CN212095524U - Material safety recovery device of numerical control gantry drill - Google Patents

Abstract

The utility model discloses a numerical control gantry drill material safety recovery device, two groups of parallel material receiving components are symmetrically arranged at two ends of a gantry drill blanking position, the blanking of the gantry drill falls into the material receiving component, the material receiving component uniformly collects the blanking, a transverse motor drives an extension shaft to rotate, the extension shaft drives a rotary vane to rotate, the rotary vane pushes the blanking to a square cover and enables the blanking to fall onto a conveying belt in a transfer component, strip-shaped convex grooves are uniformly distributed on the surface of the conveying belt, the blanking with residual temperature cannot be damaged when falling onto the conveying belt, the rotating conveying belt can push the blanking to one side well, a fan is electrified to generate air flow, the blanking air pipe on the conveying belt can be sucked into the blanking air pipe and finally falls onto a blanking carrying trolley, so that the gantry drill can be collected at one time well, the accumulation of processing areas can be effectively reduced, meanwhile, the collected blanking can be further utilized, and unnecessary resource waste is avoided.

Description

Material safety recovery device of numerical control gantry drill

Technical Field

The utility model relates to a longmen bores accessory technical field, specifically is numerical control longmen and bores material safety recovery unit.

Background

The gantry drilling machine has the functions of drilling, tapping and milling, is mainly used for machining flanges, heat exchangers and tube plate pieces, and is numerical-controlled in machining process, high in efficiency, high in precision, convenient to program and simple to operate. The gantry movable type high-speed numerical control plane drilling machine is a flexible numerical control drilling machine and is suitable for batch production of various products.

The gantry drill generates a large amount of metal waste with high temperature in the machining process, and the metal waste is called blanking. If the blanking is not timely cleared, the blanking accumulation in the machining area of the gantry drill is too much to influence machining, meanwhile, unnecessary abrasion is caused to equipment, and the common gantry drill does not have blanking collection capacity, so that unnecessary resource waste is caused.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a numerical control longmen bores material safety recovery unit possesses the blanking that can be fine and collects, can not only effectively reduce the regional blanking of processing and pile up, avoids the advantage of unnecessary wasting of resources simultaneously, can solve the problem among the prior art.

In order to achieve the above object, the utility model provides a following technical scheme:

the numerical control gantry drill material safety recovery device comprises a material receiving assembly, a transfer assembly and a concentration assembly, wherein one end of the material receiving assembly is connected with the transfer assembly, one side of the transfer assembly is provided with the concentration assembly, the material receiving assembly comprises a sheath, an end block, a rotary piece, a transverse motor, an end plate, an extension shaft and a square cover, the square cover is installed at one end of the sheath, the end plates are fixedly welded at two ends of the sheath, the end plates are connected with the transverse motor through bolts, the extension shaft is installed at the output end of the transverse motor and penetrates through the end plate, the extension shaft is connected with one end of the rotary piece, the other end of the rotary piece is provided with a cylindrical end block, the end block is movably connected with the inner wall of the sheath, the inner wall of the sheath is also movably;

the transfer assembly comprises a vertical motor, a transfer box, a guide frame, a conveying belt, a round roller, a first bevel gear, a second bevel gear and a transverse shaft, wherein the vertical motor is installed on the transfer box, the first bevel gear is installed at the output end of the vertical motor, the first bevel gear is movably connected with the second bevel gear in a gear tooth matching mode, the second bevel gear is installed on the transverse shaft, two ends of the transverse shaft are connected with the side wall of the transfer box through bearings, the outer wall of the transverse shaft is connected with the round roller in a key matching mode, the conveying belt is connected to the outer wall of the round roller, the guide frame is arranged at the edge of the conveying belt, the guide frame is fixed on the transfer box through screws, and the transfer box is also connected with one end;

the centralized assembly comprises an air pipe, a material blocking cover, a fan and a material carrying trolley, the bottom end of the air pipe is connected with a conveying belt, the material blocking cover is installed at the top end of the air pipe, the fan is installed at the top end of an inner cavity of the material blocking cover, and the material carrying trolley with universal wheels is arranged below the material blocking cover.

Preferably, the cross section of the inner wall of the sheath is semicircular.

Preferably, a rectangular opening is formed in the square cover, and the square cover is located right above the conveying belt.

Preferably, the sheath is arranged on two sides of the blanking table.

Preferably, the bottom surface of the fan is provided with a ventilating separation net.

Preferably, the surface of the conveying belt is provided with uniformly distributed strip-shaped convex grooves, and the conveying belt is a member made of polyurethane rubber.

Preferably, the material receiving assemblies are arranged in two groups, and the material receiving assemblies are arranged in parallel.

Compared with the prior art, the beneficial effects of the utility model are as follows:

the numerical control gantry drill material safety recovery device comprises two groups of parallel material receiving assemblies which are symmetrically arranged at two ends of a gantry drill blanking position, wherein the blanking of the gantry drill falls into the material receiving assemblies, the material receiving assemblies uniformly collect the blanking, a transverse motor drives an extension shaft to rotate, the extension shaft drives a rotary sheet to rotate, the rotary sheet pushes the blanking to a square cover and enables the blanking to fall onto a conveying belt in a transfer assembly, strip-shaped convex grooves which are uniformly distributed are formed in the surface of the conveying belt, the blanking with residual temperature cannot be damaged when falling onto the conveying belt, the rotating conveying belt can push the blanking to one side well, a fan is electrified to generate air flow, the blanking on the conveying belt can be sucked into an air pipe and finally falls onto a material carrying trolley, the blanking can be collected at one time well, and not only can the accumulated blanking of a processing area be effectively reduced, meanwhile, the collected blanking can be further utilized, and unnecessary resource waste is avoided.

Drawings

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

FIG. 2 is a schematic structural section view of a transfer module according to the present invention;

FIG. 3 is a schematic structural view of the concentrating assembly of the present invention;

FIG. 4 is a partially enlarged schematic view of the structure of the material receiving assembly of the present invention;

fig. 5 is a schematic diagram of the position of the protruding shaft according to the present invention.

In the figure: 1. a material receiving assembly; 11. a sheath; 12. an end-block; 13. rotating the sheet; 14. a transverse motor; 15. an end plate; 16. an extension shaft; 17. a square cover; 2. a transfer assembly; 21. a vertical motor; 22. a transfer box; 23. a guide frame; 24. a conveyor belt; 25. a round roller; 26. a first bevel gear; 27. a second bevel gear; 28. a horizontal axis; 3. a concentration component; 31. an air duct; 32. a material blocking cover; 33. a fan; 34. a material loading trolley.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the numerical control gantry drill material safety recovery device comprises a material receiving component 1, a transferring component 2 and a centering component 3, wherein the material receiving component 1 comprises two groups, the two groups of material receiving components 1 are arranged in parallel, the two groups of material receiving components 1 arranged in parallel are symmetrically arranged at two ends of a gantry drill blanking position, the gantry drill blanking can fall into the material receiving component 1, the material receiving component 1 uniformly collects the blanking, one end of the material receiving component 1 is connected with the transferring component 2, one side of the transferring component 2 is provided with the centering component 3, the material receiving component 1 comprises a sheath 11, an end block 12, a rotary sheet 13, a transverse motor 14, an end plate 15, an extension shaft 16 and a square cover 17, a rectangular opening is arranged on the square cover 17, the square cover 17 is positioned right above a conveying belt 24, the blanking on the sheath 11 falls from the square cover 17 and falls onto the conveying belt 24, the square cover 17 is arranged at one end of the, the two ends of the sheath 11 are fixedly welded with end plates 15, the end plates 15 are connected with a transverse motor 14 through bolts, an output end of the transverse motor 14 is provided with an extension shaft 16, the extension shaft 16 penetrates through the end plates 15, the extension shaft 16 is connected with one end of a rotary piece 13, the other end of the rotary piece 13 is provided with a cylindrical end block 12, the end block 12 is movably connected with the inner wall of the sheath 11, the inner wall of the sheath 11 is also movably connected with the rotary piece 13, the sheath 11 is arranged on two sides of a blanking table, the cross section of the inner wall of the sheath 11 is semicircular, the transverse motor 14 drives the extension shaft 16 to rotate, the extension shaft 16 drives the rotary piece 13 to rotate, the rotary piece 13 in rotation pushes blanking to a square cover 17 and enables the blanking to fall on the transfer component 2, and the transfer component 2 is.

The transfer component 2 comprises a vertical motor 21, a transfer box 22, a guide frame 23, a conveying belt 24, a round roller 25, a first bevel gear 26, a second bevel gear 27 and a transverse shaft 28, wherein the vertical motor 21 is installed on the transfer box 22, the first bevel gear 26 is installed at the output end of the vertical motor 21, the first bevel gear 26 is movably connected with the second bevel gear 27 in a gear-tooth matching mode, the second bevel gear 27 is installed on the transverse shaft 28, two ends of the transverse shaft 28 are connected with the side wall of the transfer box 22 through bearings, the outer wall of the transverse shaft 28 is connected with the round roller 25 in a key matching mode, the conveying belt 24 is connected at the outer wall of the round roller 25, strip-shaped convex grooves are uniformly distributed on the surface of the conveying belt 24, the conveying belt 24 is made of polyurethane rubber, the conveying belt 24 made of polyurethane rubber is wear-resistant and high-temperature-resistant, and the residual-temperature-carrying blanking falls on the conveying belt 24 and cannot damage the conveying, meanwhile, the strip-shaped convex grooves in the conveying belt 24 can well push the blanking to one side, a guide frame 23 is arranged at the edge of the conveying belt 24, the guide frame 23 is fixed on the transfer box 22 through screws, and the transfer box 22 is further connected with one end of the concentration assembly 3.

The centralized assembly 3 comprises an air pipe 31, a material blocking cover 32, a fan 33 and a material carrying trolley 34, the bottom end of the air pipe 31 is connected with a conveying belt 24, the material blocking cover 32 is installed at the top end of the air pipe 31, the fan 33 is installed at the top end of an inner cavity of the material blocking cover 32, a ventilating and isolating net is installed at the bottom surface of the fan 33, the phenomenon that blanking enters the fan 33 is avoided, the material carrying trolley 34 with universal wheels is configured below the material blocking cover 32, the fan 33 is electrified to generate air flow, and the blanking on the conveying belt 24 can be sucked into the air pipe 31 and finally falls onto the material carrying trolley 34.

The numerical control gantry drill material safety recovery device comprises two groups of material receiving assemblies 1, wherein the two groups of material receiving assemblies 1 are arranged in parallel, the two groups of material receiving assemblies 1 which are arranged in parallel are symmetrically arranged at two ends of a material falling position of a gantry drill, the falling material of the gantry drill can fall into the material receiving assemblies 1, the material receiving assemblies 1 uniformly collect the falling material, sheaths 11 are arranged at two sides of a material falling platform, the cross section of the inner wall of each sheath 11 is semicircular, a transverse motor 14 drives an extension shaft 16 to rotate, the extension shaft 16 drives a rotary sheet 13 to rotate, the rotary sheet 13 pushes the falling material to a square cover 17 and enables the falling material to fall onto a transfer assembly 2, the falling material on each sheath 11 falls from the square cover 17 and falls onto a conveying belt 24, strip-shaped convex grooves which are uniformly distributed are formed in the surface of the conveying belt 24, the falling material with residual temperature cannot damage the conveying belt 24, and the strip-shaped convex grooves on the conveying belt 24 can push the falling material to one side well, the bottom surface department of fan 33 installs ventilative partition net, avoids the blanking to get into inside fan 33, and fan 33 circular telegram to produce the air current, can inhale tuber pipe 31 with the blanking on the conveyor belt 24 in and fall on the material dolly 34 that carries at last, just so can be fine once only collect the longmen brill blanking, can not only effectively reduce the processing region blanking and pile up, and the blanking after collecting can obtain further utilization simultaneously, avoids unnecessary wasting of resources.

In summary, the following steps: the numerical control gantry drill material safety recovery device comprises two groups of parallel material receiving assemblies 1 which are symmetrically arranged at two ends of a gantry drill blanking position, the blanking of the gantry drill can fall into the material receiving assemblies 1, the material receiving assemblies 1 uniformly collect the blanking, a transverse motor 14 drives an extension shaft 16 to rotate, the extension shaft 16 drives a rotary sheet 13 to rotate, the rotary sheet 13 pushes the blanking to a square cover 17 and enables the blanking to fall onto a conveying belt 24 in a transfer assembly 2, strip-shaped convex grooves which are uniformly distributed are formed in the surface of the conveying belt 24, the blanking with residual temperature cannot be damaged when falling onto the conveying belt 24, meanwhile, the rotating conveying belt 24 can push the blanking to one side well, a fan 33 is electrified to generate air flow, the blanking on the conveying belt 24 can be sucked into an air pipe 31 and finally falls onto a material carrying trolley 34, and the blanking of the gantry drill can be collected well at one time, the blanking accumulation in the processing area can be effectively reduced, meanwhile, the collected blanking can be further utilized, and unnecessary resource waste is avoided.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. Numerical control gantry drill material safety recovery device, including receiving material subassembly (1), transporting subassembly (2) and concentrated subassembly (3), its characterized in that: the one end of receiving material subassembly (1) is connected and is transported subassembly (2), one side of transporting subassembly (2) is equipped with and concentrates subassembly (3), receives material subassembly (1) including sheath (11), end block (12), revolves piece (13), horizontal motor (14), end plate (15), projecting shaft (16) and square cover (17), the one end at sheath (11) is installed to square cover (17), and the both ends of sheath (11) all welded fastening have end plate (15), and end plate (15) pass through bolted connection horizontal motor (14), projecting shaft (16) are installed to the output of horizontal motor (14), and projecting shaft (16) run through end plate (15), and projecting shaft (16) are connected the one end of revolving piece (13), and end block (12) that are cylindric are installed to the other end of revolving piece (13), end block (12) and the inner wall swing joint of sheath (11), the inner wall of sheath (11) still with revolving piece (13) swing joint, a transfer component (2) is arranged obliquely below the sheath (11);

the transfer assembly (2) comprises a vertical motor (21), a transfer box (22), a guide frame (23), a conveying belt (24), a round roller (25), a first bevel gear (26), a second bevel gear (27) and a transverse shaft (28), wherein the vertical motor (21) is installed on the transfer box (22), the first bevel gear (26) is installed at the output end of the vertical motor (21), the first bevel gear (26) is movably connected with the second bevel gear (27) in a gear-tooth fit mode, the second bevel gear (27) is installed on the transverse shaft (28), the two ends of the transverse shaft (28) are connected with the side wall of the transfer box (22) through bearings, the outer wall of the transverse shaft (28) is connected with the round roller (25) in a key-fit mode, the conveying belt (24) is connected at the outer wall of the round roller (25), the guide frame (23) is arranged at the edge of the conveying belt (24), and the guide frame (23) is fixed on the transfer box (22, the transfer box (22) is also connected with one end of the concentration component (3);

concentrate subassembly (3) including tuber pipe (31), material blocking cover (32), fan (33) and year material dolly (34), conveyor belt (24) are connected to the bottom of tuber pipe (31), and material blocking cover (32) are installed on the top of tuber pipe (31), and fan (33) are installed to the inner chamber top department of material blocking cover (32), and the below of material blocking cover (32) disposes from year material dolly (34) of taking the universal wheel.

2. The numerical control gantry drill material safety recovery device of claim 1, characterized in that: the cross section of the inner wall of the sheath (11) is semicircular.

3. The numerical control gantry drill material safety recovery device of claim 1, characterized in that: a rectangular opening is formed in the square cover (17), and the square cover (17) is located right above the conveying belt (24).

4. The numerical control gantry drill material safety recovery device of claim 1, characterized in that: the sheath (11) is arranged on two sides of the blanking table.

5. The numerical control gantry drill material safety recovery device of claim 1, characterized in that: and a ventilating separation net is arranged on the bottom surface of the fan (33).

6. The numerical control gantry drill material safety recovery device of claim 1, characterized in that: the surface of the conveying belt (24) is provided with uniformly distributed strip-shaped convex grooves, and the conveying belt (24) is a member made of polyurethane rubber.

7. The numerical control gantry drill material safety recovery device of claim 1, characterized in that: the material receiving assemblies (1) are divided into two groups, and the two groups of material receiving assemblies (1) are arranged in parallel.

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