comprises a connecting plate and a connecting bolt, one end, far away from the second groove, of the second fixing rod is rotatably arranged on the connecting plate, and the connecting bolt penetrates through the connecting plate and is in threaded connection with the damping block.

By adopting the technical scheme, when the damping component needs to be replaced, the first fixing rod is separated from the fixing block; and then separating the connecting bolt from the damping block, separating the connecting plate from the damping block and replacing the new damping assembly.

Optionally, an adjusting cavity communicated with the first groove is formed in the fixed block, the supporting component comprises a supporting block, a second motor, a first gear and a first rack, the supporting block is slidably arranged in the adjusting cavity, and the supporting block can abut against the damping block and support the damping block; the second motor is arranged on the fixed block, and the first gear is arranged on the second motor; the first rack is arranged on the supporting block and meshed with the first gear.

Through adopting above-mentioned technical scheme, when the body made the shock attenuation not in the horizontality, make the second motor drive first gear revolve, the first rack with first gear meshing drives the supporting shoe motion, and the supporting shoe is contradicted the snubber block and is driven the snubber block motion, adjusts the snubber block into the horizontality.

Optionally, a fixing mechanism connected to the fixing block is disposed on the damper block, the fixing mechanism includes a fixture block, a second rack, a third motor and a second gear, the third motor is disposed on the damper block, and the second gear is disposed on the third motor; the two clamping blocks are respectively positioned at two sides of the second gear, each clamping block is provided with the second rack, and the two second racks are meshed with the second gear; two clamping grooves communicated with the first groove are formed in the side wall of the fixed block, and the two clamping grooves are respectively located on the two side walls opposite to the first groove; the two clamping blocks are respectively clamped with the two clamping grooves.

By adopting the technical scheme, the third motor is started, the output shaft of the third motor drives the second gear to rotate, the second gear drives the two second racks to move, and the second racks drive the two clamping blocks to move backwards, so that the two clamping blocks are respectively clamped with the two clamping grooves; the fixed establishment that sets up makes the snubber block keep the horizontality on the fixed block with supporting component jointly to improve the stability of snubber block on the fixed block.

Optionally, a limiting mechanism is arranged on the fixed block, the limiting mechanism includes a first limiting block, a second limiting block, a stabilizing block and a reinforcing component, the first limiting block is arranged on the fixed block through a mounting bolt, a third groove is formed in the first limiting block, and the second limiting block is slidably arranged in the third groove; the stabilizing block is rotatably arranged on the second limiting block and is connected to the body through a fixing bolt; the reinforcing assembly comprises a reinforcing block, a fourth motor, a third gear and a third rack, the reinforcing block is arranged on the first limiting block in a sliding mode, and a reinforcing groove clamped with the reinforcing block is formed in the second limiting block; the fourth motor is arranged on the first limiting block, and the third gear is arranged on the fourth motor; the third rack is arranged on the reinforcing block and meshed with the third gear.

By adopting the technical scheme, when the damping block is not in a horizontal state, the body drives the stabilizing block to move, the stabilizing block rotates on the second limiting block, and the stabilizing block can drive the second limiting block to slide in the third groove; when the support assembly enables the shock absorption block to be in a horizontal state, a fourth motor is started, an output shaft of the fourth motor drives a third gear to rotate, a third rack meshed with the third gear drives a reinforcing block to move, and the reinforcing block is connected with a reinforcing groove in a clamping mode; the limiting mechanism can limit the shaking body and improve the stability of the body on the damping block.

Optionally, the stabilizing block comprises a first connecting block, a second connecting block, a bidirectional screw and a fifth motor, the first connecting block is rotatably arranged on the second limiting block, a chute is formed in the first connecting block, and the second connecting block is slidably arranged at both ends of the chute; the two-way screw rod penetrates through the two second connecting blocks, and the two second connecting blocks are in threaded connection with the two-way screw rod; the fifth motor is arranged on the first connecting block and is connected with the bidirectional screw; the second connecting block is connected to the body through a fixing bolt.

By adopting the technical scheme, the fifth motor drives the two-way screw to rotate, the two-way screw drives the two second connecting blocks to move oppositely, the second connecting blocks are enabled to be abutted against the body, and finally the fixing bolt penetrates through the second connecting blocks to be in threaded connection with the body; the stability of the connection with the body can be improved by the arranged stabilizing block.

Optionally, the adjusting assembly is arranged on the second limiting block and connected with the stabilizing block, the adjusting assembly comprises an adjusting shaft and a sixth motor, the adjusting shaft is rotatably arranged on the second limiting block, and the stabilizing block is arranged on the adjusting shaft; the sixth motor is arranged on the second limiting block and is connected with the adjusting shaft.

By adopting the technical scheme, when the body vibrates, the output shaft of the sixth motor drives the adjusting shaft to rotate, and the adjusting shaft drives the stabilizing block to rotate; the stabilizing block is changed into active movement, so that the stabilizing block can better move together with the body.

In summary, the present application includes the following beneficial technical effects:

1. the arranged damping mechanism can prolong the service life of the equipment;

2. the arranged fixing mechanism and the supporting component jointly enable the damping block to keep a horizontal state on the fixing block, so that the stability of the damping block on the fixing block is improved;

3. the limiting mechanism can limit the shaking body and improve the stability of the body on the damping block.

Drawings

Fig. 1 is a schematic structural diagram of a powder vacuum conveying apparatus in an embodiment of the present application;

FIG. 2 is a schematic structural view of a shock absorbing mechanism according to an embodiment of the present application;

FIG. 3 is a schematic structural view of a shock absorbing assembly according to an embodiment of the present application;

FIG. 4 is a schematic structural view of a support assembly according to an embodiment of the present application;

FIG. 5 is a schematic structural view of a fixing mechanism in an embodiment of the present application;

FIG. 6 is a schematic structural view of a limiting mechanism in an embodiment of the present application;

fig. 7 is a schematic structural view of a reinforcing member in an embodiment of the present application.

Reference numerals: 1. a body; 2. a damping mechanism; 21. a fixed block; 211. a first groove; 22. a damper block; 23. a shock absorbing assembly; 231. a first fixing lever; 2311. a second groove; 232. a second fixing bar; 233. a spring; 24. a support assembly; 241. a support block; 242. a second motor; 243. a first gear; 244. a first rack; 3. a first connecting mechanism; 31. an adjusting block; 32. a bump; 33. adjusting the screw rod; 34. a first motor; 4. a second connecting mechanism; 41. a connecting plate; 42. a connecting bolt; 5. a fixing mechanism; 51. a clamping block; 52. a second rack; 53. a third motor; 54. a second gear; 6. a limiting mechanism; 61. a first limiting block; 62. a second limiting block; 621. a reinforcing groove; 63. a stabilizing block; 631. a first connection block; 6311. a chute; 632. a second connecting block; 633. a bidirectional screw; 634. a fifth motor; 635. adjusting a rod; 64. a reinforcement assembly; 641. a reinforcing block; 642. a fourth motor; 643. a third gear; 644. a third rack; 65. an adjustment assembly; 651. an adjustment shaft; 652. and a sixth motor.

Detailed Description

The present application is described in further detail below with reference to figures 1-7.

The embodiment of the application discloses powder vacuum conveying equipment.

Referring to fig. 1, the powder vacuum conveying apparatus includes a body 1 and a damper 2, and the body 1 is placed on the damper 2.

Referring to fig. 2 and 3, the damping mechanism 2 includes a fixing block 21, a first groove 211 is formed on the fixing block 21, a damping block 22 is slidably connected in the first groove 211, and the body 1 is placed on the damping block 22.

A damping assembly 23 is arranged on the fixed block 21, the damping assembly 23 comprises a first fixing rod 231, a second groove 2311 is formed in one end of the first fixing rod 231 along the length direction of the first fixing rod, and a second fixing rod 232 is connected in the second groove 2311 in a sliding manner; a spring 233 is disposed in the second groove 2311, one end of the spring 233 is coupled to the bottom wall of the second groove 2311, and the other end of the spring 233 is coupled to the second fixing lever 232 disposed in the second groove 2311.

A second connecting mechanism 4 is arranged at one end of the second fixing rod 232 far away from the first fixing rod 231, the second connecting mechanism 4 comprises a connecting plate 41, and the second fixing rod 232 is rotatably arranged on the connecting plate 41; the connecting plate 41 is provided with a connecting bolt 42 which passes through the connecting plate 41 and is in threaded connection with the damper block 22.

Offer the standing groove with first dead lever 231 joint on the diapire of first recess 211, offer the first cavity with the standing groove intercommunication on the fixed block 21.

The fixed block 21 is provided with a first connecting mechanism 3, the first connecting mechanism 3 comprises an adjusting block 31 connected in a first cavity in a sliding manner, and a convex block 32 is fixedly connected to the adjusting block 31; a connecting groove clamped with the convex block 32 is formed in the first fixing rod 231 positioned in the placing groove; an adjusting screw rod 33 is rotatably connected in the first cavity, and the adjusting screw rod 33 penetrates through the adjusting block 31 and is in threaded connection with the adjusting block 31; the side wall of the fixed block 21 is fixedly connected with a first motor 34, and an output shaft of the first motor 34 is connected with one end of the adjusting screw 33.

Referring to fig. 2 and 4, an adjusting cavity communicated with the first groove 211 is formed in the fixing block 21, a supporting assembly 24 is arranged on the fixing block 21, the supporting assembly 24 includes a supporting block 241 slidably connected in the adjusting cavity, the supporting block 241 can abut against the damping block 22 and support the damping block 22, and a first rack 244 is integrally arranged on a side wall of the supporting block 241; a second motor 242 is fixedly connected to the side wall of the adjusting chamber, and a first gear 243 meshed with the first rack 244 is keyed on an output shaft of the second motor 242.

Two opposite side walls of the first groove 211 are respectively provided with a clamping groove; a second cavity is formed in the damping block 22, and two sliding holes communicated with the second cavity are formed in the damping block 22.

Referring to fig. 2 and 5, the damping block 22 is provided with a fixing mechanism 5, the fixing mechanism 5 includes a fixture block 51, and each sliding hole is connected with the fixture block 51 in a sliding manner; a third motor 53 is fixedly connected in the damping block 22, a second gear 54 is keyed on an output shaft of the third motor 53, the second gear 54 is located in the second cavity, and the second gear 54 is located between the two fixture blocks 51; the side walls of the two latch blocks 51 close to each other are integrally provided with a second rack 52, and the second rack 52 on the two latch blocks 51 are both meshed with a second gear 54.

Referring to fig. 1 and 6, the fixing block 21 is provided with a limiting mechanism 6, the limiting mechanism 6 includes a first limiting block 61 connected to the fixing block 21 by a mounting bolt, third grooves are respectively formed in one end of the first limiting block 61 far away from the fixing block 21 along the length direction of the first limiting block, and a second limiting block 62 is connected to the third grooves in a sliding manner.

Referring to fig. 6 and 7, an end of the second limiting block 62 away from the fixed block 21 is provided with an adjusting assembly 65, and the adjusting assembly 65 includes an adjusting shaft 651 rotatably connected to the second limiting block 62; a sixth motor 652 is fixedly connected to the second limiting block 62, and an output shaft of the sixth motor 652 is connected to one end of the adjusting shaft 651.

Be provided with firm piece 63 on the adjusting shaft 651, firm piece 63 includes first connecting block 631 of fixed connection on adjusting shaft 651, spout 6311 has been seted up along its length direction to one side that first connecting block 631 was kept away from second limiting block 62, the both ends of spout 6311 are all slided and are connected with one and are adjusted pole 635, two are adjusted the equal fixedly connected with of pole 635 and are contradicted the second connecting block 632 of body 1, be provided with the fixing bolt who passes second connecting block 632 and body 1 threaded connection on the second connecting block 632. A bidirectional screw 633 is rotatably connected in the sliding groove 6311, the bidirectional screw 633 passes through the two adjusting rods 635, and the two second adjusting rods 635 are respectively in threaded connection with two ends of the bidirectional screw 633; the first connecting block 631 is fixedly connected with a fifth motor 634, and an output shaft of the fifth motor 634 is in threaded connection with one end of the bidirectional screw 633.

The first limiting block 61 is provided with a reinforcing component 64, the reinforcing component 64 comprises a reinforcing block 641 which is connected to the first limiting block 61 in a sliding manner, and the second limiting block 62 is provided with a reinforcing groove 621 which is clamped with the reinforcing block 641; a fourth motor 642 is fixedly connected to the first limiting block 61, and a third gear 643 is keyed on an output shaft of the fourth motor 642; the reinforcing block 641 is integrally provided with a third rack 644 engaged with the third gear 643.

The motors in this embodiment are all three-phase asynchronous motors.

The implementation principle of the powder vacuum conveying equipment in the embodiment of the application is as follows: the fixing block 21 is connected to the ground where the body 1 is to be installed by an expansion bolt, and then the connecting plate 41 is abutted against the damper block 22, and the connecting bolt 42 is threaded with the damper block 22 through the connecting plate 41.

Then, one end of the first fixing rod 231, which is far away from the shock absorption block 22, passes through the first groove 211 and is clamped into the placing groove of the fixing block 21; then, the first motor 34 is started, the output shaft of the first motor 34 drives the adjusting screw 33 to rotate, and the adjusting screw 33 drives the adjusting block 31 to slide in the first cavity of the fixing block 21, so that the protrusion 32 on the adjusting block 31 is clamped with the connecting groove on the first fixing rod 231.

The body 1 is then placed on the damper block 22.

Then, the first limiting block 61 is connected to the fixing block 21 through a mounting bolt; then, the fifth motor 634 is started, an output shaft of the fifth motor 634 drives the two adjusting rods 635 to move in opposite directions, so that the second connecting block 632 on the adjusting rods 635 abuts against the body 1, and finally, the fixing bolt penetrates through the second connecting block 632 to be in threaded connection with the body 1.

When the body 1 transports powder, the body 1 vibrates, the second fixing rod 232 slides in the first groove 211 of the first fixing rod 231, and the spring 233 is pressed. When the body 1 vibrates, the second limiting block 62 can slide in the third groove of the first limiting block 61; meanwhile, the sixth motor 652 is started, the output shaft of the sixth motor 652 drives the adjusting shaft 651 to rotate, and the adjusting shaft 651 drives the first connecting block 631 to rotate.

When powder enters the body 1 and is distributed unevenly, the second motor 242 is started, the output shaft of the second motor 242 drives the first gear 243 to rotate, the first gear 243 drives the first rack 244 to move, the first rack 244 drives the supporting block 241 to move in the direction close to the damper block 22 in the adjusting cavity, the supporting block 241 props against the damper block 22 and drives the damper block 22 to move, and the damper block 22 is in a horizontal state; then, the third motor 53 is started, an output shaft of the third motor 53 drives the second gear 54 to rotate, the second gear 54 drives the two second racks 52 to move backwards, the two second racks 52 drive the two clamping blocks 51 to move backwards, and the two clamping blocks 51 are respectively clamped with the clamping grooves on the two side walls of the first groove 211.

Meanwhile, the fourth motor 642 is started, an output shaft of the fourth motor 642 drives the third gear 643 to rotate, the third gear 643 drives the third rack 644 to move, and the third rack 644 drives the reinforcing block 641 to move towards the direction close to the second limiting block 62, so that the reinforcing block 641 is clamped with the reinforcing groove 621 of the second limiting block 62.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The powder vacuum conveying equipment comprises a body (1) and is characterized by further comprising a damping mechanism (2), wherein the damping mechanism (2) comprises a fixed block (21), a damping block (22), a damping assembly (23) and a supporting assembly (24), a first groove (211) is formed in the fixed block (21), the damping block (22) is arranged in the first groove (211) in a sliding mode, and the body (1) is arranged on the damping block (22); the damping component (23) is arranged on the fixed block (21) and connected with the damping block (22); the supporting component (24) is arranged on the fixing block (21) and connected with the damping block (22).

2. The powder vacuum conveying equipment as claimed in claim 1, wherein the damping assembly (23) comprises a first fixing rod (231), a second fixing rod (232) and a spring (233), the first fixing rod (231) is arranged on the fixing block (21), a second groove (2311) is formed in the first fixing rod (231), one end of the second fixing rod (232) is slidably arranged in the second groove (2311), and the other end of the second fixing rod is rotatably arranged with the damping block (22);

one end of the spring (233) is connected to the side wall of the second groove (2311) and the other end is connected to the second fixing rod (232).

3. The powder vacuum conveying equipment as claimed in claim 2, wherein the fixed block (21) is provided with a first connecting mechanism (3) connected with the first fixing rod (231), the fixed block (21) is provided with a placing groove communicated with the first groove (211), the first fixing rod (231) is clamped with the placing groove, and the first fixing rod (231) is provided with a connecting groove;

the first connecting mechanism (3) comprises an adjusting block (31), a convex block (32), an adjusting screw rod (33) and a first motor (34), a first cavity communicated with the placing groove is formed in the fixing block (21), the adjusting block (31) is arranged in the first cavity in a sliding mode, and the convex block (32) is arranged on the adjusting block (31) and clamped with the connecting groove; the adjusting screw rod (33) is rotatably arranged in the first cavity, and the adjusting screw rod (33) penetrates through the adjusting block (31) and is in threaded connection with the adjusting block (31); the first motor (34) is arranged on the fixing block (21), and one end of the adjusting screw rod (33) is connected with the first motor (34).

4. The powder vacuum conveying equipment as claimed in claim 3, wherein the second fixing rod (232) is provided with a second connecting mechanism (4) connected with the damping block (22),

the second connecting mechanism (4) comprises a connecting plate (41) and a connecting bolt (42), one end, far away from the second groove (2311), of the second fixing rod (232) is rotatably arranged on the connecting plate (41), and the connecting bolt (42) penetrates through the connecting plate (41) to be in threaded connection with the shock absorption block (22).

5. The powder vacuum conveying equipment as claimed in claim 1, wherein the fixed block (21) is provided with an adjusting cavity communicated with the first groove (211), the supporting assembly (24) comprises a supporting block (241), a second motor (242), a first gear (243) and a first rack (244), the supporting block (241) is slidably arranged in the adjusting cavity, and the supporting block (241) can abut against the damper block (22) and support the damper block (22);

the second motor (242) is arranged on the fixed block (21), and the first gear (243) is arranged on the second motor (242); the first rack (244) is disposed on the support block (241) and engaged with the first gear (243).

6. The powder vacuum conveying equipment as claimed in claim 1, wherein the damping block (22) is provided with a fixing mechanism (5) connected with the fixing block (21), the fixing mechanism (5) comprises a fixture block (51), a second rack (52), a third motor (53) and a second gear (54),

the third motor (53) is arranged on the damping block (22), and the second gear (54) is arranged on the third motor (53);

the number of the clamping blocks (51) is two, the two clamping blocks (51) are respectively located on two sides of the second gear (54), each clamping block (51) is provided with the second rack (52), and the two second racks (52) are meshed with the second gear (54);

two clamping grooves communicated with the first groove (211) are formed in the side wall of the fixed block (21), and the two clamping grooves are respectively located on the two opposite side walls of the first groove (211); the two clamping blocks (51) are respectively clamped with the two clamping grooves.

7. The vacuum powder conveying equipment as claimed in claim 1, wherein the fixing block (21) is provided with a limiting mechanism (6), the limiting mechanism (6) comprises a first limiting block (61), a second limiting block (62), a stabilizing block (63) and a reinforcing assembly (64), the first limiting block (61) is arranged on the fixing block (21) through a mounting bolt, the first limiting block (61) is provided with a third groove, and the second limiting block (62) is slidably arranged in the third groove;

the stabilizing block (63) is rotatably arranged on the second limiting block (62), and the stabilizing block (63) is connected to the body (1) through a fixing bolt;

the reinforcing assembly (64) comprises a reinforcing block (641), a fourth motor (642), a third gear (643) and a third rack (644), the reinforcing block (641) is arranged on the first limiting block (61) in a sliding mode, and a reinforcing groove (621) clamped with the reinforcing block (641) is formed in the second limiting block (62);

the fourth motor (642) is disposed on the first limiting block (61), and the third gear (643) is disposed on the fourth motor (642); the third rack (644) is disposed on the reinforcement block (641) and is engaged with the third gear (643).

8. The powder vacuum conveying equipment as claimed in claim 7, wherein the stabilizing block (63) comprises a first connecting block (631), a second connecting block (632), a bidirectional screw (633) and a fifth motor (634), the first connecting block (631) is rotatably disposed on the second limiting block (62), a chute (6311) is disposed on the first connecting block (631), and two ends of the chute (6311) are slidably disposed with one second connecting block (632);

the bidirectional screw (633) penetrates through the two second connecting blocks (632), and the two second connecting blocks (632) are in threaded connection with the bidirectional screw (633); the fifth motor (634) is arranged on the first connecting block (631) and is connected with the bidirectional screw rod (633);

the second connecting block (632) is connected to the body (1) through a fixing bolt.

9. The powder vacuum conveying equipment according to claim 7, wherein the adjusting assembly (65) is arranged on the second limiting block (62) and connected with the stabilizing block (63), the adjusting assembly (65) comprises an adjusting shaft (651) and a sixth motor (652), the adjusting shaft (651) is rotatably arranged on the second limiting block (62), and the stabilizing block (63) is arranged on the adjusting shaft (651); the sixth motor (652) is arranged on the second limiting block (62) and is connected with the adjusting shaft (651).

Images