CN220496775U - Anti-overflow plating device of coating machine - Google Patents

Abstract

The utility model discloses an anti-overflow plating device of a film plating machine, which comprises a plurality of horizontally arranged mounting crossbearers, wherein two side rails are respectively and horizontally fixedly connected to the bottom surfaces of two ends of each mounting crossbearer, two first dovetail sliding grooves are respectively formed in the bottom surfaces of the two side rails, two first dovetail sliding blocks are respectively and horizontally connected in the first dovetail sliding grooves in a sliding manner, two ends of the top surface of each transverse rail are respectively and fixedly connected to the bottom ends of the two first dovetail sliding blocks, a second dovetail sliding groove is horizontally formed in the top surface of each transverse rail, a second dovetail sliding block is horizontally and slidingly connected in each second dovetail sliding groove, and an oiling component is fixedly connected on each second dovetail sliding block. According to the utility model, the side rail is utilized to drive the oiling component to move in one horizontal direction, and the transverse rail is utilized to drive the oiling component to move in the other horizontal direction, so that the adjustment of any horizontal position of the oiling component is realized, the manual hand-held operation is replaced, the automation degree is higher, and the use is more convenient.

Description

Anti-overflow plating device of coating machine

Technical Field

The utility model relates to the technical field of vacuum coating equipment, in particular to an overflow-preventing coating device of a coating machine.

Background

Vacuum coating refers to a method of forming a thin film by heating a metal or nonmetal material under high vacuum to evaporate and condense the material on the surface of a plating member (metal, semiconductor or insulator). For example, vacuum aluminizing, vacuum chromeplating and the like can cause overflow plating phenomena in the vacuum plating film, namely, the film is plated at the position of the product which does not need to be plated, in order to put the overflow plating phenomena, a mechanical shielding method or a vacuum oil shielding method is mainly adopted at present, corresponding shielding jigs are required to be prepared according to the requirements of the product, jigs aiming at different products are different, special customization is required, the difficulty coefficient is relatively large, the vacuum oil shielding method is to cover and shield the position of the product which does not need to be plated by adopting high-temperature-resistant vacuum oil liquid, the vacuum oil is washed off after plating is finished, oiling can be carried out according to the requirements of the product, the difficulty is smaller, and therefore, the overflow plating preventing device which adopts the vacuum oil shielding at present has the following defects:

the current vacuum oil shielding device is an oiler, can not rely on self-adjusting position, needs manual handheld oiling when using, and degree of automation is low, and manpower consumption is big, and is not practical enough.

Therefore, we propose an overflow-preventing device of a coating machine for solving the above problems.

Disclosure of Invention

The utility model aims to provide an overflow-preventing device of a coating machine, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a coating machine anti-overflow plates device, includes a plurality of horizontal arrangement's installation crossbearer, a plurality of installation crossbearer both ends bottom surface respectively two side rails of horizontal rigid coupling, two first dovetails spouts are seted up respectively to the side rail bottom surface, two respectively horizontal sliding connection two first dovetails sliders in the first dovetails spout, two respectively rigid coupling crossbearer top surface both ends in first dovetails slider bottom, the second dovetails spout is seted up to crossbearer top surface level, horizontal sliding connection second dovetails slider in the second dovetails spout, rigid coupling oiling subassembly on the second dovetails slider.

Preferably, the oiling component comprises a bottom plate fixedly connected to the bottom surface of the second dovetail sliding block, one side of the bottom plate is vertically fixedly connected with a side plate, one side of the side plate, far away from the bottom plate, is horizontally fixedly connected with a transverse plate, the transverse plate is fixedly embedded with a small-sized electric cylinder, and the bottom end of the small-sized electric cylinder is fixedly connected with a lifting table.

Preferably, the bottom surface of the lifting platform is fixedly embedded with an oil inlet bin, the bottom surface of the oil inlet bin is fixedly connected and communicated with a plurality of drip openings, the side wall of the oil inlet bin is fixedly connected and communicated with an oil inlet pipe, the free end of the oil inlet pipe is fixedly connected and communicated with one end of a corrugated hose, and the other end of the corrugated hose is fixedly connected and communicated with an interface.

Preferably, the lifting platform bottom surface is provided with spacing frame, four posts are inserted in spacing frame top surface four corners department vertical fixation, post top rigid coupling screw thread post is inserted, four jacks are seted up perpendicularly respectively in lifting platform four corners, post grafting jack, screw thread post threaded connection hexagon nut.

Preferably, the two side rail end parts are horizontally fixedly connected with a power rod, the first dovetail sliding groove is rotationally connected with a screw rod, a threaded sleeve is fixedly connected in the first dovetail sliding groove, the screw rod is in threaded connection with the threaded sleeve, the central position inside the power rod is fixedly connected with a servo double-shaft gear motor, two rotating shaft ends of the servo double-shaft gear motor are fixedly connected with two transmission shafts respectively, two transmission shaft end parts are fixedly connected with two drive bevel gears respectively, the screw rod end parts are positioned in the power rod and fixedly connected with driven bevel gears, the drive bevel gears are in meshed connection with the driven bevel gears, two first corrugated covers are fixedly connected between two sides of the bottom surface of the first dovetail sliding groove and two guide sliding rods are horizontally fixedly connected in the first dovetail sliding groove, two guide sliding holes are horizontally formed in the first dovetail sliding groove, and the guide sliding rods are in sliding sleeve connection with the inner sides of the guide sliding holes.

Preferably, the transverse rail is located two wheel grooves are respectively formed in two end positions of the second dovetail sliding groove, the two wheel grooves are respectively connected with the driving pulley and the driven pulley in a rotating mode, the driving pulley and the driven pulley are sleeved with a synchronous belt, a through hole is horizontally formed in the second dovetail sliding block, one strand of the synchronous belt penetrates through the through hole, the other strand of the synchronous belt is fixedly connected with the second dovetail sliding block, two second corrugated covers are fixedly connected between two sides of the bottom surface of the second dovetail sliding block and two sides of the second dovetail sliding groove, one end side wall of the transverse rail is fixedly connected with a servo speed reducing motor, and the rotating shaft end of the servo speed reducing motor is fixedly connected with the rotating shaft of the driving pulley.

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

according to the utility model, the side rail is utilized to drive the oiling component to move in one horizontal direction, and the transverse rail is utilized to drive the oiling component to move in the other horizontal direction, so that the adjustment of any horizontal position of the oiling component is realized, the manual hand-held operation is replaced, the automation degree is higher, and the use is more convenient.

Drawings

FIG. 1 is a schematic diagram of a main structure of a first embodiment of the present utility model;

FIG. 2 is a schematic view showing a cross-sectional structure of side rails in the first and second embodiments of the present utility model;

FIG. 3 is a schematic view showing a cross-sectional structure of a rail in a first and second embodiment of the present utility model;

fig. 4 is a schematic view of a cut-away exploded view of a oiling station in accordance with a second embodiment of this utility model.

In the figure: 1. installing a transverse frame; 2. a side rail; 3. a transverse rail; 4. an oiling assembly; 21. the first dovetail chute; 22. a first dovetail slide; 23. a power lever; 24. a screw rod; 25. a threaded sleeve; 26. a servo double-shaft speed reducing motor; 27. a transmission shaft; 28. a drive bevel gear; 29. a driven bevel gear; 210. a first bellows; 211. a guide slide bar; 212. a guide slide hole; 31. the second dovetail groove; 32. a second dovetail slide; 33. wheel grooves; 34. a driving pulley; 35. a driven pulley; 36. a synchronous belt; 37. a through port; 38. a servo gear motor; 39. a second corrugated cover; 41. a bottom plate; 42. a side plate; 43. a cross plate; 44. a small electric cylinder; 45. a lifting table; 46. an oil inlet bin; 47. a drop mouth; 48. an oil inlet pipe; 49. a corrugated hose; 410. an interface; 411. a limit frame; 412. inserting a column; 413. a threaded column; 414. a jack; 415. a hexagonal nut.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1:

referring to fig. 1-3, the present utility model provides a technical solution: the utility model provides a coating machine anti-overflow plating device, including a plurality of horizontal arrangement's installation crossbearer 1, installation crossbearer 1 is used for installing this device in required position, two side rails 2 are respectively horizontal rigid coupling in a plurality of installation crossbearer 1 both ends bottom surfaces, two first forked tail spouts 21 are seted up respectively to two side rail 2 bottom surfaces, two first forked tail sliders 22 of horizontal sliding connection in two first forked tail spouts 21 respectively, the both ends of rail 3 top surfaces of two first forked tail sliders 22 rigid coupling respectively, second forked tail spout 31 are seted up to rail 3 top surface level, the second forked tail slider 32 is connected in the horizontal smooth motion in the second forked tail spout 31, rigid coupling oiling subassembly 4 on the second forked tail slider 32, utilize side rail 2 to drive oiling subassembly 4 and remove in one direction of level, utilize rail 3 to drive oiling subassembly 4 and remove in another direction of level, realize oiling subassembly 4's level optional position's adjustment, manual hand-held operation has been replaced, degree of automation is higher, it is more convenient to use.

Example 2:

referring to fig. 2-4, in a second embodiment of the present utility model, based on the previous embodiment, the oiling assembly 4 includes a bottom plate 41 fixedly connected to the bottom surface of the second dovetail slide 32, a side plate 42 is vertically fixedly connected to one side of the bottom plate 41, a horizontal plate 43 is horizontally fixedly connected to one side of the side plate 42 away from the bottom plate 41, the horizontal plate 43 is fixedly embedded with a small electric cylinder 44, and a lifting platform 45 is fixedly connected to the bottom end of the small electric cylinder 44.

The bottom surface of the lifting platform 45 is fixedly embedded with the oil inlet bin 46, the bottom surface of the oil inlet bin 46 is fixedly connected and communicated with a plurality of drip openings 47, the side wall of the oil inlet bin 46 is fixedly connected and communicated with an oil inlet pipe 48, the free end of the oil inlet pipe 48 is fixedly connected and communicated with one end of a corrugated hose 49, the other end of the corrugated hose 49 is fixedly connected and communicated with an interface 410, and the interface 410 is used for connecting oil supply equipment, supplying vacuum oil into the oil inlet bin 46 and covering by dripping out from the drip openings 47.

The lifting platform 45 bottom surface is provided with spacing frame 411, four posts 412 of vertical rigid coupling in spacing frame 411 top surface four corners department, posts 412 top rigid coupling threaded column 413, four jack 414 are seted up perpendicularly to lifting platform 45 four corners punishment do not, posts 412 peg graft jack 414, threaded column 413 threaded connection hex nut 415, spacing frame 411 is used for restricting the flow area of vacuum oil, confirms and shields the position, can change spacing frame 411 through demolising hex nut 415, adapts to different shielding demands.

The end parts of the two side rails 2 are horizontally fixedly connected with a power rod 23, a screw rod 24 is rotationally connected with a first dovetail sliding groove 21, a threaded sleeve 25 is fixedly connected with a first dovetail sliding groove 22, the screw rod 24 is in threaded connection with the threaded sleeve 25, the central position inside the power rod 23 is fixedly connected with a servo double-shaft speed reduction motor 26, two rotating shaft ends of the servo double-shaft speed reduction motor 26 are respectively fixedly connected with two transmission shafts 27, the end parts of the two transmission shafts 27 are respectively fixedly connected with two driving bevel gears 28, the end parts of the screw rod 24 are positioned in the power rod 23 and fixedly connected with a driven bevel gear 29, the driving bevel gears 28 are in meshed connection with the driven bevel gears 29, two first corrugated covers 210 are fixedly connected between the two sides of the bottom surface of the first dovetail sliding groove 22 and the two sides of the first dovetail sliding groove 21, two guide sliding rods 211 are horizontally connected with the first dovetail sliding groove 22, two guide sliding holes 212 are horizontally formed in the guide sliding rods 211 in a sleeved mode, and the inner sides of the guide sliding holes 212 are slidingly sleeved, the servo double-shaft speed reduction motor 26 is used for driving the two screw rods 24 to rotate, and the horizontal position of the oiling assembly 4 is adjusted.

The transverse rail 3 is positioned at two ends of the second dovetail sliding groove 31 and is respectively provided with two wheel grooves 33, the two wheel grooves 33 are respectively connected with a driving pulley 34 and a driven pulley 35 in a rotating way, a synchronous belt 36 is sleeved on the driving pulley 34 and the driven pulley 35, a through hole 37 is horizontally formed in the second dovetail sliding block 32, one strand of the synchronous belt 36 passes through the through hole 37, the other strand of the synchronous belt is fixedly connected with the second dovetail sliding block 32, two second corrugated covers 39 are fixedly connected between two sides of the bottom surface of the second dovetail sliding block 32 and two sides of the second dovetail sliding groove 31, one end side wall of the transverse rail 3 is fixedly connected with a servo speed reducing motor 38, the rotating shaft end of the servo speed reducing motor 38 is fixedly connected with the rotating shaft of the driving pulley 34, and the synchronous belt 36 is driven to work by the servo speed reducing motor 38, so that the horizontal position of the oiling component 4 is driven.

Example 3:

referring to fig. 1-4, in a third embodiment of the present utility model, based on the two embodiments, when the present utility model is used, an oil supply device is connected to an interface 410 in an oiling component 4, a limiting frame 411 with a corresponding size and shape is selected according to practical situations, and is installed on the oiling component 4, then a material is placed under the apparatus, the oiling component 4 is moved to a position to be shielded through a side rail 2 and a transverse rail 3, then a small-sized electric cylinder 44 is started to enable the limiting frame 411 to press the material, and vacuum oil flows out from a drop 47 to shield the surface of the material, and the operation is repeated until the required position is completely shielded, and then the material can be fed into a vacuum coater for coating, and after coating, the material is washed, and overflow plating phenomenon can be prevented; according to the utility model, the side rail 2 is utilized to drive the oiling component 4 to move in one horizontal direction, and the transverse rail 3 is utilized to drive the oiling component 4 to move in the other horizontal direction, so that the adjustment of any horizontal position of the oiling component 4 is realized, the manual handheld operation is replaced, the automation degree is higher, and the use is more convenient.

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

Claims (6)

1. The utility model provides a coating machine anti-overflow plates device, includes a plurality of horizontal arrangement's installation crossbearer (1), its characterized in that:

a plurality of installation crossbearer (1) both ends bottom surface respectively horizontal rigid coupling two curb rails (2), two first forked tail spout (21) are seted up respectively to curb rail (2) bottom surface, two respectively horizontal sliding connection two first forked tail sliders (22) in first forked tail spout (21), two respectively rigid coupling crossbearer (3) top surface both ends in first forked tail slider (22) bottom, second forked tail spout (31) are seted up to crossbearer (3) top surface level, water smoothness moves in second forked tail spout (31) connects second forked tail slider (32), rigid coupling oiling subassembly (4) on second forked tail slider (32).

2. The anti-overflow plating device of a coating machine according to claim 1, wherein: the oiling component (4) comprises a bottom plate (41) fixedly connected to the bottom surface of the second dovetail sliding block (32), a side plate (42) is vertically fixedly connected to one side of the bottom plate (41), a transverse plate (43) is horizontally fixedly connected to one side of the side plate (42) away from the bottom plate (41), a small electric cylinder (44) is fixedly embedded in the transverse plate (43), and a lifting table (45) is fixedly connected to the bottom end of the small electric cylinder (44).

3. The anti-overflow plating device of a coating machine according to claim 2, wherein: the lifting platform (45) is fixedly embedded with the oil inlet bin (46), the bottom surface of the oil inlet bin (46) is fixedly connected and communicated with a plurality of drip ports (47), the side wall of the oil inlet bin (46) is fixedly connected and communicated with the oil inlet pipe (48), the free end of the oil inlet pipe (48) is fixedly connected and communicated with one end of the corrugated hose (49), and the other end of the corrugated hose (49) is fixedly connected and communicated with the interface (410).

4. The anti-overflow plating device of a coating machine according to claim 2, wherein: the lifting platform (45) bottom surface is provided with spacing frame (411), four inserted posts (412) of perpendicular rigid coupling in spacing frame (411) top surface four corners department, inserted post (412) top rigid coupling screw thread post (413), four jack (414) are seted up perpendicularly in lifting platform (45) four corners punishment do not, inserted post (412) are pegged graft jack (414), screw thread post (413) threaded connection hex nut (415).

5. The anti-overflow plating device of a coating machine according to claim 1, wherein: two side rail (2) tip horizontal rigid coupling power pole (23), lead screw (24) are connected in first forked tail spout (21) internal rotation, rigid coupling screw sleeve (25) in first forked tail slider (22), lead screw (24) threaded connection screw sleeve (25), the inside central point of power pole (23) puts rigid coupling servo biax gear motor (26), two pivot ends of servo biax gear motor (26) rigid coupling respectively two transmission shafts (27), two transmission shaft (27) tip rigid coupling two initiative bevel gears (28) respectively, lead screw (24) tip is located power pole (23) and rigid coupling driven bevel gear (29), initiative bevel gear (28) meshing is connected driven bevel gear (29), rigid coupling two first ripple cover (210) between first forked tail slider (22) bottom surface both sides and first forked tail spout (21) both sides, two direction slide bar (211) are offered to the level on first forked tail slider (22) and are led slide bar (212), direction slide bar (212) are cup jointed to direction slide.

6. The anti-overflow plating device of a coating machine according to claim 1, wherein: the transverse rail (3) is located at two ends of the second dovetail sliding groove (31) and is provided with two wheel grooves (33) respectively, the two wheel grooves (33) are respectively connected with a driving pulley (34) and a driven pulley (35) in a rotating mode, a synchronous belt (36) is sleeved on the driving pulley (34) and the driven pulley (35), a through hole (37) is horizontally formed in the second dovetail sliding block (32), one strand of the synchronous belt (36) penetrates through the through hole (37) and is fixedly connected with the second dovetail sliding block (32) in another strand, two second corrugated covers (39) are fixedly connected between two sides of the bottom surface of the second dovetail sliding block (32) and two sides of the second dovetail sliding groove (31), one end side wall of the transverse rail (3) is fixedly connected with a servo speed reducing motor (38), and the rotating shaft end of the servo speed reducing motor (38) is fixedly connected with the rotating shaft of the driving pulley (34).