CN219883337U - Feeding system - Google Patents

Abstract

The utility model is applicable to the technical field of battery heat insulation, and provides a feeding system, which comprises: a bottom film feeding assembly and a heat insulation cotton feeding assembly; the bottom film feeding assembly comprises a discharging mechanism and a transmission mechanism, a bottom film material roll is placed on the discharging mechanism, and the transmission mechanism is used for driving the bottom film material roll to feed the heat insulation cotton feeding assembly; the heat-insulating cotton feeding assembly comprises a positioning platform, a heat-insulating cotton placing platform and a heat-insulating cotton moving mechanism, wherein heat-insulating cotton is placed on the heat-insulating cotton placing platform, the heat-insulating cotton moving mechanism is used for moving the heat-insulating cotton to the positioning platform, and a bottom film conveyed by the transmission mechanism passes through the position right below the positioning platform so as to press the heat-insulating cotton and the bottom film together through the pressing assembly. According to the utility model, the basement membrane is not required to be sliced, and manual feeding is not required, so that the process flow can be simplified, the utilization rate and the production efficiency of raw materials can be improved, and the product quality is ensured.

Description

Feeding system

Technical Field

The utility model belongs to the technical field of battery heat insulation, and particularly relates to a feeding system.

Background

The new energy automobile is an environment-friendly automobile adopting unconventional automobile fuel as a power source, and is more and more favored because the new energy automobile can reduce energy consumption and environmental pollution. At present, a lithium battery is mainly used as an electric drive storage battery for a new energy vehicle, and a great amount of heat is generated in the charging and discharging process, so that serious consequences are caused for avoiding direct contact between the storage battery and a vehicle body, and heat insulation materials are mostly used for effectively separating the storage battery from the vehicle body.

The heat insulation material is mostly heat-insulated by adopting a composite aerosol heat insulation product, and the composite aerosol heat insulation product is realized by pressing the heat insulation cotton and the bottom film with the hot melt adhesive coating during preparation, so that the bottom film and the heat insulation cotton need to be fed, at present, during preparation of the heat insulation material, the bottom film is usually required to be cut into sheets according to the size of a battery, then the heat insulation cotton is correspondingly placed on the bottom film in a manual discharging mode, and during pressing, the process flow is complex, waste is easy to generate during cutting the bottom film, the quality is difficult to ensure, the utilization rate of raw materials is relatively low, and the production efficiency is relatively low due to the manual discharging mode.

Disclosure of Invention

The present utility model provides a feeding system, which aims to solve at least one problem existing in the prior art.

The utility model is realized in that a feeding system comprises:

a bottom film feeding assembly and a heat insulation cotton feeding assembly;

the bottom film feeding assembly comprises a discharging mechanism and a transmission mechanism, a bottom film material roll is placed on the discharging mechanism, and the transmission mechanism is used for driving the bottom film material roll to feed the heat insulation cotton feeding assembly;

the heat-insulating cotton feeding assembly comprises a positioning platform, a heat-insulating cotton placing platform and a heat-insulating cotton moving mechanism, wherein heat-insulating cotton is placed on the heat-insulating cotton placing platform, the heat-insulating cotton moving mechanism is used for moving the heat-insulating cotton to the positioning platform, and a bottom film conveyed by the transmission mechanism passes through the position right below the positioning platform so as to press the heat-insulating cotton and the bottom film together through the pressing assembly.

In an embodiment, the carrier film feeding assembly includes:

the first limiting wheels are arranged above the discharging mechanism and used for limiting the bottom film;

the deviation corrector assembly is arranged at the discharge hole of the first limiting wheel and used for correcting the deviation of the basement membrane positioned by the first limiting wheel.

In one embodiment, the error corrector assembly comprises:

a base;

the device comprises a base, a deviation corrector, a plurality of U-shaped grooves and deviation correcting sensors, wherein the deviation corrector is arranged above the base and used for adjusting the position of a base film, and the U-shaped grooves are formed in the deviation corrector and are used for detecting the edge position of the base film.

In an embodiment, the carrier film feeding assembly further includes:

the material shortage sensor is arranged on the base and used for detecting whether the material is deficient; and

the material changing platform is arranged between the deviation corrector assembly and the transmission mechanism and is used for docking new and old material rolls when changing materials.

In an embodiment, the discharging mechanism comprises:

a first driving motor;

and the discharging roller is movably connected with the power output end of the first driving motor, so that the discharging roller is driven by the first driving motor to rotate, and a bottom film material roll is placed on the discharging roller.

In one embodiment, the transmission mechanism includes:

a second driving motor;

the first driving roller is movably connected with the power output end of the second driving motor, and the second driving roller is arranged above the first driving roller, and a gap for the bottom film to pass through is arranged between the first driving roller and the second driving roller;

the lifting structure is oppositely arranged above two sides of the second driving roller and is used for pushing the second driving roller so as to adjust the size of the gap.

In an embodiment, the thermal insulation cotton feeding assembly comprises:

the buffer mechanism is arranged below the positioning platform and is used for buffering the passing bottom film so as to realize intermittent feeding;

the second limiting wheels are arranged at two ends of the buffer mechanism and used for limiting the bottom films input and output by the buffer mechanism.

In one embodiment, the heat insulation cotton moving mechanism comprises:

the transverse moving module is arranged above the positioning platform and the heat insulation cotton placing platform;

the lifting module is arranged above the transverse moving module and used for carrying out reciprocating motion along the transverse moving module;

the suction disc module is arranged at one end of the lifting module, which is far away from the transverse moving module, and is used for adsorbing the heat insulation cotton.

In one embodiment, the suction cup module comprises:

a plurality of sucking disc structures for sucking the heat insulation cotton;

and the vacuum generator is communicated with the sucker structure through a ventilation pipeline so as to vacuumize the sucker structure.

In an embodiment, the thermal insulation cotton feeding assembly comprises:

the static removing structure is arranged on the heat insulating cotton moving mechanism and is used for removing static of the heat insulating cotton.

The utility model provides a feeding system, which comprises: a bottom film feeding assembly and a heat insulation cotton feeding assembly; the bottom film feeding assembly comprises a discharging mechanism and a transmission mechanism, a bottom film material roll is placed on the discharging mechanism, and the transmission mechanism is used for driving the bottom film material roll to feed the heat insulation cotton feeding assembly; the heat-insulating cotton feeding assembly comprises a positioning platform, a heat-insulating cotton placing platform and a heat-insulating cotton moving mechanism, wherein heat-insulating cotton is placed on the heat-insulating cotton placing platform, the heat-insulating cotton moving mechanism is used for moving the heat-insulating cotton to the positioning platform, and a bottom film conveyed by the transmission mechanism passes through the position right below the positioning platform so as to press the heat-insulating cotton and the bottom film together through the pressing assembly. According to the embodiment of the utility model, the whole roll of the bottom film material roll is directly placed by the bottom film feeding assembly, and the heat insulation cotton feeding assembly and the pressing assembly are fed by the transmission mechanism, the heat insulation cotton feeding assembly can move the heat insulation cotton to the positioning platform right above the bottom film feeding path, the head of the heat insulation cotton can be pushed by the pressing assembly to be contacted with the bottom film below and pressed, the bottom film is not required to be sliced, manual feeding is not required, the process flow can be simplified, the problem that waste is easy to generate when the bottom film is cut can be avoided, the utilization rate and the production efficiency of raw materials can be effectively improved, and the quality of products is ensured.

Drawings

FIG. 1 is a schematic structural diagram of a feeding system according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a carrier film feeding assembly according to an embodiment of the present utility model;

fig. 3 is a schematic structural diagram II of a carrier film feeding assembly according to an embodiment of the present utility model;

fig. 4 is a schematic structural view of a heat insulation cotton feeding assembly according to an embodiment of the present utility model;

FIG. 5 is a schematic structural view of a heat insulation cotton moving mechanism according to an embodiment of the present utility model;

FIG. 6 is a schematic structural diagram of a traversing module according to an embodiment of the present utility model;

FIG. 7 is a schematic structural diagram of a buffering mechanism according to an embodiment of the present utility model;

wherein, 1, a basement membrane feeding assembly; 2; a heat insulation cotton feeding assembly; 3. a base; 11. a discharging mechanism; 111. a first driving motor; 112. a discharging roller; 113. a bearing with a seat; 12. a transmission mechanism; 121. a second driving motor; 122. a first driving roller; 123. a second driving roller; 124. a lifting structure; 125. a first bracket; 126. a second bracket; 127. a movable block; 13. a bottom film material roll; 131. a base film; 14. a first limit wheel; 15. a rectifier assembly; 151. a base; 152. a deviation corrector; 1521. a U-shaped groove; 16. a material shortage sensor; 17. a material changing platform; 171. briquetting; 18. the second limiting wheel; 21. positioning a platform; 211. a limit structure; 22. a heat insulation cotton placement platform; 23. a heat insulation cotton moving mechanism; 231. a traversing module; 2311. a first mounting plate; 2312. a second mounting plate; 2313. a through groove; 2314. a slide rail; 2315. a first wiring structure; 232. a lifting module; 2321. a first slider; 2322. a chute; 2323. a second slider; 2324. a second wiring structure; 233. a suction cup module; 2331. a suction cup structure; 234. a first mounting bracket; 235. a second mounting bracket; 236. a third mounting bracket; 2361. reinforcing ribs; 24. a buffer mechanism; 241. a buffer base, 242, support bar; 243. the third limiting wheel; 244. a lifting member; 25. a fourth limit wheel; 26. a static electricity removing structure; 31. a support; 32. and a universal wheel.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

In the description of the present utility model, it should be understood that the terms "longitudinal," "radial," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships that are based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In an embodiment of the present utility model, there is provided a feeding system including: a bottom film feeding component 1 and a heat insulation cotton feeding component 2; the bottom film feeding assembly 1 comprises a discharging mechanism 11 and a transmission mechanism 12, wherein a bottom film material roll 13 is placed on the discharging mechanism 11, and the transmission mechanism 12 is used for driving the bottom film material roll 13 to feed the heat insulation cotton feeding assembly 2; the heat insulation cotton feeding assembly 2 comprises a positioning platform 21, a heat insulation cotton placing platform 22 and a heat insulation cotton moving mechanism 23, wherein heat insulation cotton is placed on the heat insulation cotton placing platform 22, the heat insulation cotton moving mechanism 23 is used for moving the heat insulation cotton to the positioning platform 21, and a bottom film 131 conveyed by the transmission mechanism 12 passes through the position right below the positioning platform 21 so as to press the heat insulation cotton and the bottom film 131 together through a pressing assembly (not shown in the figure). Through directly placing the backing film material roll of whole roll on the backing film material loading subassembly to walk the material through drive mechanism to thermal-insulated cotton material loading subassembly and pressfitting subassembly, this thermal-insulated cotton material loading subassembly can move thermal-insulated cotton to the location platform that is located directly over this backing film material path, and this thermal-insulated cotton's head accessible pressfitting subassembly promotes, make it contact with the backing film that is located the below, and pressfitting, need not to slice the backing film, and need not artifical material loading, can simplify the technological process, and can avoid when tailorring the backing film, the problem of easily producing the waste material, can effectively improve the utilization ratio and the production efficiency of raw and other materials, guarantee the quality of product.

The base film can be a protective film made of PET material, and the surface of the base film is provided with a hot melt adhesive coating, so that the base film generates viscosity when heated.

In the embodiment of the utility model, the pressing assembly is arranged on one side of the heat insulation cotton feeding assembly 2 away from the bottom film feeding assembly, and is used for pushing the heat insulation cotton placed on the positioning platform 21 to a pressing position, so that the head of the heat insulation cotton is contacted with the bottom film and is pressed, and then the heat insulation cotton can be driven by the bottom film to move continuously until the heat insulation cotton is separated from the positioning platform, and then the next heat insulation cotton is moved and pressed again.

In the embodiment of the present utility model, the carrier film feeding assembly 1 further includes: a plurality of first limiting wheels 14 arranged above the discharging mechanism 11 and used for limiting the bottom film 131; and the deviation corrector assembly 15 is arranged at the discharge hole of the first limiting wheel 14 and is used for correcting the deviation of the bottom film 131 after the first limiting wheel 14 is limited. The bottom film 131 can be supported and limited by the plurality of first limiting wheels 14, so that the bottom film 131 can be fed along a preset route, the bottom film 131 is prevented from being separated from the feeding route, the bottom film 131 subjected to limiting treatment can be further detected by the deviation corrector assembly 15, and the position of the bottom film 131 can be adjusted by twisting when the bottom film 131 deviates from a set position, so that the bottom film 131 can be always stored at the set position.

The first limiting wheels 14 may include 3 limiting wheels, and the first limiting wheels 14 are relatively provided with a stop block 141, and the bottom film 131 passes between the stop blocks 141, and can be limited by the stop block 141. The bottom film 131 can sequentially pass through the gap between the two first limiting wheels 14, pass over the uppermost first limiting wheel 14, and pass over the deviation corrector assembly 15.

It can be understood that the number of the first limiting wheels 14 may be 5, 7, etc., and may be specifically set according to practical situations, which is not limited herein.

Further, the error corrector assembly 15 may include: a base 151; the deviation corrector 152 is disposed above the base 151 and is used for adjusting the position of the bottom film 131, the deviation corrector 152 is provided with a U-shaped groove 1521, and a plurality of deviation correcting sensors (not shown in the figure) are disposed on the U-shaped groove 1521 and are used for detecting the edge position of the bottom film 131. When the bottom film 131 is fed, it can pass through the top of the deviation corrector 152, i.e. at the opening end of the U-shaped groove 1521, at this time, the edge position of the passing bottom film can be detected by the deviation corrector sensor, so as to determine whether the edge position of the bottom film is consistent with the preset position, and when the edge position of the bottom film is inconsistent with the preset position, the deviation corrector 152 can be controlled to twist so as to adjust the position of the bottom film, thereby avoiding the inclined feeding of the bottom film or the folding problem.

The deviation correcting sensor may be an ultrasonic sensor, an optical fiber sensor, etc., and may be disposed on the peripheral edge of the U-shaped groove 1521.

In an embodiment of the present utility model, the carrier film feeding assembly 1 further includes: a starved sensor 16 disposed on the base 151 for detecting whether a starved material exists; and a material changing platform 17 arranged between the deviation corrector assembly 15 and the transmission mechanism 12, wherein the material changing platform 17 is used for docking new and old material rolls when material is changed. Specifically, when the backing film roll falls off from the discharging mechanism 1 or the use is completed, the feeding system can be controlled to stop running, at this time, an operator can replace a new backing film roll, and the tail end of the previous backing film roll and the head end of the new backing film roll can be aligned, flattened and bonded on the material changing platform, so that the butt joint and replacement of the new and old rolls are realized.

The material changing platform 17 is relatively provided with a pressing block 171, and the tail end of the last roll of bottom film material and the rear end of the new bottom film material roll can respectively pass through a gap between the pressing block 171 and the surface of the material changing platform 17, and align and flatten the bottom film of the new and old rolls between the pressing blocks 171, so as to perform bonding operation.

The material shortage sensor 16 may be an optical fiber sensor, a photoelectric sensor, or the like.

In an embodiment of the present utility model, a second limiting wheel 18 is further disposed between the material changing platform 17 and the deviation corrector assembly 15, for limiting the bottom film 131 entering the material changing platform 17, and establishing a material path between the material changing platform 17 and the deviation corrector assembly 15, so that the material is more smooth.

The second limiting wheel 18 may also include a plurality of limiting wheels, which may be specifically set according to practical situations, and the present utility model is not limited herein.

In an embodiment of the present utility model, the discharging mechanism 11 includes: a first driving motor 111; and the discharging roller 112 is movably connected with the power output end of the first driving motor 111 so as to rotate under the driving of the first driving motor 111, and a bottom film roll 13 is placed on the discharging roller 112. Specifically, the first driving motor 111 can drive the discharging roller 112 to rotate, so as to drive the bottom film roll 13 to rotate, thereby realizing bottom film feeding.

The first driving motor 111 may be a servo motor, and the discharging roller 112 may be an encapsulation shaft.

Wherein, a bearing 113 with a seat is arranged between the first driving motor 111 and the discharging roller 112.

In one embodiment of the present utility model, the transmission 12 includes: a second driving motor 121; a first driving roller 122 movably connected to the power output end of the second driving motor 121, and a second driving roller 123 disposed above the first driving roller 122, wherein a gap for the bottom film 131 to pass through is disposed between the first driving roller 121 and the second driving roller 122; the lifting structures 124 are oppositely arranged above two sides of the second driving roller 123, and the lifting structures 124 are used for pushing the second driving roller 122 so as to adjust the size of the gap.

Specifically, the transmission mechanism 12 further includes a first support 125 and a second support 126 opposite to the first support 125, the first driving roller 122 and the second driving roller 123 are disposed horizontally up and down, the first support 125 and the second support 126 are opposite to each other and provided with a movable block 127, two ends of the second driving roller 123 are respectively disposed on the movable block 127, a lifting structure 124 is disposed above the movable block 127, the movable block 127 can be driven to move up and down by the lifting structure 124, and then the second driving roller 123 is driven to move up and down by the movable block 127, so as to adjust a gap distance between the second driving roller 123 and the first driving roller 122, and when the first driving roller 122 and the second driving roller 123 are driven to rotate by the second driving motor 121, the bottom film 131 is pushed to move by friction force therebetween.

The second driving motor 121 may be a servo motor, and the first driving roller 122 and the second driving roller 123 may be rubber covered shafts. A bearing with a seat is also provided between the second driving motor 121 and the first and second driving rollers 122 and 123.

Wherein, the lifting structure 124 may be a lifting cylinder.

In the embodiment of the present utility model, the torque of the first driving motor 111 may be adjusted to maintain a certain tension between the discharging roller 112 and the first driving roller 122 and the second driving roller 123, so that the bottom film may be smoother during driving.

In one embodiment of the present utility model, the heat insulation cotton feeding assembly 2 comprises: the buffer mechanism 24 is disposed below the positioning platform 21, and the buffer mechanism 24 is configured to buffer the passing bottom film 131, so as to realize intermittent feeding. It will be appreciated that the composite aerosol insulation product is used to insulate a battery, and because of the limited volume of the battery, the composite aerosol insulation product needs to be prepared at the actual distance of the aerosol insulation product, and the base film roll is integral, so that the base film roll can stop feeding after each step of one product, and can temporarily buffer the base film 131 by the buffer mechanism 24 when feeding the next product to realize intermittent feeding operation.

Further, the buffering mechanism 24 includes a buffering base 241, supporting rods 242 disposed on the buffering base, a third limiting wheel 243 is disposed between the two supporting rods 242, the height of the third limiting wheel 243 is lower than that of the supporting rods 242, a gap for the bottom film to pass through is disposed between the third limiting wheel 243 and the buffering base 241, when feeding, the bottom film 131 enters from above the first supporting rod 241 and passes through the gap between the third limiting wheel 243 and the buffering base 241, and then passes through above the second supporting rod 241, and the running route of the bottom film 131 can be prolonged by the third limiting wheel 243, thereby buffering the bottom film 131.

The buffer base 241 is relatively provided with a lifting member 244 for lifting the third limiting wheel 243, so as to adjust the buffer length of the bottom film to adapt to the lengths of different products.

Wherein, the lifting member 244 may be a lifting cylinder.

In an embodiment of the present utility model, the heat insulation cotton feeding assembly 2 further includes: the fourth limiting wheels 25 are disposed at two ends of the buffer mechanism 24, and the fourth limiting wheels 25 are used for limiting the bottom film 131 input and output by the buffer mechanism 24. So as to prevent the bottom film 131 from deviating from the predetermined feeding path.

Wherein the fourth limiting wheel 25 is in the same height as the supporting rod 241.

In one embodiment of the present utility model, the heat insulation cotton moving mechanism 23 includes: a traversing module 231 disposed above the positioning platform 21 and the heat insulation cotton placement platform 22; a lifting module 232 disposed above the traversing module 231 for reciprocating along the traversing module 231; the sucking disc module 233 is arranged at one end of the lifting module 232, which is far away from the traversing module 231 and is used for sucking the heat insulation cotton. Specifically, the traversing module 231 can move the lifting module 232 to a position right above the heat insulation cotton placement platform 22, at this time, the lifting module 232 can drive the sucking disc module 233 to descend to the heat insulation cotton placement platform 22, and adsorb the heat insulation cotton placed on the heat insulation cotton placement platform 22 in a vacuum sucking manner, at this time, the lifting module 232 ascends to a safe distance and moves to a position right above the positioning platform 21 again through the traversing module 231, and drives the sucking disc module 233 to descend to a position where the heat insulation cotton just contacts the positioning platform through the lifting module 232, at this time, vacuum sucking is stopped, so that the heat insulation cotton falls on the positioning platform 233, and the lifting module 233 ascends to the safe distance again, thereby realizing movement of the heat insulation cotton. The steps are repeated, so that the plurality of heat insulation cottons can be sequentially moved. It can be understood that after the heat insulation cotton on the positioning platform 21 is pressed with the bottom film 131, i.e. the heat insulation cotton is separated from the positioning platform 21, the next circulation step is performed.

Further, the positioning platform 21 is provided with a plurality of limiting structures 211, and when the heat insulation cotton falls onto the positioning platform 21, the side edges of the heat insulation cotton are positioned by the limiting structures 211.

The limiting structure 211 may be a cylinder.

In an embodiment of the present utility model, a sliding rail 2314 is disposed on the traversing module 231, a first sliding block 2321 is disposed on the lifting module 232, and the first sliding block 2321 reciprocates along the sliding rail 2314 in a horizontal direction;

specifically, the traversing module 231 includes a first mounting plate 2311 and a second mounting plate 2312, a through slot 2313 is disposed between the first mounting plate 2311 and the second mounting plate 2312, the second mounting plate 2312 is close to one side of the first mounting plate 2311, a sliding rail 2314 is disposed on the second mounting plate 2312 relatively, a sliding groove 2322 is disposed on the first sliding block 2321 relatively, and the sliding groove 2322 is clamped on the sliding rail 2314.

The traversing module 231 further includes a first driving motor 2315 for driving the lifting module 232 to reciprocate along the traversing module 231.

In an embodiment of the present utility model, a second slider 2323 is disposed on the lifting module 232, and the second slider 2323 is connected to the suction cup module 233 and is used for driving the suction cup module 233 to lift up and down. Specifically, the suction cup module 233 and the second slider 2323 may be detachably connected through the first mounting bracket 234, and the suction cup module 233 and the second slider 2323 may be vertically disposed, so as to move the suction cup module 233 up and down through the lifting module belt 232.

The suction cup module 233 and the first mounting frame 234 may be detachably connected together by bolts (not shown), and the second slider 2322 and the first mounting frame 234 may also be detachably connected together by bolts (not shown). For replacement and maintenance.

The lifting module 232 further includes a second driving motor 2325 for driving the second slider 2322 to lift up and down.

In the embodiment of the utility model, the traversing module 231 is provided with a first routing structure 2315, the lifting module 232 is provided with a second mounting bracket 235, the second mounting bracket 235 and the first routing structure 2315 can be detachably connected together through bolts, the first routing structure 2315 can be bent and can move along with the movement of the lifting module 232, wherein the first routing structure 2315 can be used for carrying out routing so as to hide connecting wires and protect the connecting wires.

Further, a second routing structure 2324 is disposed on the lifting module 232, and the second routing structure 2324 can also be bent and moved along with the movement of the second slider 2322, so as to perform routing, and hide and protect the connection line.

In one embodiment of the present utility model, the heat insulation cotton moving mechanism 23 further comprises: the third mounting bracket 236 is disposed on a side of the positioning platform 21 away from the heat insulation cotton placement platform 22, and is used for fixing the traversing module 231. The third mounting bracket 236 has a reinforcing rib 2361 at one end contacting the ground to improve supporting force, and one end of the third mounting bracket 236 away from the ground is used for mounting the traversing module 231, and the traversing module 231 can be fixedly assembled together by bolts (not shown).

In an embodiment of the present utility model, the suction cup module 233 includes: a plurality of suction cup structures 2331 for sucking the heat insulation cotton; a vacuum generator (not shown) in communication with the suction cup structure 2331 via a vent line (not shown) for evacuating the suction cup structure 2331. The vacuum generator is used for vacuumizing operation, so that the sucker structure 2331 adsorbs heat insulation cotton.

The sucking disc structures 2331 may be arranged along the length direction of the heat insulation cotton, for example, 4 heat insulation cotton, so as to absorb the heat insulation cotton completely, avoid the problem of bending or sagging at two ends, and avoid the problem of folding and wrinkling when the positioning platform 21 is placed.

In the embodiment of the present utility model, the heat insulation cotton feeding assembly 2 includes: and a static eliminating structure 26 arranged on the heat insulating cotton moving mechanism 23 and used for eliminating static. The static eliminating structure 26 can be fixedly assembled on the third mounting bracket 236 through bolts (not shown in the figure), and can be used for eliminating static electricity generated in the moving process of the heat insulation cotton, so as to avoid causing potential safety hazards.

The static-removing structure 26 may be a static-removing rod.

In the embodiment of the utility model, the feeding system further comprises a base 3, the basement membrane feeding assembly 1 and the heat insulation cotton feeding mechanism 2 are arranged on the base 3, a plurality of supporting pieces 31 are arranged at the bottom of the base 3 and used for supporting the base 3 to avoid direct contact with the ground, a plurality of universal wheels 32 are further arranged at the bottom of the base 3, the feeding system can be pushed to a proper position at will through the universal wheels 32, manual moving is not needed, and the operation is convenient.

According to the embodiment of the utility model, the whole roll of the bottom film material roll is directly placed by the bottom film feeding assembly, and the heat insulation cotton feeding assembly and the pressing assembly are fed by the transmission mechanism, the heat insulation cotton feeding assembly can move the heat insulation cotton to the positioning platform right above the bottom film feeding path, the head of the heat insulation cotton can be pushed by the pressing assembly to be contacted with the bottom film below and pressed, the bottom film is not required to be sliced, manual feeding is not required, the process flow can be simplified, the problem that waste is easy to generate when the bottom film is cut can be avoided, the utilization rate and the production efficiency of raw materials can be effectively improved, and the quality of products can be improved.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The utility model provides a feeding system which characterized in that, feeding system includes:

a bottom film feeding assembly and a heat insulation cotton feeding assembly;

the bottom film feeding assembly comprises a discharging mechanism and a transmission mechanism, a bottom film material roll is placed on the discharging mechanism, and the transmission mechanism is used for driving the bottom film material roll to feed the heat insulation cotton feeding assembly;

the heat-insulating cotton feeding assembly comprises a positioning platform, a heat-insulating cotton placing platform and a heat-insulating cotton moving mechanism, wherein heat-insulating cotton is placed on the heat-insulating cotton placing platform, the heat-insulating cotton moving mechanism is used for moving the heat-insulating cotton to the positioning platform, and a bottom film conveyed by the transmission mechanism passes through the position right below the positioning platform so as to press the heat-insulating cotton and the bottom film together through the pressing assembly.

2. The loading system of claim 1, wherein the carrier film loading assembly comprises:

the first limiting wheels are arranged above the discharging mechanism and used for limiting the bottom film;

the deviation corrector assembly is arranged at the discharge hole of the first limiting wheel and used for correcting the deviation of the basement membrane positioned by the first limiting wheel.

3. The loading system of claim 2, wherein the rectifier assembly comprises:

a base;

the device comprises a base, a deviation corrector, a plurality of U-shaped grooves and deviation correcting sensors, wherein the deviation corrector is arranged above the base and used for adjusting the position of a base film, and the U-shaped grooves are formed in the deviation corrector and are used for detecting the edge position of the base film.

4. The feeding system of claim 3, wherein said carrier film feeding assembly further comprises:

the material shortage sensor is arranged on the base and used for detecting whether the material is deficient; and

the material changing platform is arranged between the deviation corrector assembly and the transmission mechanism and is used for docking new and old material rolls when changing materials.

5. The loading system of claim 1, wherein the discharging mechanism comprises:

a first driving motor;

and the discharging roller is movably connected with the power output end of the first driving motor, so that the discharging roller is driven by the first driving motor to rotate, and a bottom film material roll is placed on the discharging roller.

6. The loading system of claim 1, wherein the transmission mechanism comprises:

a second driving motor;

the first driving roller is movably connected with the power output end of the second driving motor, and the second driving roller is arranged above the first driving roller, and a gap for the bottom film to pass through is arranged between the first driving roller and the second driving roller;

the lifting structure is oppositely arranged above two sides of the second driving roller and is used for pushing the second driving roller so as to adjust the size of the gap.

7. The loading system of claim 1, wherein the thermal insulation cotton loading assembly comprises:

the buffer mechanism is arranged below the positioning platform and is used for buffering the passing bottom film so as to realize intermittent feeding;

the second limiting wheels are arranged at two ends of the buffer mechanism and used for limiting the bottom films input and output by the buffer mechanism.

8. The loading system of claim 1, wherein the insulating cotton moving mechanism comprises:

the transverse moving module is arranged above the positioning platform and the heat insulation cotton placing platform;

the lifting module is arranged above the transverse moving module and used for carrying out reciprocating motion along the transverse moving module;

the suction disc module is arranged at one end of the lifting module, which is far away from the transverse moving module, and is used for adsorbing the heat insulation cotton.

9. The loading system of claim 8, wherein the suction cup module comprises:

a plurality of sucking disc structures for sucking the heat insulation cotton;

and the vacuum generator is communicated with the sucker structure through a ventilation pipeline so as to vacuumize the sucker structure.

10. The loading system of claim 6, wherein the thermal insulation cotton loading assembly comprises:

the static removing structure is arranged on the heat insulating cotton moving mechanism and is used for removing static of the heat insulating cotton.