CN115043064A - Turnover equipment - Google Patents

Abstract

The application provides turnover equipment, specifically includes a plurality of turnover subassemblies that framework and interval set up. The frame body comprises a first annular part and a second annular part which are arranged at intervals. At least part of every turnover subassembly is fixed in between first annular portion and the second annular portion, and two adjacent turnover subassemblies press from both sides and establish and form the heat dissipation space, and every turnover subassembly has a plurality of turnover spaces of interval setting, and the turnover space is used for placing and treats the turnover piece. This application sets up through making two adjacent turnover subassemblies interval to make two adjacent turnover subassemblies press from both sides and establish and form the heat dissipation space, place like this in the turnover subassembly treat the heat alright transmission to the heat dissipation space that the turnover piece produced, thereby realize radiating purpose from heat dissipation space transmission to the external world.

Description

Turnover equipment

Technical Field

The application belongs to the technical field of turnover equipment, and particularly relates to turnover equipment.

Background

The turnover equipment is generally used for installing the to-be-turned pieces and transferring the to-be-turned pieces. But the thermal diffusivity of present turnover equipment is relatively poor, treats that the heat of turnover piece can't in time, effectively through turnover equipment effluvium to the performance of turnover piece is treated in the influence.

Disclosure of Invention

In view of this, the present application provides a turnaround device comprising:

the frame body comprises a first annular part and a second annular part which are arranged at intervals;

a plurality of turnover subassemblies that the interval set up, every at least part of turnover subassembly is fixed in first annular portion with between the second annular portion, adjacent two the turnover subassembly presss from both sides and establishes and form heat dissipation space, every the turnover subassembly has a plurality of turnover spaces that the interval set up, the turnover space is used for placing and treats the turnover piece.

The application provides a turnover device is through being fixed in between first annular portion and the second annular portion with a plurality of turnover subassemblies in order to realize fixed to the turnover subassembly. Each turnaround assembly may utilize multiple turnaround spaces to place multiple waiting turnaround pieces. And this application makes two adjacent turnover subassemblies interval setting to make two adjacent turnover subassemblies press from both sides and establish and form the heat dissipation space, place like this in the turnover subassembly treat the heat alright transmit to the heat dissipation space that the turnover piece produced, thereby realize radiating purpose from heat dissipation space transmission to the external world.

To sum up, the turnover equipment that this application provided utilizes heat dissipation space can improve the heat dispersion of turnover equipment, makes the heat of treating the turnover piece in time, effectively through the heat dispersion of turnover equipment, does not influence the performance of treating the turnover piece.

Drawings

In order to more clearly explain the technical solution in the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be described below.

Fig. 1 is a schematic perspective view of a transfer apparatus according to an embodiment of the present disclosure.

Figure 2 is a schematic perspective view of the epicyclic plant of figure 1 from another angle.

Figure 3 is an exploded view of the epicyclic arrangement shown in figure 1.

Figure 4 is a top view of the epicyclic plant shown in figure 1.

Fig. 5 is a schematic perspective view of a transfer apparatus according to another embodiment of the present disclosure.

Figure 6 is a side view of the epicyclic arrangement shown in figure 5.

Fig. 7 is a schematic perspective view of another perspective view of the epicyclic plant shown in fig. 5.

Fig. 8 is a schematic perspective view of another perspective view of the epicyclic plant shown in fig. 1.

Fig. 9 is a front view of a turn-around device in yet another embodiment of the present application.

Fig. 10 is a front view of a turn-around device in yet another embodiment of the present application.

Fig. 11 is a schematic perspective view of a transfer apparatus according to another embodiment of the present application.

Figure 12 is a graph of the temperature of each epicyclic plant at different times.

Description of reference numerals:

the heat dissipation device comprises a turnover device-1, a frame body-10, a first annular part-11, a second annular part-12, a through hole-120, a heat dissipation space-13, a turnover assembly-20, a first side wall-201, a second side wall-202, a first through hole-203, a turnover space-21, a turnover piece-22, a second through hole-220, a supporting piece-23, an elastic layer-30, a convex supporting part-40, an annular supporting part-50, an air inlet space-51, an anti-skid layer-52, a fixing piece-60 and a communication hole-61.

Detailed Description

The following is a preferred embodiment of the present application, and it should be noted that, for those skilled in the art, several improvements and modifications can be made without departing from the principle of the present application, and these improvements and modifications are also considered as the protection scope of the present application.

Before describing the technical problems of the present application, the technical problems of the related art will be described in detail.

The turnover equipment is a common equipment in the actual production process, and is mainly used for placing the to-be-turned over piece, transferring the to-be-turned over piece from one position to another position, transferring the to-be-turned over piece from one working procedure to another working procedure, and carrying out performance test and other operations on the to-be-turned over piece in the turnover equipment. Present turnaround devices typically include a turnaround assembly made of plastic or foam having a plurality of turnaround spaces, each of which can be placed one to be turnaround and then placed in the turnaround. The related art epicyclic assembly has poor heat dissipation. When waiting to have enough to meet need the piece just to prepare the completion or be in operating condition can produce the heat, this heat can't in time be followed turnover equipment and is dispelled, can influence like this and wait each item performance and the life of turnover piece.

In view of the above, in order to solve the above problems, the present application provides a turnover device. Referring to fig. 1 to 4 together, fig. 1 is a schematic perspective view of a transfer apparatus according to an embodiment of the present disclosure. Figure 2 is a schematic perspective view of the epicyclic plant of figure 1 from another angle. Figure 3 is an exploded view of the epicyclic arrangement shown in figure 1. Figure 4 is a top view of the epicyclic plant shown in figure 1. The present embodiment provides a turnover device 1 including a frame 10 and a plurality of turnover assemblies 20 arranged at intervals. The frame 10 includes a first annular portion 11 and a second annular portion 12 spaced apart from each other. At least part of each turnover assembly 20 is fixed between the first annular part 11 and the second annular part 12, two adjacent turnover assemblies 20 are clamped to form a heat dissipation space 13, each turnover assembly 20 is provided with a plurality of turnover spaces 21 arranged at intervals, and the turnover spaces 21 are used for placing pieces to be turned over 22.

The transfer apparatus 1 according to the present embodiment is mainly used for transferring various members to be transferred 22. For example, the to-be-cycled 22 includes, but is not limited to, electronic devices, chips, batteries, engines, and the like. For electronic devices, the electronic devices include, but are not limited to, mobile terminals such as mobile phones, tablet computers, notebook computers, palmtop computers, Personal Computers (PCs), Personal Digital Assistants (PDAs), Portable Media Players (PMPs), navigation devices, wearable devices, smart bands, pedometers, and fixed terminals such as Digital TVs, desktop computers, and the like. The present embodiment does not limit the type of the electronic device. In the present embodiment and the following description, the to-be-turned member 22 is only schematically described as a mobile phone.

The epicyclic arrangement 1 comprises a frame 10 and an epicyclic assembly 20, wherein the frame 10 comprises a first annular part 11 and a second annular part 12 arranged at an interval. The first annular portion 11 and the second annular portion 12 are annular, the first annular portion 11 can surround to form the via 120, and the second annular portion 12 can also surround to form the via 120.

The present embodiment comprises a plurality of epicyclic assemblies 20, and at least part of each epicyclic assembly 20 is fixed between the first and second annular portions 11, 12. In the present embodiment, only a part of the turnaround module 20 is provided between the first annular portion 11 and the second annular portion 12, and a part of the turnaround module 20 is positioned in the through hole 120 between the first annular portion 11 and the second annular portion 12 and connected to the first annular portion 11 and the second annular portion 12, so that the plurality of turnaround modules 20 are fixed and mounted, thereby omitting the turnaround case in the related art and simplifying the structure of the turnaround device 1.

In addition, in the present embodiment, a plurality of the epicyclic components 20 may be disposed at intervals, in other words, two adjacent epicyclic components 20 may be interposed to form the heat dissipation space 13. Alternatively, the width of the heat dissipation space 13 is 50-55mm, i.e. the spacing between two adjacent epicyclic components 20 is 50-55 mm. Specifically, the present embodiment is illustrated with the width of the heat dissipation space 13 being 52 mm. In addition, each turnover assembly 20 has a plurality of turnover spaces 21 arranged at intervals, and each turnover space 21 is used for placing one turnover member 22, so that a plurality of turnover members 22 can be placed in one turnover assembly 20. Alternatively, the arrangement direction of the plurality of turnaround spaces 21 is perpendicular to the arrangement direction of the plurality of heat dissipation spaces 13.

The epicyclic device 1 according to the present embodiment fixes the plurality of epicyclic components 20 between the first annular portion 11 and the second annular portion 12 to fix the epicyclic components 20. Each turnaround assembly 20 may utilize multiple turnaround spaces 21 to house multiple to-be-turnaround components 22. In addition, in the present embodiment, two adjacent turnover assemblies 20 are arranged at intervals, so that the two adjacent turnover assemblies 20 are clamped to form the heat dissipation space 13, and thus, heat generated by the to-be-turned piece 22 placed in the turnover assembly 20 can be transmitted to the heat dissipation space 13, and further transmitted from the heat dissipation space 13 to the outside, so as to achieve the purpose of heat dissipation, and the heat generated by the to-be-turned piece 22 can be easily transmitted to the outside.

In summary, the turnover device 1 provided in this embodiment can improve the heat dissipation performance of the turnover device 1 by using the heat dissipation space 13, so that the heat of the to-be-turned over member 22 can be dissipated timely and effectively through the turnover device 1, and the performance of the to-be-turned over member 22 is not affected.

Referring to fig. 1-2 again, in the present embodiment, the heat dissipation space 13 penetrates at least one of the first annular portion 11, the second annular portion 12, and a peripheral side surface between the first annular portion 11 and the second annular portion 12.

The present embodiment may make the heat dissipation space 13 penetrate at least one region so as to make the heat dissipation space 13 communicate with the outside, that is, the heat dissipation space 13 penetrates at least one of the first annular portion 11, the second annular portion 12, and the peripheral side surface between the first annular portion 11 and the second annular portion 12. Specifically, the heat dissipation space 13 may extend through only any one of the first annular portion 11, the second annular portion 12, and the circumferential side surface between the first annular portion 11 and the second annular portion 12. Or the heat dissipation space 13 may penetrate through the first annular portion 11, the second annular portion 12, and any two of the circumferential side surfaces between the first annular portion 11 and the second annular portion 12. Or the heat dissipation space 13 may penetrate through any three of the first annular portion 11, the second annular portion 12, and the circumferential side surface between the first annular portion 11 and the second annular portion 12. Or the heat dissipation space 13 penetrates four of the first annular portion 11, the second annular portion 12, and the circumferential side surface between the first annular portion 11 and the second annular portion 12. The present embodiment is schematically described with only the heat dissipation space 13 penetrating the first annular portion 11, the second annular portion 12, and four of the circumferential side surfaces between the first annular portion 11 and the second annular portion 12. As shown in fig. 1-2, the heat dissipation space 13 extends through four surfaces, namely the upper surface, the lower surface, the front surface, and the rear surface of the epicyclic gear 1. The heat dissipation performance of the epicyclic equipment 1 is further improved by making the heat dissipation space 13 penetrate and the outside, so that the heat conducted from the members 22 to be circulated into the heat dissipation space 13 is more easily conducted to the outside.

Please refer to fig. 5-6, fig. 5 is a schematic perspective view of a transfer apparatus according to another embodiment of the present application. Figure 6 is a side view of the epicyclic arrangement shown in figure 5. In this embodiment, each of the turnover assemblies 20 includes a first side wall 201 and a second side wall 202 disposed opposite to each other, at least one of the first side wall 201 and the second side wall 202 has a plurality of first through holes 203, and the first through holes 203 are used for communicating the turnover space 21 with the heat dissipation space 13.

Two sidewalls are included for the epicyclic assembly 20: first side wall 201 and second side wall 202, first side wall 201 and second side wall 202 are disposed opposite to each other, and the distance between first side wall 201 and second side wall 202 is greater than or equal to the length of turnover 22, so that turnover 22 can be placed into turnover assembly 20. In this embodiment, a plurality of first through holes 203 may be formed on at least one of the first sidewall 201 and the second sidewall 202. In other words, a plurality of first through holes 203 may be formed in the first sidewall 201, a plurality of first through holes 203 may be formed in the second sidewall 202, or a plurality of first through holes 203 may be formed in both the first sidewall 201 and the second sidewall 202. The present embodiment is only schematically described in the case where a plurality of first through holes 203 are formed in both the first sidewall 201 and the second sidewall 202. The arrangement of first through-hole 203 can communicate turnover space 21 and heat dissipation space 13 that are located the lateral wall both sides, like this when arranging in turnover space 21 treat that turnover 22 produces heat, the heat that is located in turnover space 21 is changeed and is entered into in the heat dissipation space 13 to the follow-up leads to the external world, has further improved turnover equipment 1's heat dispersion.

Referring to fig. 7, fig. 7 is a schematic perspective view of another perspective view of the epicyclic equipment shown in fig. 5. In the present embodiment, the first side wall 201 of the turnover component 20 located at the end side of the turnover components 20 is farther from the heat dissipation space 13 than the second side wall 202, the first side wall 201 has a plurality of first through holes 203, and the first through holes 203 are also used for communicating the outside with the turnover space 21.

As is apparent from the above description, since the plurality of turnaround assemblies 20 are arranged at intervals, the plurality of turnaround assemblies 20 include two turnaround assemblies 20 located at the end side. In other words, the first side wall 201 and the second side wall 202 of the non-end-side epicyclic component 20 are both the epicyclic space 21 and the heat dissipation space 13. However, in the end-side circulation assembly 20, both sides of the first side wall 201 are the circulation space 21 and the outside, and both sides of the second side wall 202 are the circulation space 21 and the heat dissipation space 13, that is, the first side wall 201 is farther from the heat dissipation space 13 than the second side wall 202. When a plurality of first through holes 203 are provided on the first side wall 201, the role of the first through holes 203 at this time is different from that of the first through holes 203 on the first side wall 201 of the epicyclic component 20 located on the non-end side. The first through holes 203 can introduce external air into the circulation space 21, then the air enters the heat dissipation space 13 from the circulation space 21, and finally the air is led to the outside from the heat dissipation space 13, so that air convection from the outside to the inside is formed, and the heat dissipation performance of the circulation equipment 1 is further improved.

Referring to fig. 4 and 8 together, fig. 8 is a schematic perspective view of another perspective view of the epicyclic equipment shown in fig. 1. In this embodiment, each of the turnover assemblies 20 includes a plurality of turnover members 22 arranged at intervals, the turnover members 22 are mounted on the first side wall 201 and the second side wall 202, two adjacent turnover members 22 are sandwiched to form a turnover space 21, each turnover member 22 has a second through hole 220, and the second through hole 220 is used for communicating two adjacent turnover spaces 21.

Each of the turnover assemblies 20 includes a plurality of turnover members 22, the turnover members 22 are mounted on the first side wall 201 and the second side wall 202, and the turnover members 22 are arranged at intervals, so that two adjacent turnover members 22 are sandwiched to form the above-mentioned turnover space 21. The part 22 to be rotated is thus practically confined in the space 21 by the first side wall 201, the second side wall 202 and the two rotating parts 22. Optionally, the direction of the arrangement of the plurality of turnarounds 22 is perpendicular to the direction of the arrangement of the plurality of turnarounds 20.

And the second through hole 220 can be opened on the turnover part 22, and the second through hole 220 can be communicated with two adjacent turnover spaces 21, so that the heat in one turnover space 21 is easier to cause other turnover spaces 21, the heat dissipation performance of the turnover device 1 is improved, the heat distribution of a plurality of turnover spaces 21 in each turnover assembly 20 is uniform, and the problem of over concentration of the heat in the individual turnover spaces 21 is prevented.

Optionally, each turnaround assembly 20 further comprises a support 23, the support 23 connecting the first side wall 201 and the second side wall 202, the support 23 being configured to support the to-be-turnaround 22.

Referring to fig. 8 again, in the present embodiment, the end-side one of the plurality of the turnover members 22 also has the second through hole 220, and the second through hole 220 is also used for communicating the outside with the turnover space 21.

As is apparent from the above description, since the plurality of turnarounds 22 are arranged at intervals, the plurality of turnarounds 22 include two turnarounds 22 located on the end side. In other words, the non-end-side turnaround part 22 is flanked by turnaround spaces 21. However, the turnaround space 21 and the outside are on both sides of the end-side turnaround piece 22. When the second through holes 220 are also provided in the end-side turnaround member 22, and the second through holes 220 have different functions from the second through holes 220 in the non-end-side turnaround member 22, the second through holes 220 on the end side can introduce external air into the turnaround space 21, and then the external air enters the heat dissipation space 13 from the turnaround space 21, and finally the external air is induced from the heat dissipation space 13, so that air convection from the outside to the inside is formed, and the heat dissipation performance of the turnaround device 1 is further improved.

Referring again to fig. 1, each of the turnaround spaces 21 extends through at least one of the first annular portion 11 and the second annular portion 12.

The heat dissipation space 13 may also extend through at least one of the first annular portion 11 and the second annular portion 12, as may the turnaround space 21. In other words, the turnaround space 21 may extend through the first annular portion 11, or the turnaround space 21 may extend through the second annular portion 12, or the turnaround space 21 may extend through both the first and second annular portions 11, 12. In the present embodiment, only the turnaround space 21 penetrates the first annular portion 11 and the second annular portion 12, and as shown in fig. 1, the turnaround space 21 penetrates the upper surface and the lower surface of the turnaround device 1. Therefore, heat generated by the to-be-circulated part 22 in the circulation space 21 can not only cause the heat dissipation space 13 to dissipate heat, but also can dissipate heat of the circulation space 21, and the heat dissipation performance of the circulation equipment 1 is further improved. And the turnover space 21 penetrating up and down can provide a foundation for subsequent stack heat dissipation. The stacking heat dissipation is that a plurality of turnover devices 1 are stacked together, a first annular part 11 of one turnover device 1 is close to a second annular part 12 of another turnover device 1, so that turnover spaces 21 of the turnover devices 1 can be communicated up and down, and a plurality of heat dissipation spaces can be communicated up and down to form a complete, through and larger-size space, so that heat can be dissipated more easily.

Referring again to fig. 1, in this embodiment, the epicyclic arrangement 1 further comprises an elastic layer 30, the elastic layer 30 covering at least part of the epicyclic component 20.

The epicyclic arrangement 1 may comprise, in addition to the above mentioned components, an elastic layer 30, the elastic layer 30 being able to coat at least part of the epicyclic assembly 20. In which the elastic layer 30 is a structure having a certain elasticity, and can be formed through an encapsulation process. The silica gel process can be a process of coating a layer of silica gel on the surface of a product under the conditions of high-temperature high-pressure vulcanization and vacuum after plastic injection molding is carried out. Thus, when the member 22 is placed in the turnaround space 21, it is the elastic layer 30 that abuts the member 22 rather than the first side wall 201, the second side wall 202, and the turnaround member 22. Therefore, collision of the members to be rotated 22 can be prevented, and the members to be rotated 22 are effectively protected.

Referring to fig. 9, fig. 9 is a front view of a transferring apparatus according to another embodiment of the present application. In the present embodiment, a plurality of protrusion support portions 40 are disposed on a side of the second annular portion 12 away from the first annular portion 11.

In this embodiment, a plurality of protruding support portions 40 may be disposed on a side of the second annular portion 12 away from the first annular portion 11, and the protruding support portions 40 and the second annular portion 12 may be of an integrated structure or a split structure. The arrangement of the convex supporting portion 40 can prevent the second annular portion 12 from directly contacting a place when the turnover device 1 is placed at the place, but the convex supporting portion 40 contacts the place, and at this time, the second annular portion 12 can form a gap with the place, so that air enters the heat dissipation space 13 and/or the turnover space 21 from below, air convection from bottom to top is formed, and the heat dissipation performance of the turnover device 1 is further improved.

For example, when the epicyclic device 1 is placed on the ground, the second annular portion 12 is spaced from the ground by the raised support 40, so that air can enter the heat dissipation space 13 and the epicyclic space 21 through the gap between the ground and the second annular portion 12, creating air convection. Or when one turnover device 1 is placed on another turnover device 1, the second annular part 12 of one turnover device 1 and the first annular part 11 of the other turnover device 1 are supported and fixed through the convex supporting part 40, and the two annular parts are arranged at intervals, so that air can enter the heat dissipation space 13 and the turnover space 21 through the gap between the two annular parts to form air convection.

Referring to fig. 2 and 10 together, fig. 10 is a front view of a transfer apparatus according to another embodiment of the present application. In this embodiment, an annular support portion 50 is disposed on a side of the second annular portion 12 away from the first annular portion 11, the annular support portion 50 is connected to the second annular portion 12, and the annular support portion 50 and the second annular portion 12 form an air inlet space 51 in an interposed manner.

In addition to the raised support 40 described above, the present application provides another embodiment. The annular supporting portion 50 may be disposed on a side of the second annular portion 12 away from the first annular portion 11, the annular supporting portion 50 and the second annular portion 12 are disposed at an interval, and the annular supporting portion 50 is connected to the second annular portion 12, so that the annular supporting portion 50 and the second annular portion 12 can be sandwiched to form the air inlet space 51, when the turnover device 1 is placed at a certain position, the second annular portion 12 is prevented from directly contacting the certain position, but the protrusion supporting portion 40 is contacted with the certain position, and at this time, the second annular portion 12 can form a gap with the certain position, so that air enters the heat dissipation space 13 and/or the turnover space 21 from below, air convection from bottom to top is formed, and the heat dissipation performance of the turnover device 1 is further improved.

For example, when the epicyclic plant 1 is placed on the ground, the second annular portion 12 is spaced from the ground by the annular support 50, so that air can enter the heat dissipation space 13 and the epicyclic space 21 through the gap between the ground and the second annular portion 12, creating air convection. Or when one turnover device 1 is placed on another turnover device 1, the second annular part 12 of one turnover device 1 and the first annular part 11 of the other turnover device 1 are supported and fixed through the convex supporting part 40, and the two annular parts are arranged at intervals, so that air can enter the heat dissipation space 13 and the turnover space 21 through the gap between the two annular parts to form air convection.

Alternatively, the second annular portion 12 and the annular support portion 50 may be connected by a plurality of support posts spaced apart from each other, so that the air inlet space 51 may be formed also at the side, further improving the convection effect.

Optionally, an anti-slip layer 52 may be provided on the side of the annular support 50 facing away from the second annular portion 12 to improve stability when stacking a plurality of epicyclic devices 1.

Referring to fig. 11, fig. 11 is a schematic perspective view of a transfer apparatus according to another embodiment of the present disclosure. In this embodiment, a stabilizing member 60 may be further included, and the stabilizing member 60 is disposed in the heat dissipation space 13 and connects two adjacent turnover assemblies 20. In particular steady 60 is connected at one end to a first side wall 201 of one epicyclic assembly 20 and at the other end to a second side wall 202 of the other epicyclic assembly 20. Two adjacent turnaround assemblies 20 may be secured together with a securing member 60 to prevent the turnaround assemblies 20 from wobbling. Optionally, the fixing member 60 has a communication hole 61 for communicating the heat dissipation space 13 with the outside, so that the heat dissipation performance is not affected upon addition of the fixing member 60.

In addition to introducing the structure of the above-described epicyclic plant 1, the present application also provides a performance test for the above-described epicyclic plant 1. In particular, the present embodiment provides 3 epicyclic arrangements 1, 3 epicyclic arrangements 1 stacked, each epicyclic arrangement 1 comprising 3 epicyclic components 20, each epicyclic component 20 having 13 epicyclic spaces 21. This test was temperature tested for 13 turnaround spaces 21 in the intermediate turnaround assembly 20 and the temperature of the 13 turnaround spaces 21 at different temperatures averaged. This is because the circulation assemblies 20 located on both sides are in contact with the outside of the peripheral side, and the heat dissipation effect is better, so the test measures the middle circulation assembly 20 with a slightly inferior heat dissipation effect. The specific structure is shown in table 1 and fig. 12. Figure 12 is a graph of the temperature profile of each epicyclic plant at different times.

TABLE 1 temperatures of the various transfer devices at different times

The upper layer, the middle layer and the lower layer in table 1 refer to the uppermost turnover device 1, the middle turnover device 1 and the lowermost turnover device 1. Initial refers to the temperature before testing has not begun, and before entering the dump interface. The present application measures the average temperature of the intermediate turnaround component 20 in each turnaround facility 1 from 0.5-4 hours without taking one half hour to take a temperature measurement.

As can be seen from table 1 and fig. 12, the temperature of the transfer device 1 of any layer gradually increases from the start of the test, but does not increase sharply after 4 hours, and the temperature fluctuates between 37.3 and 40.1 degrees, so that the heat can be dissipated normally. Compared with the prior art, the temperature of the circulation device 1 reaches 60 degrees within 1h or 2h and is gradually increased subsequently, the circulation device 1 provided by the application has excellent heat dissipation performance. In addition, as seen from the three-layer circulation device 1, due to the arrangement of the convex support part 40 or the annular support part 50, the temperature difference of each layer is not large, and the situation that the circulation device 1 in the middle layer has excessive temperature does not occur.

In conclusion, the turnover equipment 1 provided by the application can realize good heat dissipation, heat can be dissipated even after stacking, static heat rises through the heat dissipation channel, the heat is relatively balanced with the heat dissipation, the heat is guided and avoided, and high-temperature accumulation is avoided, so that harmful temperature is reached.

The foregoing detailed description has provided for the embodiments of the present application, and the principles and embodiments of the present application have been presented herein for purposes of illustration and description only and to facilitate understanding of the methods and their core concepts; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (10)

1. An epicyclic apparatus, comprising:

the frame body comprises a first annular part and a second annular part which are arranged at intervals;

a plurality of turnover subassemblies that the interval set up, every at least part of turnover subassembly is fixed in first annular portion with between the second annular portion, adjacent two the turnover subassembly presss from both sides and establishes and form heat dissipation space, every the turnover subassembly has a plurality of turnover spaces that the interval set up, the turnover space is used for placing and treats the turnover piece.

2. The epicyclic apparatus of claim 1 wherein said heat dissipation space extends through at least one of said first annular portion, said second annular portion, and a peripheral side surface between said first annular portion and said second annular portion.

3. The epicyclic apparatus of claim 1 wherein each said epicyclic assembly comprises oppositely disposed first and second side walls, at least one of said first and second side walls having a plurality of first through holes for communicating said epicyclic space with said heat dissipation space.

4. The epicyclic apparatus of claim 3 wherein said first sidewall of said epicyclic assembly on an end side of said plurality of epicyclic assemblies is further from said heat dissipation space than said second sidewall, said first sidewall having a plurality of said first through holes, said first through holes also serving to communicate the external world with said epicyclic space.

5. The epicyclic apparatus of claim 3 wherein each said epicyclic assembly comprises a plurality of said epicyclic members disposed at intervals, said epicyclic members being mounted to said first side wall and said second side wall, and two adjacent said epicyclic members being sandwiched to form an epicyclic space, said epicyclic member having a second through hole for communicating two adjacent said epicyclic spaces.

6. The epicyclic apparatus of claim 5 wherein said end side of said plurality of epicyclic members also has said second through-hole, said second through-hole also serving to communicate the external world with said epicyclic space.

7. The epicyclic apparatus of claim 1 wherein each said epicyclic space extends through at least one of said first annulus and said second annulus.

8. The epicyclic device of claim 1 further comprising an elastomeric layer covering at least a portion of said epicyclic assembly.

9. The epicyclic apparatus of claim 1 wherein a side of said second annular portion facing away from said first annular portion is provided with a plurality of boss supports.

10. The epicyclic apparatus of claim 1 wherein a side of said second annular portion facing away from said first annular portion is provided with an annular support portion, said annular support portion being connected to said second annular portion, and said annular support portion and said second annular portion being interposed to form an air intake space.

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