CN111567962B

CN111567962B - Latex glove dip-coating device

Info

Publication number: CN111567962B
Application number: CN202010465094.5A
Authority: CN
Inventors: 尚毅
Original assignee: Nanjing Ruirun New Material Technology Co ltd
Current assignee: Nanjing Ruirun New Material Technology Co.,Ltd.
Priority date: 2020-05-28
Filing date: 2020-05-28
Publication date: 2022-03-18
Anticipated expiration: 2040-05-28
Also published as: CN111567962A

Abstract

The invention relates to the field of latex gloves, in particular to a latex glove dip-coating device. The invention aims to provide a dipping device for latex gloves. A latex glove dip-coating device comprises support legs, a dip-coating treatment device, a chamber door, a liquid level extrusion lifting device and a glove transfer dip-coating device; the top ends of the support legs are connected with the dip-coating treatment device through bolts; and welding the right top of the dip-coating treatment device with the bearing plate. The invention overcomes the buoyancy effect of the dip-coating liquid, so that the gloves can completely enter the dip-coating liquid, and complete dip-coating is realized; the gloves are squeezed to force the inner layer dip-coating liquid to move upwards, so that the dip-coating liquid can dip-coat the inner surface of the whole glove, and the effect of complete dip-coating can be achieved only by using half or less dip-coating liquid.

Description

Latex glove dip-coating device

Technical Field

The invention relates to the field of latex gloves, in particular to a latex glove dip-coating device.

Background

The latex glove is one of gloves, which is different from general gloves and is made of latex. Can be used in the industries of families, industry, medical treatment, beauty treatment and the like, and is a necessary hand protection article. The latex gloves are processed by adopting natural latex and other fine additives, and the products are comfortable to wear after being subjected to special surface treatment, and have wide application in industrial and agricultural production, medical treatment and daily life.

In order to strengthen the function of the glove and enable the glove to adapt to certain special environments, such as electromagnetic resistance and radiation resistance, the common method is to immerse the glove into the dip-coating liquid and dip-coat a layer of special material film on the surface of the glove, but the density of the general dip-coating liquid is greater than that of the glove, so that the glove can not be completely immersed into the dip-coating liquid due to strong buoyancy, the dip-coating effect of the outer surface of the glove is poor, and the glove cannot be completely immersed to meet the requirement; the gloves are also dipped and coated inside so as to improve the internal lubrication degree and facilitate wearing, but in order to dip and coat the inner surface of the gloves completely, the general method can select the whole gloves to be filled with the dip coating liquid for dip coating, the dip coating can be completed only by consuming a part of the dip coating liquid, and most of the dip coating liquid is wasted.

Therefore, at present, a device which can assist the glove to overcome buoyancy of the dip-coating liquid, so that the glove can be completely immersed in the dip-coating liquid to achieve the purpose of complete dip-coating, and meanwhile, the dip-coating of the whole inner surface can be realized only by consuming a small amount of the dip-coating liquid, so that the consumption of the dip-coating liquid on the inner surface is reduced, and the problems that the glove cannot be completely immersed in the dip-coating liquid due to strong buoyancy of the glove in the prior art, the dip-coating effect of the outer surface of the glove is poor, and the complete dip-coating cannot be achieved to meet the requirements are overcome; the whole glove is filled with the dip-coating liquid for dip-coating, only a part of the dip-coating liquid is consumed actually, and most of the dip-coating liquid is wasted.

Disclosure of Invention

The invention aims to overcome the defects that the gloves in the prior art cannot be thoroughly dipped into the dip-coating liquid due to strong buoyancy, so that the dip-coating effect of the outer surfaces of the gloves is poor, and the gloves cannot be thoroughly dipped to meet the requirements; the invention aims to solve the technical problem of providing a dipping and coating device for latex gloves, which has the defect that only a part of dipping and coating liquid is consumed and most of the dipping and coating liquid is wasted when the whole gloves are filled with the dipping and coating liquid for dipping and coating.

The invention is achieved by the following specific technical means:

a latex glove dip-coating device comprises support legs, a dip-coating treatment device, a support plate, a control screen, a top treatment chamber, a chamber door, a liquid level extrusion lifting device, a glove transfer dip-coating device, an arc top plate and an inner immersion nozzle; the top ends of the support legs are connected with the dip-coating treatment device through bolts; welding the right top of the dip-coating treatment device with the bearing plate; welding the top end of the dip-coating treatment device with the top treatment chamber; the right side of the top of the bearing frame plate is connected with the control screen; a chamber door is arranged on the inner side of the left middle bottom of the top treatment chamber; a liquid level extrusion lifting device is arranged on the left side of the inner bottom of the top treatment chamber, and the bottom end and the right middle part of the liquid level extrusion lifting device are connected with a dip-coating treatment device; the middle top part in the top treatment chamber is provided with a glove transferring dip-coating device, and the right bottom part of the glove transferring dip-coating device is connected with a dip-coating treatment device; the top end of the top treatment chamber is welded with the arc top plate; the front side of the right top in the top treatment chamber is connected with the inner immersion nozzle through a hack lever.

Furthermore, the dip-coating treatment device comprises an outer dip-coating cabin, a liquid guide pipe, a surface drying chamber, a pushing rod, a bottom outlet, a first friction wheel, a second friction wheel, a third friction wheel, a fourth friction wheel, a first bevel gear, a second bevel gear, a motor, a first transmission wheel, a second transmission wheel and fan blades; the right side of the outer dip-coated bilge is mutually spliced with the liquid conduit; welding the left side of the outer dip-coated bilge with a surface drying chamber; the middle right side of the inner top of the outer dip-coating cabin is connected with a first friction wheel through a connecting plate; the inner side of the left bottom of the surface drying chamber is sleeved with a pushing rod; the middle part of the bottom of the surface drying chamber is rotationally connected with the outlet at the bottom; the right lower side of the first friction wheel is in transmission connection with the second friction wheel; a third friction wheel is arranged on the right of the second friction wheel; the right upper side of the third friction wheel is in transmission connection with the fourth friction wheel; the right upper side of the fourth friction wheel is in transmission connection with the first bevel gear; the right front side of the first bevel gear is meshed with the second bevel gear; the left end axle center of the second bevel gear is in transmission connection with the motor; the right end axis of the second bevel gear is in transmission connection with the first transmission wheel; the bottom of the first driving wheel is in transmission connection with a second driving wheel; the left end axis of the second driving wheel is in transmission connection with the fan blade; the left side and the right side of the top of the outer dip-coating cabin are both connected with a top treatment chamber; the middle left rear side of the outer dip-coating cabin is connected with a liquid level extrusion lifting device; the left side of the bottom of the surface drying chamber is connected with the support legs; the left upper side of the first bevel gear is connected with a liquid level extrusion lifting device; the right end axle center of the first driving wheel is connected with the glove transferring and dip-coating device.

Furthermore, the liquid level extrusion lifting device comprises a first straight gear, a second straight gear, a first electric push rod, a third straight gear, a transmission disc, a transmission column, a first transmission frame, a sliding base, a sliding groove, a sliding rod, a sliding block, a height lifting rod, a height adjusting block, a second transmission frame, a piggy-back nail, a spring rod and a roller; the right upper side of the first straight gear is meshed with the second straight gear; the left side of the second straight gear is in transmission connection with the first electric push rod; the left upper side of the second straight gear is meshed with the third straight gear; the left lower side of the third straight gear is in transmission connection with the transmission disc; the front top of the transmission disc is welded with the transmission column; the outer surface of the transmission column is in transmission connection with the first transmission frame; the bottom end of the first transmission frame is welded with the sliding base; the right top of the first transmission frame is welded with the sliding rod through a connecting block; the bottom end of the sliding base is in sliding connection with the sliding chute; the middle part of the outer surface of the sliding rod is connected with the sliding block in a sliding way; the front middle part of the sliding block is welded with the high-low lifting rod; the right middle part of the sliding block is in transmission connection with the second transmission frame; the bottom ends of the high-low lifting rods are in sliding connection with the height adjusting blocks; the middle part in the second transmission frame is connected with the piggy-back nail; the rear right side of the second transmission frame is connected with the spring rod through a bolt; the front right side of the spring rod is in transmission connection with the roller; the right lower side of the first straight gear is connected with a first bevel gear; the bottom end of the sliding chute is connected with the outer dip-coating cabin; the rear end of the staple is connected with the top processing chamber.

Furthermore, the glove transferring and dip-coating device comprises a third bevel gear, a fourth bevel gear, a third driving wheel, a fourth driving wheel, a telescopic rod, a control panel, a cylinder, a fifth bevel gear, a sixth bevel gear, a seventh bevel gear, a screw rod, a driving block, a second electric push rod, a third electric push rod, a lifting plate, a funnel, a first electric clamp and a second electric clamp; the left top of the third bevel gear is meshed with the fourth bevel gear; the top of the fourth bevel gear is in transmission connection with a third transmission wheel; the left side of the third driving wheel is in transmission connection with the fourth driving wheel; the top end axis of the fourth driving wheel is in transmission connection with the telescopic rod; the bottom of the outer surface of the telescopic rod is sleeved with the control plate; the middle bottom of the outer surface of the telescopic rod is mutually inserted with the fifth bevel gear; the top of the outer surface of the telescopic rod is mutually inserted with the sixth bevel gear; the right side of the bottom of the control plate is connected with the air cylinder through a bolt; the left bottom of the sixth bevel gear is meshed with the seventh bevel gear; the left end axis of the seventh bevel gear is in transmission connection with the screw rod; the left side of the outer surface of the screw rod is in transmission connection with the transmission block; the left side of the bottom of the transmission block is connected with a second electric push rod through a bolt; the right side of the bottom of the transmission block is connected with a third electric push rod through a bolt; the bottom end of the second electric push rod is connected with the lifting plate through a bolt, and the right side of the top of the lifting plate is connected with a third electric push rod; the front side of the middle part of the top of the lifting plate is mutually inserted with the funnel; the front part of the left side of the bottom of the lifting plate is connected with a first electric clamp; the front part of the right side of the bottom of the lifting plate is connected with a second electric clamp; the left end axle center of the third bevel gear is connected with the first transmission wheel.

Furthermore, when the cylinder drives the control plate in a telescopic manner, the control plate drives the telescopic rod to enable the sixth bevel gear and the seventh bevel gear to be meshed with each other, the telescopic rod drives the sixth bevel gear to rotate, and the sixth bevel gear is meshed with and drives the seventh bevel gear; when the cylinder stretches out and draws back to drive the control plate, the control plate drives the telescopic rod to enable the fifth bevel gear and the seventh bevel gear to be meshed with each other, the telescopic rod drives the fifth bevel gear to rotate, the fifth bevel gear is meshed with the seventh bevel gear to drive the seventh bevel gear, and the seventh bevel gear is made to rotate in the opposite direction when being meshed with the sixth bevel gear to drive the seventh bevel gear; when the cylinder stretches out and draws back to drive the control panel, the control panel drives the telescopic rod to enable the fifth bevel gear and the sixth bevel gear not to be meshed with the seventh bevel gear at the same time, and the seventh bevel gear keeps static.

Furthermore, when the height adjusting block slides to contact with the highest point and the lowest point of the height adjusting block, the spring rod extends to the maximum length, and the roller reaches the lowest point and the highest point of the vertical height and does not contact with the inner wall of the top treatment chamber.

Furthermore, the rear end axle centers of the second friction wheel and the third friction wheel are connected with a straight gear, and the two straight gears are meshed with each other.

Compared with the prior art, the invention has the following beneficial effects:

the glove aims to solve the problems that in the prior art, the glove cannot be thoroughly immersed into the dip-coating liquid due to strong buoyancy, so that the dip-coating effect of the outer surface of the glove is poor, and the glove cannot be thoroughly dipped to meet the requirements; fill the dip-coating liquid with whole gloves are inside and carry out the dip-coating, have consumed partly dip-coating liquid in reality only, and most dip-coating liquid is all by the extravagant problem of falling, has designed dip-coating processing apparatus, liquid level extrusion elevating gear and gloves and has shifted dip-coating device.

The glove dipping and coating device has the advantages that the problem that the surface of the glove cannot be completely dipped and coated with a film due to the fact that the glove cannot completely enter dipping and coating liquid under the buoyancy action of the dipping and coating liquid and the final product performance cannot meet requirements is solved through a pulling method, and meanwhile, automatic quick air drying of the surface of the glove can be achieved.

The utility model discloses a dip-coating liquid, including the inlayer, the inlayer is soaked the coating liquid and is moved upwards, the liquid level extrusion elevating gear, utilize spring beam and cylinder extrusion to begin to extrude gloves from the bottom, utilize this kind of method to force inlayer to soak the coating liquid and move upwards, make the dip-coating liquid can dip-coat whole gloves internal surface, on the basis of accomplishing the whole internal surface of dip-coating, only need use half or less dip-coating liquid, dip-coating liquid consumption still less, the dip-coating cost is lower, the dip-coating waste liquid of production still less, the consumption of follow-up processing waste liquid still less, more environmental protection.

The glove transfer dip-coating device is used for realizing automatic left-right operation and up-down lifting of the hanging gloves, the dip-coating treatment device and the liquid level extrusion lifting device are matched to complete dip-coating and taking-out work of the inner surface and the outer surface of the gloves, manual work is replaced for glove transfer work, and work efficiency is improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a dip coating apparatus according to the present invention;

FIG. 3 is a schematic structural view of the liquid level squeezing and lifting device of the present invention;

FIG. 4 is a schematic view of the glove transfer dip-coating apparatus of the present invention;

fig. 5 is a left side view structural diagram of the chamber door of the present invention.

The labels in the figures are: 1-support foot, 2-dip coating treatment device, 3-support plate, 4-control screen, 5-top treatment chamber, 6-chamber door, 7-liquid level extrusion lifting device, 8-glove transfer dip coating device, 9-arc top plate, 10-inner dip coating nozzle, 201-outer dip coating cabin, 202-liquid guide pipe, 203-surface drying chamber, 204-push rod, 205-bottom outlet, 206-first friction wheel, 207-second friction wheel, 208-third friction wheel, 209-fourth friction wheel, 2010-first bevel gear, 2011-second bevel gear, 2012-motor, 2013-first driving wheel, 2014-second driving wheel, 2015-fan blade, 701-first straight gear, 702-second straight gear, 703-first electric push rod, 704-a third spur gear, 705-a transmission disc, 706-a transmission column, 707-a first transmission frame, 708-a sliding base, 709-a sliding chute, 7010-a sliding rod, 7011-a sliding block, 7012-a high-low lifting rod, 7013-a height adjusting block, 7014-a second transmission frame, 7015-a piggy-back nail, 7016-a spring rod, 7017-a roller, 801-a third bevel gear, 802-a fourth bevel gear, 803-a third transmission wheel, 804-a fourth transmission wheel, 805-a telescopic rod, 806-a control plate, 807-an air cylinder, 808-a fifth bevel gear, 809-a sixth bevel gear, 8010-a seventh bevel gear, 1-a screw rod, 8012-a transmission block, 8013-a second electric push rod, 8014-a third electric push rod, 8015-a lifting plate, 8016-a funnel, 8017-first powered clip, 8018-second powered clip.

Detailed Description

The invention is further described below with reference to the figures and examples.

Examples

A latex glove dip-coating device is shown in figures 1-5 and comprises a support leg 1, a dip-coating treatment device 2, a support frame plate 3, a control screen 4, a top treatment chamber 5, a chamber door 6, a liquid level extrusion lifting device 7, a glove transfer dip-coating device 8, an arc top plate 9 and an inner immersion nozzle 10; the top end of the support leg 1 is connected with the dip-coating treatment device 2 through a bolt; the right top of the dip-coating treatment device 2 is welded with the bearing plate 3; the top end of the dip coating treatment device 2 is welded with the top treatment chamber 5; the right side of the top of the bearing plate 3 is connected with the control screen 4; a chamber door 6 is arranged at the inner side of the left middle bottom part of the top treatment chamber 5; a liquid level extrusion lifting device 7 is arranged on the left side of the inner bottom of the top treatment chamber 5, and the bottom end and the right middle part of the liquid level extrusion lifting device 7 are connected with the dip-coating treatment device 2; a glove transferring and dip-coating device 8 is arranged at the middle top part in the top treatment chamber 5, and the right bottom part of the glove transferring and dip-coating device 8 is connected with the dip-coating treatment device 2; the top end of the top treatment chamber 5 is welded with the arc top plate 9; the right top front side in the top treatment chamber 5 is connected to an inner immersion nozzle 10 by means of a frame rod.

The working principle is as follows: during the use, install latex gloves dip-coating device in the place that needs to use earlier, external power supply, dip-coating processing apparatus 2 and the external liquid pipe 202 of interior immersion fluid spout 10, then open room door 6, fix pending latex gloves in gloves transfer dip-coating device 8 with the gesture that gloves back of the hand and gloves palm of the hand are towards left or towards the right, then be full of dip-coating liquid with dip-coating processing apparatus 2 inside, then through control panel 4 starting drive, gloves transfer dip-coating device 8 shifts gloves to interior immersion fluid spout 10 below right, then gloves transfer dip-coating device 8 is extension downwards, send gloves to dip-coating processing apparatus 2, draw gloves through dip-coating processing apparatus 2 simultaneously and make it overcome the buoyancy of dip-coating liquid, fully dip in the dip-coating liquid and carry out surface dip-coating. Gloves shift dip-coating device 8 and pull up gloves after dip-coating is accomplished, it is right-hand to make it be located liquid level extrusion elevating gear 7, then through interior immersion fluid spout 10 to the inside infusion liquid that plays different effects of gloves, but only need inject the half amount of infusion liquid of the inside volume of gloves can, after that, extrude elevating gear 7 through the liquid level and carry out the extrusion from bottom to top again to the gloves, rise inside infusion liquid level, make it can cover inside the gloves, can regard the inside dip-coating work of accomplishing of gloves after repeating several times. And finally, transferring the gloves back to the position where the gloves are initially hung by the glove transferring and dip-coating device 8, directly releasing the gloves to enable the gloves to fall into a container at the bottom of the dip-coating treatment device 2, quickly air-drying the surfaces of the gloves by the dip-coating treatment device 2, pushing the gloves out from the bottom after the air-drying for subsequent internal drying, and finally completing the dip-coating of the gloves. The device is simple to use, and can overcome the problems that when a common device is used for dip-coating the surface of a latex glove, the glove cannot be thoroughly immersed in dip-coating liquid due to buoyancy of the dip-coating liquid, so that the surface dip-coating is not thorough, and the performance improvement cannot completely meet the requirements; can carry out inside dip-coating immediately after accomplishing the surface dip-coating to only need consume the half dip-coating liquid measure of gloves internal volume, just can accomplish the dip-coating work of whole internal surface, general method is to fill the dip-coating liquid with gloves inside, and this device consumes the dip-coating liquid measure and only has half of general method, and the dip-coating liquid is utilized to the high efficiency, has reduced the dip-coating cost and environmental protection more, is worth using widely.

The dip-coating treatment device 2 comprises an outer dip-coating cabin 201, a liquid guide pipe 202, a surface drying chamber 203, a pushing rod 204, a bottom outlet 205, a first friction wheel 206, a second friction wheel 207, a third friction wheel 208, a fourth friction wheel 209, a first bevel gear 2010, a second bevel gear 2011, a motor 2012, a first driving wheel 2013, a second driving wheel 2014 and fan blades 2015; the right side of the bottom of the outer dip-coating cabin 201 is mutually inserted with the liquid conduit 202; the left side in the bottom of the outer dip coating cabin 201 is welded with the surface drying chamber 203; the middle right side of the inner top of the outer dip-coating cabin 201 is connected with a first friction wheel 206 through a connecting plate; the inner side of the left bottom of the surface drying chamber 203 is sleeved with a pushing rod 204; the middle of the bottom of the surface drying chamber 203 is rotatably connected with a bottom outlet 205; the right lower side of the first friction wheel 206 is in transmission connection with a second friction wheel 207; a third friction wheel 208 is arranged on the right of the second friction wheel 207; the upper right side of the third friction wheel 208 is in transmission connection with a fourth friction wheel 209; the right upper side of the fourth friction wheel 209 is in transmission connection with the first bevel gear 2010; the right front side of the first bevel gear 2010 is meshed with the second bevel gear 2011; the left end axis of the second bevel gear 2011 is in transmission connection with the motor 2012; the right end axis of the second bevel gear 2011 is in transmission connection with the first transmission wheel 2013; the bottom of the first driving wheel 2013 is in driving connection with a second driving wheel 2014; the axle center of the left end of the second transmission wheel 2014 is in transmission connection with the fan blade 2015; the top left side and the top right side of the external dip-coating cabin 201 are both connected with a top treatment chamber 5; the middle left rear side of the outer dip-coating cabin 201 is connected with a liquid level extrusion lifting device 7; the left side of the bottom of the surface drying chamber 203 is connected with the support leg 1; the left upper side of the first bevel gear 2010 is connected with a liquid level extrusion lifting device 7; the axle center of the right end of the first driving wheel 2013 is connected with a glove transferring and dip-coating device 8.

When the outer surface is dip-coated, the liquid conduit 202 is firstly used for filling the dip-coating liquid on the outer surface of the glove into the outer dip-coating cabin 201, the glove is then fed towards the centre of the mechanism consisting of the first friction wheel 206, the second friction wheel 207, the third friction wheel 208 and the fourth friction wheel 209, then the motor 2012 drives the second bevel gear 2011, the second bevel gear 2011 is meshed with and drives the first bevel gear 2010, the first bevel gear 2010 then drives the fourth friction wheel 209 to rotate, the fourth friction wheel 209 then drives the third friction wheel 208, the third friction wheel 208 drives the second friction wheel 207, finally the second friction wheel 207 drives the first friction wheel 206 to rotate, the four friction wheels jointly act with the surface of the latex glove to pull the glove into the dip-coating liquid, the buoyancy of the dip-coating liquid is overcome through the action of the friction wheel, so that the gloves can be fully immersed in the dip-coating liquid, the surfaces of the gloves can be fully dip-coated and coated, and the requirement of glove transformation is met. After finishing the dip-coating work of the inner and outer surfaces of the glove, the glove is thrown to the left side of the surface drying chamber 203, then the glove slides into the surface drying chamber 203, then the motor 2012 drives the first driving wheel 2013, the first driving wheel 2013 drives the second driving wheel 2014, then the second driving wheel 2014 drives the fan blades 2015, the rotating fan blades 2015 form wind flow to quickly air-dry the surface of the glove, the bottom outlet 205 is opened after air-drying, then the pushing rod 204 is pushed to the right, the glove with the air-dried surface is pushed out of the surface drying chamber 203 from the bottom outlet 205, and the glove is taken away for subsequent inner drying work. The device is simple to use, through mechanical transmission, can overcome through the method of dragging and dip-coat liquid buoyancy effect and lead to gloves to be difficult to thoroughly get into dip-coat liquid, cause the unable complete dip-coating tectorial membrane in gloves surface, final product performance can not reach the problem of requirement, can be accompanied simultaneously and realize automatic gloves surface and air-dry fast to the device can shift dip-coating device 8 with liquid level extrusion elevating gear 7 and gloves and form the linkage, is worth using widely.

The liquid level extrusion lifting device 7 comprises a first straight gear 701, a second straight gear 702, a first electric push rod 703, a third straight gear 704, a transmission disc 705, a transmission column 706, a first transmission frame 707, a sliding base 708, a sliding chute 709, a sliding rod 7010, a sliding block 7011, a high-low lifting rod 7012, a height adjusting block 7013, a second transmission frame 7014, a piggy-back nail 7015, a spring rod 7016 and a roller 7017; the upper right side of the first straight gear 701 is meshed with the second straight gear 702; the left side of the second spur gear 702 is in transmission connection with a first electric push rod 703; the upper left side of the second spur gear 702 is meshed with a third spur gear 704; the left lower side of the third straight gear 704 is in transmission connection with a transmission disc 705; the front top of the transmission disc 705 is welded with the transmission post 706; the outer surface of the transmission column 706 is in transmission connection with a first transmission frame 707; the bottom end of the first transmission frame 707 is welded with the sliding base 708; the right top of the first transmission frame 707 is welded with the sliding rod 7010 through a connecting block; the bottom end of the sliding base 708 is in sliding connection with the sliding chute 709; the middle part of the outer surface of the sliding rod 7010 is in sliding connection with the sliding block 7011; the front middle part of the sliding block 7011 is welded with a high-low lifting rod 7012; the right middle part of the sliding block 7011 is in transmission connection with a second transmission frame 7014; the bottom end of the high-low lifting rod 7012 is in sliding connection with the height adjusting block 7013; the inner middle part of the second transmission frame 7014 is connected with a piggyback nail 7015; the rear right side of the second transmission frame 7014 is connected with a spring rod 7016 through a bolt; the front right side of the spring bar 7016 is in transmission connection with the roller 7017; the lower right side of the first straight gear 701 is connected with a first bevel gear 2010; the bottom end of the chute 709 is connected with the outer dip-coating cabin 201; the rear end of the staple 7015 is connected to the top chamber 5.

When dip-coating the interior of the glove, firstly adjusting the liquid level extrusion lifting device 7 to enable the roller 7017 to move downwards to the bottommost part of the vertical height which can be reached by the roller, then lifting the glove which finishes surface dip-coating through the glove transfer dip-coating device 8 to enable the bottom end of the glove to be parallel to the roller 7017, then filling the inner layer dip-coating liquid which is half of the volume of the interior of the glove into the glove through the inner dip-coating nozzle 10, then driving the first bevel gear 2010 to drive the first straight gear 701, driving the first straight gear 701 to be meshed with the second straight gear 702, driving the second straight gear 702 to be meshed with the third straight gear 704, driving the third straight gear 704 to drive the transmission disc 705, driving the transmission disc 705 to rotate again by the transmission column 706, driving the first transmission frame 707 to slide to the left and the right under the support assistance of the sliding base 708 and the sliding chute 709 in a reciprocating manner, driving the sliding rod 7010 to slide together, driving the sliding rod 7011 to slide to the left and the right, the sliding block 7011 can simultaneously drive the high-low lifting rod 7012 and the second transmission frame 7014 to slide, the high-low lifting rod 7012 can simultaneously lift up and down under the influence of self gravity and the inclined plane of the height adjusting block 7013 when sliding left and right, so that the high-low lifting rod 7012 reversely drives the sliding block 7011 to lift up and down, and then drives the second transmission frame 7014 to swing up and down, because the second transmission frame 7014 is limited by the fixed piggy-back nail 7015, the second transmission frame 7014 can tilt left and right like a seesaw, then the second transmission frame 7014 drives the spring rod 7016 to swing up and down, the spring rod 7016 drives the roller 7017 to move up and down, in the process that the roller 7017 moves from the lowest point to the highest point, the roller 7017 can contact the inner right side wall of the top processing chamber 5, the spring rod 7016 is firstly compressed, then released, then the spring rod 7016 is returned from the highest point, and then the spring rod 7016 is continuously compressed and then released. Therefore, when the spring bar 7016 is in a compressed state, the spring bar 7016 also pushes the roller 7017 to the right to press the glove, and when the spring bar 7016 pushes the roller 7017 to move upwards from the bottom, the roller 7017 can press the dip coating liquid in the glove upwards together to raise the liquid level, so that the inner layer dip coating liquid can be contacted with the inner layer dip coating liquid in the whole glove, and dip coating can be performed. When the device is not used, the first electric push rod 703 is controlled to extend and contract, so that the second spur gear 702 is disengaged from the first spur gear 701 and the third spur gear 704, and the device stops operating. The device is simple to use, and the inner layer dip coating liquid is forced to move upwards by using a mechanical transmission method to extrude the glove from the bottom by utilizing the extrusion of the spring rod 7016 and the roller 7017, so that the dip coating liquid can dip-coat the whole inner surface of the glove. General dip-coating device is with inside whole full dip-coating liquid of filling of gloves, and this device, on the basis of accomplishing the whole internal surface of dip-coating, only need use half or even less dip-coating liquid, dip-coating liquid consumes still less, and the dip-coating cost is lower, and the dip-coating waste liquid of production still less, the consumption of follow-up processing waste liquid still less, more environmental protection to the device can shift dip-coating device 8 and dip-coating processing apparatus 2 with gloves and form the linkage, is worth using widely.

The glove transferring and dip-coating device 8 comprises a third bevel gear 801, a fourth bevel gear 802, a third driving wheel 803, a fourth driving wheel 804, an expansion link 805, a control plate 806, an air cylinder 807, a fifth bevel gear 808, a sixth bevel gear 809, a seventh bevel gear 8010, a screw rod 8011, a driving block 8012, a second electric push rod 8013, a third electric push rod 8014, a lifting plate 8015, a funnel 8016, a first electric clamp 8017 and a second electric clamp 8018; the left top of the third bevel gear 801 is meshed with a fourth bevel gear 802; the top of the fourth bevel gear 802 is in transmission connection with a third transmission wheel 803; the left side of the third driving wheel 803 is in transmission connection with the fourth driving wheel 804; the top end axis of the fourth driving wheel 804 is in driving connection with the telescopic rod 805; the bottom of the outer surface of the telescopic rod 805 is sleeved with the control plate 806; the bottom of the outer surface of the telescopic rod 805 is inserted into the fifth bevel gear 808; the top of the outer surface of the telescopic rod 805 is inserted into a sixth bevel gear 809; the right side of the bottom of the control plate 806 is connected with the air cylinder 807 through bolts; the left bottom of sixth bevel gear 809 is meshed with seventh bevel gear 8010; the axle center of the left end of the seventh bevel gear 8010 is in transmission connection with the screw rod 8011; the left side of the outer surface of the screw rod 8011 is in transmission connection with a transmission block 8012; the left side of the bottom of the transmission block 8012 is in bolted connection with a second electric push rod 8013; the right side of the bottom of the transmission block 8012 is in bolted connection with a third electric push rod 8014; the bottom end of the second electric push rod 8013 is connected with the lifting plate 8015 through a bolt, and the right top side of the lifting plate 8015 is connected with the third electric push rod 8014; the front side of the middle of the top of the lifting plate 8015 is plugged with the funnel 8016; the front part of the left side of the bottom of the lifting plate 8015 is connected with the first electric clamp 8017; the front part of the right side of the bottom of the lifting plate 8015 is connected with the second electric clamp 8018; the axle center of the left end of the third bevel gear 801 is connected with the first driving wheel 2013.

When transferring gloves, firstly, the gloves are fixed on a first electric clamp 8017 and a second electric clamp 8018 with the open ends facing upwards, the back of the hand and the palm face facing left and right respectively, then a first driving wheel 2013 drives a third bevel gear 801, the third bevel gear 801 is meshed with and drives a fourth bevel gear 802, the fourth bevel gear 802 drives a third driving wheel 803 to rotate, the third driving wheel 803 drives a fourth driving wheel 804, the fourth driving wheel 804 drives an expansion link 805, the expansion link 805 drives a sixth bevel gear 809, the sixth bevel gear 809 is meshed with and drives a seventh bevel gear 8010, the seventh bevel gear 8010 drives a screw rod 8011 to rotate, the screw rod 8011 drives a driving block 8012 to move right, the driving block 8012 drives the gloves 8012 to move to the rightmost end together, then the second electric push rod 8013 and the third electric push rod 8014 are controlled to stretch and push a lifting plate 8015 to descend, the gloves are conveyed to a dip-coating processing device 2 for surface coating, realize the automatic transportation of gloves. The glove lining dip from the inner dip spout 10 is directed through the funnel 8016. The device is simple to use, through mechanical transmission, has realized the automation of carry gloves and has controlled operation and oscilaltion, and the work of taking out is accomplished the dip-coating of the interior external surface of gloves and is carried out to cooperation dip-coating processing apparatus 2 and liquid level extrusion elevating gear 7, replaces the manual work to carry out gloves transfer work, improves work efficiency to the device can form the linkage with dip-coating processing apparatus 2 and liquid level extrusion elevating gear 7, is worth using widely.

When the air cylinder 807 telescopically drives the control plate 806, the control plate 806 drives the telescopic rod 805 to enable the sixth bevel gear 809 and the seventh bevel gear 8010 to be meshed with each other, the telescopic rod 805 drives the sixth bevel gear 809 to rotate, and the sixth bevel gear 809 is meshed with and drives the seventh bevel gear 8010; when the air cylinder 807 telescopically drives the control plate 806, the control plate 806 drives the telescopic rod 805 to enable the fifth bevel gear 808 and the seventh bevel gear 8010 to be meshed with each other, the telescopic rod 805 drives the fifth bevel gear 808 to rotate, the fifth bevel gear 808 is meshed with the seventh bevel gear 8010 to drive the seventh bevel gear 8010 to rotate in the opposite direction when the seventh bevel gear 8010 is meshed with the sixth bevel gear 809 for transmission; when air cylinder 807 extends and retracts to drive control plate 806, control plate 806 drives telescoping rod 805 to simultaneously disengage fifth bevel gear 808 and sixth bevel gear 809 from seventh bevel gear 8010, and seventh bevel gear 8010 remains stationary. The steering of the screw 8011 is controlled in this way, the ultimate purpose being to control the side-to-side movement of the gripping glove to different positions of the device, or to stop the coating process at the extreme right, all depending on the configuration control.

Wherein, when the high-low lifting rod 7012 slides to contact with the highest point and the lowest point of the height adjusting block 7013, the spring rod 7016 extends to the maximum length, at this time, the roller 7017 reaches the lowest point and the highest point of the vertical height, and the roller 7017 does not contact with the inner wall of the top treatment chamber 5. The roller 7017 is not in contact with the inner wall of the top treatment chamber 5 at the lowermost end thereof, and is spaced apart from the inner wall so as to allow the glove to enter the space after the glove transfer dip-coating apparatus 8 has moved the glove to the rightmost side, where the glove is subsequently subjected to the pressing of the roller 7017 to complete the dip-coating of the inner surface in the semi-dip-coating liquid state.

Wherein, the rear end axle centers of the second friction wheel 207 and the third friction wheel 208 are connected with a straight gear, and the two straight gears are meshed with each other. The steering is changed through the two straight gears which are meshed with each other, so that the gears can be matched with each other to form a downward pulling force through friction force, the auxiliary gloves overcome the buoyancy of the dip-coating liquid, and the dip-coating of the outer surface is thoroughly carried out.

The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are only exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. A latex glove dip-coating device comprises support legs (1), a support plate (3), a control screen (4), a top treatment chamber (5) and a chamber door (6), and is characterized by further comprising a dip-coating treatment device (2), a liquid level extrusion lifting device (7), a glove transfer dip-coating device (8), an arc top plate (9) and an inner immersion nozzle (10); the top ends of the support legs (1) are connected with the dip-coating treatment device (2) through bolts; the right top of the dip-coating treatment device (2) is welded with the bearing plate (3); the top end of the dip coating device (2) is welded with the top treatment chamber (5); the right side of the top of the bearing plate (3) is connected with the control screen (4); a chamber door (6) is arranged on the inner side of the left middle bottom part of the top treatment chamber (5); a liquid level extrusion lifting device (7) is arranged on the left side of the inner bottom of the top treatment chamber (5), and the bottom end and the right middle part of the liquid level extrusion lifting device (7) are connected with the dip-coating treatment device (2); a glove transfer dip-coating device (8) is arranged at the middle top part in the top treatment chamber (5), and the right bottom part of the glove transfer dip-coating device (8) is connected with the dip-coating treatment device (2); the top end of the top treatment chamber (5) is welded with the arc top plate (9); the front side of the right top in the top treatment chamber (5) is connected with an inner immersion nozzle (10) through a frame rod;

the dip-coating treatment device (2) comprises an outer dip-coating cabin (201), a liquid guide pipe (202), a surface drying chamber (203), a pushing rod (204), a bottom outlet (205), a first friction wheel (206), a second friction wheel (207), a third friction wheel (208), a fourth friction wheel (209), a first bevel gear (2010), a second bevel gear (2011), a motor (2012), a first driving wheel (2013), a second driving wheel (2014) and fan blades (2015); the right side of the bottom of the outer dip-coating cabin (201) is mutually inserted with the liquid conduit (202); the left side in the bottom of the outer dip-coating cabin (201) is welded with the surface drying chamber (203); the middle right side of the inner top of the outer dip-coating cabin (201) is connected with a first friction wheel (206) through a connecting plate; the inner side of the left bottom of the surface drying chamber (203) is sleeved with a pushing rod (204); the middle part of the bottom of the surface drying chamber (203) is rotationally connected with a bottom outlet (205); the right lower side of the first friction wheel (206) is in transmission connection with a second friction wheel (207); a third friction wheel (208) is arranged on the right side of the second friction wheel (207); the right upper side of the third friction wheel (208) is in transmission connection with a fourth friction wheel (209); the right upper side of the fourth friction wheel (209) is in transmission connection with the first bevel gear (2010); the right front side of the first bevel gear (2010) is meshed with the second bevel gear (2011); the left end axis of the second bevel gear (2011) is in transmission connection with the motor (2012); the right end axis of the second bevel gear (2011) is in transmission connection with the first transmission wheel (2013); the bottom of the first driving wheel (2013) is in driving connection with a second driving wheel (2014); the axle center of the left end of the second transmission wheel (2014) is in transmission connection with the fan blade (2015); the top left side and the top right side of the outer dip-coating cabin (201) are connected with a top treatment chamber (5); the middle left rear side of the outer dip-coating cabin (201) is connected with a liquid level extrusion lifting device (7); the left side of the bottom of the surface drying chamber (203) is connected with the support leg (1); the left upper side of the first bevel gear (2010) is connected with a liquid level extrusion lifting device (7); the right end axle center of the first driving wheel (2013) is connected with a glove transferring and dip-coating device (8).

2. The dipping device for latex gloves according to claim 1, wherein the liquid level extrusion lifting device (7) comprises a first straight gear (701), a second straight gear (702), a first electric push rod (703), a third straight gear (704), a transmission disc (705), a transmission column (706), a first transmission frame (707), a sliding base (708), a sliding groove (709), a sliding rod (7010), a sliding block (7011), a high-low lifting rod (7012), a height adjusting block (7013), a second transmission frame (7014), a piggy-back nail (7015), a spring rod (7016) and a roller (7017); the right upper side of the first straight gear (701) is meshed with the second straight gear (702); the left side of the second straight gear (702) is in transmission connection with a first electric push rod (703); the left upper side of the second straight gear (702) is meshed with a third straight gear (704); the left lower side of the third straight gear (704) is in transmission connection with a transmission disc (705); the front top of the transmission disc (705) is welded with the transmission post (706); the outer surface of the transmission column (706) is in transmission connection with the first transmission frame (707); the bottom end of the first transmission frame (707) is welded with the sliding base (708); the right top of the first transmission frame (707) is welded with the sliding rod (7010) through a connecting block; the bottom end of the sliding base (708) is in sliding connection with the sliding chute (709); the middle part of the outer surface of the sliding rod (7010) is connected with the sliding block (7011) in a sliding way; the front middle part of the sliding block (7011) is welded with a high-low lifting rod (7012); the right middle part of the sliding block (7011) is in transmission connection with a second transmission frame (7014); the bottom end of the high-low lifting rod (7012) is connected with the height adjusting block (7013) in a sliding way; the inner middle part of the second transmission frame (7014) is connected with a piggyback nail (7015); the rear right side of the second transmission frame (7014) is connected with a spring rod (7016) through a bolt; the front right side of the spring rod (7016) is in transmission connection with the roller (7017); the right lower side of the first straight gear (701) is connected with a first bevel gear (2010); the bottom end of the chute (709) is connected with the outer dip-coating cabin (201); the rear end of the piggyback nail (7015) is connected with the top processing chamber (5).

3. The dipping device for latex gloves according to claim 2, wherein the glove transfer dipping device (8) comprises a third bevel gear (801), a fourth bevel gear (802), a third driving wheel (803), a fourth driving wheel (804), a telescopic rod (805), a control plate (806), a cylinder (807), a fifth bevel gear (808), a sixth bevel gear (809), a seventh bevel gear (8010), a screw rod (8011), a driving block (8012), a second electric push rod (8013), a third electric push rod (8014), a lifting plate (8015), a funnel (8016), a first electric clamp (8017) and a second electric clamp (8018); the left top of the third bevel gear (801) is meshed with the fourth bevel gear (802); the top of the fourth bevel gear (802) is in transmission connection with a third transmission wheel (803); the left side of the third driving wheel (803) is in transmission connection with a fourth driving wheel (804); the top end axis of the fourth driving wheel (804) is in driving connection with the telescopic rod (805); the bottom of the outer surface of the telescopic rod (805) is sleeved with the control plate (806); the bottom of the outer surface of the telescopic rod (805) is mutually inserted with a fifth bevel gear (808); the top of the outer surface of the telescopic rod (805) is mutually inserted with a sixth bevel gear (809); the right side of the bottom of the control plate (806) is connected with the air cylinder (807) through a bolt; the left bottom of the sixth bevel gear (809) is meshed with the seventh bevel gear (8010); the axle center of the left end of the seventh bevel gear (8010) is in transmission connection with the screw rod (8011); the left side of the outer surface of the screw rod (8011) is in transmission connection with the transmission block (8012); the left side of the bottom of the transmission block (8012) is in bolted connection with a second electric push rod (8013); the right side of the bottom of the transmission block (8012) is in bolted connection with a third electric push rod (8014); the bottom end of the second electric push rod (8013) is in bolted connection with the lifting plate (8015), and the right top side of the lifting plate (8015) is connected with the third electric push rod (8014); the front side of the middle part of the top of the lifting plate (8015) is mutually inserted with the funnel (8016); the front part of the left side of the bottom of the lifting plate (8015) is connected with a first electric clamp (8017); the front part of the right side of the bottom of the lifting plate (8015) is connected with a second electric clamp (8018); the left end axis of the third bevel gear (801) is connected with the first transmission wheel (2013).

4. The dipping device for latex gloves according to claim 3, wherein when the air cylinder (807) telescopically drives the control plate (806), the control plate (806) drives the telescopic rod (805) to enable the sixth bevel gear (809) to be meshed with the seventh bevel gear (8010), the telescopic rod (805) drives the sixth bevel gear (809) to rotate, and the sixth bevel gear (809) is meshed with the seventh bevel gear (8010); when the cylinder (807) telescopically drives the control plate (806), the control plate (806) drives the telescopic rod (805) to enable the fifth bevel gear (808) and the seventh bevel gear (8010) to be meshed with each other, the telescopic rod (805) drives the fifth bevel gear (808) to rotate, the fifth bevel gear (808) is meshed with and drives the seventh bevel gear (8010), and the seventh bevel gear (8010) rotates in the opposite direction when being meshed with and driven by the sixth bevel gear (809); when the air cylinder (807) telescopically drives the control plate (806), the control plate (806) drives the telescopic rod (805) to enable the fifth bevel gear (808) and the sixth bevel gear (809) to be simultaneously not meshed with the seventh bevel gear (8010), and the seventh bevel gear (8010) is kept static.

5. A latex glove dip-coating apparatus as claimed in claim 4, wherein the spring bar (7016) is extended to a maximum length when the elevation bar (7012) slides to contact the highest and lowest points of the elevation adjustment block (7013), and the roller (7017) reaches the lowest and highest points of the vertical height, and the roller (7017) does not contact the inner wall of the top treatment chamber (5).

6. A latex glove dip-coating device according to claim 5, characterized in that the rear end axes of the second friction wheel (207) and the third friction wheel (208) are connected with a straight gear, and the two straight gears are meshed with each other.