CN212664062U - Storage battery dispensing, curing and heating system - Google Patents

Abstract

The utility model provides a solidification heating system is glued to battery point, including the frame and install in rotary conveying mechanism in the frame, still include the equipartition install in last fretwork chain plate mechanism of rotary conveying mechanism, set up in rotary conveying mechanism middle part space's radiant heating mechanism, heat reflection mechanism and set up in the terminal transmission tilting mechanism of rotary conveying mechanism, be the laminating storage battery of arranging through setting up the spacing transmission of fretwork chain plate mechanism, set up radiant heating mechanism and cooperation and set up heat reflection mechanism in fretwork chain plate mechanism below, can upwards reflect and collect and the directional heating on storage battery upper cover plane after the heat radiation, realize heat concentration directional heating, the high-usage, just stand the output through transmission tilting mechanism upset after the heating solidification is accomplished, degree of automation is high, the heat dispersion that has solved and exists among the prior art, The directional heating can not be realized, and the energy utilization rate is low.

Description

Storage battery dispensing, curing and heating system

Technical Field

The utility model relates to a battery production field, concretely relates to solidification heating system is glued to battery point.

Background

The storage battery is also called a lead-acid storage battery, is a common article in life, converts electric energy into chemical energy for storage through charging, and converts the stored chemical energy into electric energy again when needed. In the production process of the storage battery, red and blue glue is required to be dispensed on the positive and negative poles for sealing after the storage battery is covered, and the resin glue is required to be dried and cured by heating after dispensing.

The application number is CN 201721301803.6's chinese utility model patent discloses a battery resin drying kiln heating system, including carrying the link joint, carry the link joint to pass from the dry curing kiln, dry curing kiln bottom is equipped with takes the opening steam heating pipe up, steam heating pipe installs on the support of wearing out from carrying link joint middle part space, and in battery upper cover point gluing back handstand put into the drying kiln, change the side and blow for the bottom is bloied, with higher speed the steam pipe heat dissipation, help the close point of battery upper cover to glue the solidification.

However, in the above technical scheme, the heat of the steam pipe is dispersed and cannot be directionally concentrated, the heating effect on the upper cover is poor, the storage battery is integrally covered in the relatively closed curing kiln, the heat can be collected in the curing kiln after rising, so that the temperature of the whole storage battery body rises, an integral cooling process is required after the curing process, the production cost is increased, the energy is wasted, and in addition, the temperature rise can also influence the quality of the storage battery, so the technical problems of heat dispersion, incapability of directionally heating and low energy utilization rate exist in the above technical scheme.

SUMMERY OF THE UTILITY MODEL

To above problem, the utility model provides a solidification heating system is glued to battery point, be the storage battery that the laminating was arranged through setting up the spacing transmission of fretwork chain plate mechanism, it sets up heat reflection mechanism and cooperation to set up radiation heating mechanism in fretwork chain plate mechanism below, can upwards reflect and collect and directional heating on the storage battery upper cover plane after the heat radiation goes out, realize the heat and concentrate directional heating, high-usage, and the cooperation sets up transmission tilting mechanism, the storage battery upset that will add the thermal cure completion is just founding the output, degree of automation is high, the heat dispersion that exists has been solved among the prior art, unable directional heating, the technical problem that energy utilization is low.

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

the storage battery dispensing, curing and heating system comprises a rack, a rotary conveying mechanism arranged on the rack, a hollow chain plate mechanism uniformly arranged on the rotary conveying mechanism, a radiation heating mechanism arranged in the middle space of the rotary conveying mechanism, a heat reflecting mechanism and a transmission turnover mechanism arranged at the transmission tail end of the rotary conveying mechanism;

the storage battery pack which is glued and arranged one by one is reversely clamped on the hollow chain plate mechanism, heat radiated outwards by the radiation heating mechanism is upwards reflected by the heat reflection mechanism and passes through the hollow chain plate mechanism to carry out centralized heating on the glue dispensing on the storage battery pack cover body in the transmission process, and the storage battery pack which is heated is transmitted to the transmission turnover mechanism and turned over for 180 degrees and then is output in an upright state.

Preferably, the plurality of hollowed-out chain plate mechanisms are erected around the rotary conveying mechanism for one circle and comprise a plurality of vertical chain plates which are distributed at intervals along the conveying direction and are vertically arranged, clamping seats which are fixedly connected with two ends of each vertical chain plate respectively and are installed on the rotary conveying mechanism, and at least one group of reinforcing plates which are connected and arranged between every two adjacent vertical chain plates and are vertically arranged; the two clamping seats can limit and fix the two ends of the storage battery pack.

Preferably, the radiation heating mechanisms and the heat reflection mechanisms correspond to each other one by one and are uniformly distributed in multiple groups along the transmission direction of the rotary conveying mechanism.

Preferably, the radiant heating mechanism comprises a support and infrared heating pipes which are uniformly arranged on the support and positioned above the heat reflection mechanism, and the width of the heat reflection mechanism is matched with the length of the infrared heating pipes.

Preferably, the heat reflection mechanism comprises a reflection disc which is arranged upwards, and the reflection disc comprises a bottom plate and a side plate which is arranged around the bottom plate in a circle.

Preferably, the rack is provided with a plurality of slide rails corresponding to the heat reflection mechanisms, and bottoms of two ends of each heat reflection mechanism can be respectively erected on the slide rails and drive the radiation heating mechanism to slide in or pull out laterally.

Preferably, the support longitudinally penetrates and is slidably mounted on the heat reflection mechanism, and a lifting adjusting block is arranged below the heat reflection mechanism on the support.

Preferably, the conveying and turning mechanism comprises a conveying assembly in transitional connection with the rotary conveying mechanism and turning assemblies arranged in a staggered mode with the conveying assembly.

Preferably, the transmission assembly includes two first rotating shafts mounted on the frame and driven by a motor to rotate, and a plurality of revolving transmission belts sleeved on the two first rotating shafts at intervals in an array manner.

Preferably, the turnover assembly comprises a second rotating shaft and a plurality of coaxial fixing sleeves, the second rotating shaft is mounted on the rack and driven to rotate by a motor, the I-shaped rotating plates are coaxially fixed on the second rotating shaft, each I-shaped rotating plate is located between every two rotary conveying belts, two placing grooves are symmetrically formed in two sides of each I-shaped rotating plate, and the tops and the bottoms of the placing grooves can be rotated to be flush with the conveying surface of the conveying assembly.

The beneficial effects of the utility model reside in that:

(1) the utility model discloses a set up the spacing transmission of fretwork chain plate mechanism and be the battery of laminating range, set up radiant heating mechanism and cooperate and set up heat reflection mechanism below fretwork chain plate mechanism, can upwards reflect and assemble on the closed plane that the storage battery upper cover constitutes after the heat radiation out and concentrate and the directional heating, radiant heating mode intensity is big, cooperate heat reflection and battery laminating mode of arranging again to block thermal rise, realize that the heat concentrates the directional heating, the high-usage, shorten curing time and transmission solidification stroke greatly;

(2) the utility model discloses a set up the chain plate mechanism of vertical hollow out construction, it is good to pass through the heat nature, the heat that comes from reflecting easily pierces through hollow out chain plate mechanism, and the secondary battery is mated closely to be laminated and arranged and is formed the closed plane, blocks the heat and can't continue rising, thereby fully collects at the upper cover, improves the directional utilization ratio of heat, and the solidification kiln structure of canceling the cover and establishing helps the battery case to keep the normal atmospheric temperature, the subsequent cooling process of fine trimming, and guarantee the battery product quality;

(3) the utility model discloses a set up radiation heating mechanism and heat reflection mechanism as disjunctor formula structure, specifically, radiation heating mechanism vertically runs through and slidable sets up at heat reflection mechanism, and the distance between radiation heating mechanism and the fretwork chain plate mechanism is adjustable to realize that the heat is strong and weak adjustable, production strong adaptability; in addition, the rack is matched with slide rails corresponding to the heat reflection mechanisms, the heat reflection mechanism frame is arranged on the slide rails and can slide into the lower part of the hollow chain plate mechanism or be pulled out along with the radiation heating mechanism, and the disassembly and the maintenance are convenient;

(4) the utility model has the advantages that the transmission turnover mechanism is arranged at the transition of the solidification transmission end, the storage battery pack which is inverted after solidification is turned over to be output in an upright state in the transmission process, the turnover process is stable, and the matching continuity with the subsequent production process is good;

to sum up, the utility model has the advantages of the heat is directional concentrated, utilization ratio and solidification are efficient, production continuity is good, is particularly useful for the battery production field.

Drawings

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

FIG. 2 is an enlarged view of FIG. 1 at B;

FIG. 3 is a schematic view of the installation structure of the radiant heating mechanism and the heat reflection mechanism of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 1;

FIG. 5 is a top view of the storage battery pack of the present invention in an inverted state;

FIG. 6 is a schematic view of the overall structure of the radiant heating mechanism and the heat reflection mechanism of the present invention;

fig. 7 is a schematic view of the overall structure of the conveying and turning mechanism of the present invention;

fig. 8 is an enlarged view at C in fig. 7.

Detailed Description

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

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Example one

As shown in fig. 1-3, the storage battery dispensing, curing and heating system comprises a frame 100, a rotary conveying mechanism 1 mounted on the frame 100, hollow chain plate mechanisms 2 uniformly mounted on the rotary conveying mechanism 1, a radiation heating mechanism 3 disposed in the middle space of the rotary conveying mechanism 1, a heat reflecting mechanism 4, and a transmission turnover mechanism 5 disposed at the transmission end of the rotary conveying mechanism 1, as shown in fig. 4-5, the storage battery packs 10 glued and arranged one by one are inversely clamped on the hollow chain plate mechanism 2, in the transmission process, heat radiated outwards by the radiation heating mechanism 3 is reflected upwards by the heat reflection mechanism 4 and passes through the hollow chain plate mechanism 2 to perform centralized heating on glue dispensing on the cover body of the storage battery pack 10, and the heated storage battery pack 10 is transmitted to the transmission turnover mechanism 5 and turned over for 180 degrees and then output in an upright state.

In this implementation, be the storage battery 10 that the laminating was arranged through setting up the spacing transmission of fretwork chain plate mechanism 2, set up radiant heating mechanism 3 in fretwork chain plate mechanism 2 below, and further set up heat reflection mechanism 4 in cooperation radiant heating mechanism 3 below, after the radiation of radiant heating mechanism 3 produced the heat, upwards reflect through heat reflection mechanism 4, pass through fretwork department of fretwork chain plate mechanism 2 again, storage battery 10 through closely laminating range blocks, finally assemble on the sealed plane that storage battery 10 upper cover is constituteed and concentrate and the directional heating, the heat is directional concentrated, heating efficiency improves greatly.

It should be noted that, this embodiment adopts the infrared radiation heating mode, compares in traditional electrical heating or steam heating, and its intensity is bigger, and the design of the upwards reflection of deuterogamying heat concentrates upwards to collect the heat, reduces calorific loss, increases operation rate to and utilize the design that battery laminating arrangement structure blockked the heat and rise, realize that the heat is fully concentrated, directional heating, heat utilization rate is high, can shorten the transmission stroke of curing time and solidification greatly.

In addition, this embodiment has cancelled the curing kiln structure that the cover was established above the transmission device, helps battery case to keep the normal atmospheric temperature, is in the cooling state all the time, saves subsequent cooling process, improves production efficiency, and has ensured the quality of battery product.

Further, as shown in fig. 2 and 5, a plurality of the hollow-out chain plate mechanisms 2 are erected around the rotary conveying mechanism 1 for one circle, and include a plurality of vertical chain plates 21 which are arranged at intervals along the conveying direction and are vertically arranged, clamping seats 22 which are respectively fixedly connected with two ends of the vertical chain plates 21 and are installed on the rotary conveying mechanism 1, and at least one group of reinforcing plates 23 which are connected and arranged between two adjacent vertical chain plates 21 and are vertically arranged; as shown in fig. 4, two of the retainer seats 22 can limit and fix two ends of the battery pack 10.

In this embodiment, through the link plate mechanism that sets up hollow out construction, it is concrete, set up the vertical link plate 21 that the interval was arranged and vertical setting and with be the reinforcing plate 23 of vertical setting, a plurality of big fretwork holes have, improve the heat permeability of whole fretwork link plate mechanism 2 greatly, the heat that comes in the reflection easily fully pierces through fretwork link plate mechanism, do not receive and block, it closely laminates to arrange to form and seals the plane and block that the heat continues to rise to cooperate storage battery 10 again, because the battery is placed upside down, its battery upper cover sets up down, thereby it can fully collect in upper cover plane department to collect the heat that rises, heat directional utilization is high.

It should be noted that, a plurality of storage batteries are closely attached one by one in a direction perpendicular to the conveying direction of the rotary conveying mechanism 1 and are arranged upside down to form a storage battery pack 10, an upper cover of the storage battery pack is placed on the vertical chain plate 21, and two side bottoms of the storage battery pack 10 in the width direction are respectively clamped between the front clamping seat 22 and the rear clamping seat 22 for limiting and fixing, so that the heating effect and the conveying stability are improved; the reinforcing plate 23 serves to improve the mechanical strength of the link plate structure.

Further, as shown in fig. 1, the radiation heating mechanisms 3 and the heat reflection mechanisms 4 are in one-to-one correspondence, and a plurality of groups are uniformly distributed along the transmission direction of the rotary conveying mechanism 1.

In this embodiment, the battery pack 10 is transported from one end of the rotary conveying mechanism 1 to the other end transitionally provided with the transport turnover mechanism 5, and a plurality of groups of radiation heating mechanisms 3 and heat reflection mechanisms 4 are uniformly distributed and arranged below the transport path in sequence, so that the transport and heating curing are realized.

Further, as shown in fig. 6, the radiant heating mechanism 3 includes a support 31 and infrared heating pipes 32 uniformly installed on the support 31 and located above the heat reflection mechanism 4, and the width of the heat reflection mechanism 4 is adapted to the length of the infrared heating pipes 32.

In the present embodiment, a plurality of the infrared heating pipes 32 are arranged along the conveying direction of the rotary conveying mechanism 1.

Further, the heat reflection mechanism 4 includes a reflection plate 40 disposed upward, and the reflection plate 40 includes a bottom plate 41 and a side plate 42 disposed around the bottom plate 41.

In the embodiment, the heat reflection mechanism 4 with a disc-shaped structure is arranged to fully block and collect radiant heat and reflect the radiant heat upwards, specifically, the heat generated by the infrared heating pipe 32 is radiated towards the periphery, the bottom plate 41 is arranged to block the heat from flowing downwards to cause loss, the heat can rebound upwards after contacting with the bottom plate 41 to change the radiation spreading direction, the side plates 42 are arranged around the bottom plate 41 for one circle to prevent the heat from flowing towards four sides to cause loss, so that the heat is fully collected towards the middle, the proportion of the heat finally reaching the upper cover of the storage battery is increased, the utilization rate is increased, and energy waste is avoided; the heat reflecting means 4 is preferably made of a material having low thermal conductivity.

Further, as shown in fig. 1 and 7, the conveying and overturning mechanism 5 includes a conveying assembly 51 transitionally connected with the rotary conveying mechanism 1 and an overturning assembly 52 staggered with the conveying assembly 51.

In the embodiment, the transmission turnover mechanism 5 is transitionally arranged at the transmission tail end of the curing transmission production line, so that the storage battery pack 10 which is inverted after curing is turned over to be in an upright state and output in the transmission process, the turnover process is stable, and the matching continuity with the subsequent production process is improved.

Further, the transmission assembly 51 includes two first rotating shafts 511 mounted on the frame 100 and driven by a motor to rotate, and a plurality of rotating transmission belts 512 sleeved on the two first rotating shafts 511 in an array at intervals.

In this embodiment, the two first rotating shafts 511 are provided with a spacing groove at an interval, and each of the rotating transmission belts 512 is disposed in the spacing groove in a spacing manner.

Further, the turnover assembly 52 includes a second rotating shaft 521 mounted on the frame 100 and driven to rotate by a motor, and a plurality of i-shaped rotating plates 522 coaxially fixed and sleeved on the second rotating shaft 521, each i-shaped rotating plate 522 is located between two pairs of the rotating conveyor belts 512, two placing grooves 520 are symmetrically formed in two sides of each i-shaped rotating plate 522, and the top and the bottom of each placing groove 520 can be rotated to be flush with the transmission surface of the transmission assembly 51.

In the present embodiment, the flipping unit 52 is disposed at the middle position of the transmission unit 51; the second rotating shaft 521 is arranged above the conveying surface of the rotary conveying belt 512, and the i-shaped rotating plates 522 are positioned between every two rotary conveying belts 512 and fixedly sleeved on the second rotating shaft 521, so that the second rotating shaft 521 can drive the rotation without interfering with the rotation of the rotary conveying belts 512; the size of the placing groove 520 is matched with the size of the storage battery pack 10, when the placing groove 520 is empty, the bottom of the placing groove 520 is flush with the conveying surface of the conveying assembly 51, so that the inverted storage battery pack 10 can be conveyed into the placing groove 520 through the conveying assembly 51, the overturning assembly 52 drives the storage battery pack 10 to overturn by 180 degrees and then stop rotating, the top of the placing groove 520 is flush with the conveying surface of the conveying assembly 51, and the storage battery pack 10 in an upright state is continuously conveyed and output through the conveying assembly 51.

Example two

For simplicity, only the differences between the second embodiment and the first embodiment will be described below; the second embodiment is different from the first embodiment in that:

further, as shown in fig. 3, a plurality of slide rails 11 are disposed on the rack 100 corresponding to each heat reflection mechanism 4, and bottoms of two ends of each heat reflection mechanism 4 can be respectively erected on the slide rails 11 and drive the radiation heating mechanism 3 to slide in or pull out laterally.

Further, the bracket 31 longitudinally penetrates and is slidably mounted on the heat reflecting mechanism 4, and a lifting adjusting block 30 is disposed on the bracket 31 below the heat reflecting mechanism 4.

In this embodiment, will radiant heating mechanism 3 and heat reflection mechanism 4 set up to disjunctor formula structure, and is concrete, and the four corners position of support 31 vertically runs through and slidable sets up four corners position department on bottom plate 41, and the cooperation corresponds the both ends of each heat reflection mechanism 4 and is provided with slide rail 11 respectively on frame 100, and bottom plate 41 of heat reflection mechanism 4 can erect on slide rail 11 to can take radiant heating mechanism 3 side direction to slide into fretwork chain plate mechanism 2 below or outwards pull out, dismantle convenient and be convenient for maintain.

It should be noted that the support 31 includes two installation muscle that the level set up, infrared heating pipe 32 directly erects on these two installation muscle, still includes the sliding shaft that links to each other and vertical setting with installation muscle both ends, and this sliding shaft runs through bottom plate 41 sets up, in addition, still including setting up and connecting the pull rod that sets up in the sliding shaft lower extreme, the operator holds this pull rod and carries out the sideslip to radiant heating mechanism 3 and heat reflection mechanism 4 of disjunctor formula structure.

As a preferred embodiment, the distance from the infrared heating pipe 32 to the heat reflecting mechanism 4 and the upper cover of the battery pack 10 can be flexibly adjusted by further arranging the lifting adjusting block 30 on the bracket 31 below the heat reflecting mechanism 4, so that the heat intensity can be adjusted, and the production adaptability is strong.

It should be noted that, the lifting adjusting block 30 is sleeved on each sliding shaft, a threaded through hole is formed in the lifting adjusting block 30, an adjusting screw is installed in the threaded through hole in a rotating mode, the adjusting screw can be unscrewed outwards, the position of the radiation heating mechanism 3 can be adjusted longitudinally, the adjusting screw is screwed downwards after adjustment, the end portion of the adjusting screw is in interference fit with the sliding shaft, locking and fixing are achieved, adjustment is convenient, and the structure is stable.

The working process is as follows:

feeding and conveying, wherein the storage battery packs 10 which are glued and arranged in a fitting manner are manually or mechanically grabbed, then are reversely clamped on the hollow chain plate mechanism 2 side by side, and are conveyed to the conveying and overturning mechanism 5 by the rotary conveying mechanism 1; radiation reflection, in the transmission process, after the radiation heating mechanism 3 below the rotary conveying mechanism 1 radiates to generate heat, the heat is reflected upwards by the heat reflection mechanism 4; directionally heating, wherein the reflected heat passes through the hollow part of the hollow chain plate mechanism 2, is blocked by the storage battery pack 10 which is closely attached and arranged, is converged at a closed plane formed by an upper cover of the storage battery pack 10, and is concentrated and directionally heats and cures the resin adhesive on the pole column; and (3) transferring and overturning, wherein the storage battery pack 10 after solidification is transitionally transferred to a transfer and overturning mechanism 5 and further clamped in the placing groove 520, at the moment, the overturning component 52 drives the storage battery pack 10 to overturn for 180 degrees and then stop rotating, and the storage battery pack 10 in the upright state continues to transfer and output. The heat reflection mechanism 4 is arranged on the sliding rail 11 in a sliding way, can slide in or pull out along with the radiation heating mechanism 3, and can adjust the distance between the infrared heating pipe 32 and the heat reflection mechanism 4 as well as the upper cover of the storage battery by adjusting the lifting adjusting block 30.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The storage battery dispensing, curing and heating system comprises a rack (100) and a rotary conveying mechanism (1) arranged on the rack (100), and is characterized by further comprising hollow chain plate mechanisms (2) uniformly distributed on the rotary conveying mechanism (1), a radiation heating mechanism (3) arranged in the middle space of the rotary conveying mechanism (1), a heat reflecting mechanism (4) and a transmission turnover mechanism (5) arranged at the transmission tail end of the rotary conveying mechanism (1);

the storage battery pack (10) which is glued and arranged one by one is reversely clamped on the hollowed-out chain plate mechanism (2), heat radiated outwards by the radiation heating mechanism (3) is upwards reflected by the heat reflection mechanism (4) and passes through the hollowed-out chain plate mechanism (2) to intensively heat glue on a cover body of the storage battery pack (10) in the transmission process, and the storage battery pack (10) which is heated is transmitted to the transmission turnover mechanism (5) and turned over for 180 degrees and then output in a vertical state.

2. The storage battery dispensing, curing and heating system according to claim 1, wherein a plurality of the hollow-out chain plate mechanisms (2) are erected around the rotary conveying mechanism (1) at one circle and comprise a plurality of vertical chain plates (21) which are arranged at intervals along the conveying direction and are vertically arranged, clamping seats (22) which are respectively fixedly connected with two ends of each vertical chain plate (21) and are arranged on the rotary conveying mechanism (1), and at least one group of reinforcing plates (23) which are connected between two adjacent vertical chain plates (21) and are vertically arranged; the two clamping seats (22) can limit and fix two ends of the storage battery pack (10).

3. The storage battery dispensing, curing and heating system according to claim 1, wherein the radiation heating mechanisms (3) and the heat reflection mechanisms (4) are in one-to-one correspondence, and a plurality of groups are uniformly distributed along the transmission direction of the rotary conveying mechanism (1).

4. Storage battery dispensing, curing and heating system according to claim 1, wherein the radiant heating mechanism (3) comprises a support (31) and an infrared heating pipe (32) uniformly installed on the support (31) and located above the heat reflection mechanism (4), and the width of the heat reflection mechanism (4) is adapted to the length of the infrared heating pipe (32).

5. Storage battery spot-gluing curing heating system according to claim 1, wherein the heat reflection mechanism (4) comprises a reflection plate (40) arranged upwards, and the reflection plate (40) comprises a bottom plate (41) and a side plate (42) arranged around the bottom plate (41).

6. The storage battery dispensing, curing and heating system according to claim 1, wherein a plurality of slide rails (11) are disposed on the rack (100) corresponding to the heat reflection mechanisms (4), and bottoms of two ends of each heat reflection mechanism (4) can be respectively erected on the slide rails (11) and drive the radiation heating mechanism (3) to slide in or pull out laterally.

7. The storage battery dispensing, curing and heating system according to claim 4, wherein the bracket (31) is longitudinally penetrated and slidably mounted on the heat reflection mechanism (4), and a lifting adjusting block (30) is arranged on the bracket (31) below the heat reflection mechanism (4).

8. The storage battery dispensing, curing and heating system according to claim 1, wherein the conveying and turning mechanism (5) comprises a conveying assembly (51) transitionally connected with the rotary conveying mechanism (1) and a turning assembly (52) staggered with the conveying assembly (51).

9. The system as claimed in claim 8, wherein the conveying assembly (51) includes two first shafts (511) mounted on the frame (100) and driven by a motor to rotate, and a plurality of rotating belts (512) disposed on the two first shafts (511) in a spaced array.

10. The storage battery dispensing, curing and heating system according to claim 9, wherein the flipping module (52) comprises a second rotating shaft (521) mounted on the rack (100) and driven by a motor to rotate, and a plurality of i-shaped rotating plates (522) coaxially and fixedly sleeved on the second rotating shaft (521), each i-shaped rotating plate (522) is located between two pairs of the rotating conveyor belts (512), two placing slots (520) are symmetrically formed in two sides of each i-shaped rotating plate (522), and the top and the bottom of each placing slot (520) can rotate to be flush with the conveying surface of the conveying module (51).

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