CN114446332A - Engineering cost data management storage module heat dissipation case - Google Patents

Abstract

The invention relates to a storage module heat dissipation box, in particular to a project cost data management storage module heat dissipation box which comprises a base, a large annular plate, fans and the like, wherein the top of the base is fixedly connected with the large annular plate along the circumferential direction, the front side and the rear side of the lower part of the large annular plate are arranged in an open mode, and nine fans for dissipating heat of a storage module are fixedly penetrated and connected on the upper part of the large annular plate at uniform intervals along the circumferential direction. When an operator puts the storage module into the discharging mechanism, the fan can be started, the fan pumps hot air out of the large circular plate, cold air is discharged into the discharging mechanism through the opening of the large circular plate to dissipate heat of the storage module, when the discharging mechanism is required to be used, the material pushing mechanism can be pulled to drive the discharging mechanism to move upwards, the discharging mechanism drives the storage module to move upwards to a proper position, and the required storage module can be taken out, so that the heat of the storage module can be dissipated, and the storage module is prevented from being burnt out due to high heat.

Description

Engineering cost data management storage module heat dissipation case

Technical Field

The invention relates to a storage module heat dissipation box, in particular to a project cost data management storage module heat dissipation box.

Background

Among the engineering cost, people can take notes data, and the data of taking notes are deposited in storage module and are managed again, and the data to the demand after the convenience are drawed and are used, and at present, there are following problems in the storage module use: because data are stored and extracted continuously, the storage module can operate continuously to generate a very hot phenomenon, the storage module is very hot for a long time and is easy to burn out, and the storage module cannot be used to cause data loss.

Therefore, it is necessary to design and develop a heat dissipation box for engineering cost data management storage module, which can dissipate heat of the storage module and avoid data loss caused by burning-out.

Disclosure of Invention

The invention provides a heat dissipation box of a project cost data management storage module, which can dissipate heat of the storage module and avoid data loss caused by the phenomenon of burning out, so as to overcome the defects that the storage module can be burnt out due to the phenomenon of continuous storage and extraction of data, and the storage module cannot be used to cause data loss.

The invention is realized by the following technical approaches:

the utility model provides an engineering cost data management storage module heat dissipation case, including base, big annular plate, fan, drop feed mechanism and pushing equipment, the base top has big annular plate along the circumference rigid coupling, both sides are uncovered setting around big annular plate lower part, big annular plate upper portion along the even spaced fixed wearing of circumference have been connected and are used for carrying out radiating nine fans to storage module, install the drop feed mechanism that is used for storage module to place on the big annular plate, the last pushing equipment that installs of drop feed mechanism.

Further, drop feed mechanism is including disc, little annular plate, place frame and heat radiation fins, and big annular plate inboard upper portion has the disc along circumference rigid coupling, has worn to connect along the even spaced slidingtype of circumference on the disc and has been used for eighteen of storage module to place the frame, places frame lateral surface lower part and installs the heat radiation fins who is used for playing the radiating effect, and the fixed cross-under in disc middle part has little annular plate, and little annular plate is connected with pushing equipment.

Further, pushing equipment includes annular knob, montant, scraping wings and ring baffle, and eighteen scraping wings that are used for driving heat radiation fins rebound have been worn to connect along the even spaced slidingtype of circumference in ringlike plate lower part, and the scraping wings corresponds with placing the frame, and the rigid coupling has the ring baffle between all scraping wings inner, and ring baffle top is connected with four montants along circumference slidingtype, and the rigid coupling has annular knob between four montant tops.

Further, still including being used for placing the closing mechanism that the frame blocked, closing mechanism is including porous dish, the swing board, the annular strip, the guide block, gear and rack, big annular plate top has porous dish along the circumference rigid coupling, the downthehole symmetrical formula's of porous dish rotary type has worn to connect and is used for placing the swing board that the frame blocked, the downthehole swing board quantity of every of porous dish is two, every two swing boards correspond with every frame of placing, the axle rear end rigid coupling of swing board has the gear, little annular plate top is connected with the guide block along circumference slidingtype, the rigid coupling has the annular strip between four guide block lateral surface upper portions, the gear is located the annular strip, annular strip top and bottom all evenly spaced rigid coupling have and are used for driving eighteen racks of gear inward rotation, the crisscross setting of upper and lower both sides rack.

Further, the device also comprises a pushing mechanism for driving the placing frame to move, the pushing mechanism comprises L-shaped guide blocks, a rotary circular plate, an inner six-diamond-shaped frame, a first L-shaped plate, a first circular plate, a first u-shaped push plate, a second L-shaped plate, a second circular plate and a second u-shaped push plate, the bottom of the small circular plate is connected with the six L-shaped guide blocks in a sliding mode along the circumferential direction, the rotary circular plate is fixedly connected between the tail ends of the six L-shaped guide blocks, two groups of L-shaped guide grooves are formed in the outer side of the rotary circular plate along the circumferential direction, the number of the L-shaped guide grooves in each group is two, the two L-shaped guide grooves in each group are symmetrically arranged, the second u-shaped push plates are fixedly connected between the upper parts of the outer two side surfaces of nine placing frames, the second circular plate is fixedly connected between the bottom ends of all the second u-shaped push plates, the bottom of the second circular plate is fixedly connected with two second L-shaped plates along the circumferential direction, the two second L-shaped plates are symmetrically arranged, and the two second L-shaped guide grooves are positioned in the inner ends of the two L-shaped guide plates, the outer two sides of the other nine placing frames are fixedly connected with first u-shaped push plates, the bottom ends of all the first u-shaped push plates are fixedly connected with first circular ring plates, the bottom of each first circular ring plate is fixedly connected with a first L-shaped plate, the inner ends of the two first L-shaped plates are located in the other two L-shaped guide grooves, the rotating circular ring plate is circumferentially provided with two six diamond holes, the two six diamond holes are symmetrically arranged, and the upper part of the inner side of the rotating circular ring plate is circumferentially and fixedly connected with an inner six diamond frame.

Further, still including being used for playing the complementary unit of auxiliary action, complementary unit is including the carriage, the annular fixed plate, the round block, the hexagonal rhombus actuating lever, slider and trigger bar, the medial surface middle part rigid coupling of guide block medial surface has the trigger bar, the cross-under of interior hexagonal rhombus frame slidingtype has the hexagonal rhombus actuating lever, hexagonal rhombus actuating lever top is passed little annular plate and is located annular knob, hexagonal rhombus actuating lever top rigid coupling has the carriage, the carriage contacts with annular knob inner wall, the rigid coupling has the annular fixed plate between four ends of carriage bottom, annular fixed plate bottom rigid coupling has nine sliders, the cover of slidingtype between nine sliders is equipped with the round block, the round block lower part is located little annular plate, the round block outside is opened along circumference interval and is used for driving four L type grooves of trigger bar rebound, the trigger bar inner is located L type inslot.

Further, including perforated plate and drive column, being connected with of the inboard rotary type in big shaped plate lower part is arranged in carrying out filterable perforated plate to the impurity in the air, and both sides middle part is all fixed to have worn to connect the drive column around the perforated plate, drive column inner and rotatory annular plate lateral surface fixed connection.

Further, still including L type brush piece and spring, the embedded sliding connection that the left and right sides lower part all evenly spaced in the big annular plate has the L type brush piece that is used for driving impurity on the perforated plate, and L type brush piece and perforated plate contact, the rigid coupling has the spring between L type brush piece outer end and the big annular plate is inboard.

Compared with the prior art, the invention has the remarkable improvements that:

1. when operating personnel put into drop feed mechanism with storage module in, can start the fan, the hot-air of fan in with big annular plate is taken out, cold air then dispels the heat to storage module through the uncovered department of big annular plate row, when needing to use, can pull pushing equipment and drive drop feed mechanism rebound, drop feed mechanism drives storage module rebound to suitable position, can take out the storage module of demand, so, can dispel the heat to storage module, avoid storage module very hot to cause to burn out.

2. When the storage module is placed into the placing frame, the closing mechanism can block the placing frame, and when the storage module needs to be taken out, the closing mechanism is pulled to operate and does not block the placing frame, so that the storage module can be prevented from being broken by falling foreign matters into the placing frame.

3. Can put according to the storage module of demand and place frame interior pulling pushing mechanism function in which, the pushing mechanism function drives nine and places frame rebound, just also drives the storage module rebound of demand to suitable position, so, can avoid placing the storage module that the whole rebound of frame leads to operating personnel inconvenient to take out the demand.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a first partial cross-sectional structural schematic of the present invention.

FIG. 3 is a second partial cross-sectional structural schematic of the present invention.

Fig. 4 is a schematic perspective view of the pushing mechanism of the present invention.

Fig. 5 is a schematic view of a first partial body structure of the pushing mechanism of the present invention.

Fig. 6 is a schematic view of a second partial body structure of the pushing mechanism of the present invention.

Fig. 7 is a perspective view of a third part of the pushing mechanism of the present invention.

Fig. 8 is a third partial sectional structural schematic of the present invention.

Fig. 9 is an enlarged schematic view of part a of the present invention.

FIG. 10 is a schematic view of a first partial body structure according to the present invention.

Fig. 11 is a partial perspective view of the auxiliary mechanism of the present invention.

Fig. 12 is a fourth partial sectional structural view of the present invention.

FIG. 13 is a schematic view of a second partial body structure according to the present invention.

FIG. 14 is an enlarged view of part B of the present invention.

Reference numbers in the drawings: 1_ base, 2_ large circular plate, 3_ fan, 4_ discharge mechanism, 41_ disc, 42_ small circular plate, 43_ placing frame, 44_ heat dissipation fin, 5_ pushing mechanism, 51_ circular knob, 52_ vertical bar, 53_ pushing plate, 54_ circular guide plate, 6_ closing mechanism, 61_ porous disc, 62_ swinging plate, 63_ circular bar, 64_ guide block, 65_ gear, 66_ rack, 7_ pushing mechanism, 71_ L type guide block, 72_ rotary circular plate, 73_ inner six diamond frame, 74_ L type guide slot, 75_ first L type plate, 76_ first circular plate, 77_ first u type push plate, 78_ second L type plate, 79_ second circular plate, 710_ second u type push plate, 711_ six diamond hole, 8_ auxiliary mechanism, 81_ sliding frame, 82_ circular fixing plate, 83_ circular block, 84_ six diamond hole, 85_ L type groove, 86_ slide block, 87_ trigger lever, 9_ perforated plate, 10_ drive column, 12_ L type brush block, 13_ spring.

Detailed Description

The invention is further explained by combining the drawings in the specification, and the embodiments of the invention are given by combining the drawings in the specification.

Example 1

The utility model provides an engineering cost data management storage module heat dissipation case, including base 1, big ring plate 2, fan 3, drop feed mechanism 4 and pushing equipment 5, please refer to fig. 1, fig. 2, fig. 3 and fig. 8 show, big ring plate 2 is installed through welded connection's mode along circumference in the top of base 1, both sides are uncovered setting around big ring plate 2 lower part, nine fans 3 have been worn to connect along the even spaced fixed wearing of circumference in big ring plate 2 upper portion, when fan 3 starts, fan 3 can dispel the heat to storage module, install drop feed mechanism 4 on big ring plate 2, operating personnel can put into drop feed mechanism 4 with appropriate amount storage module in, install pushing equipment 5 on drop feed mechanism 4, when needs put into storage module or take out, pulling pushing equipment 5 can drive drop feed mechanism 4 and operate.

The discharging mechanism 4 comprises a disc 41, a small annular plate 42, a placing frame 43 and radiating fins 44, please refer to fig. 2 and fig. 3, the disc 41 is installed on the upper portion of the inner side of the large annular plate 2 along the circumferential direction in a welding connection mode, eighteen placing frames 43 are connected on the disc 41 along the circumferential direction in a sliding type cross-connection mode at uniform intervals, an operator can place a storage module into the placing frame 43, the radiating fins 44 are installed on the lower portion of the outer side face of the placing frame 43, the radiating fins 44 are used for better radiating the placing frame 43, the small annular plate 42 is fixedly connected to the middle of the disc 41 in a cross-connection mode, and the small annular plate 42 is connected with the pushing mechanism 5.

The pushing mechanism 5 includes an annular knob 51, vertical rods 52, pushing plates 53 and a circular guide plate 54, please refer to fig. 1, 2, 3 and 8, eighteen pushing plates 53 are slidably connected to the lower portion of the small annular plate 42 at uniform intervals along the circumferential direction, when the pushing plates 53 move upward, the pushing plates 53 can drive the heat dissipation fins 44 to move upward, the pushing plates 53 correspond to the placement frame 43, the circular guide plates 54 are installed between the inner ends of all the pushing plates 53 in a welding connection manner, the top of the circular guide plate 54 is connected with four vertical rods 52 in a sliding manner along the circumferential direction, the annular knob 51 is installed between the top ends of the four vertical rods 52 in a welding connection manner, and an operator can pull the annular knob 51 to drive the vertical rods 52 to move upward.

At first in the drop feed mechanism 4 is put into with appropriate amount storage module to operating personnel, and then storage module is when the use, the phenomenon that generates heat can appear along with continuous use to storage module, restart fan 3, the hot-air suction in the fan 3 function is with big annular plate 2, outside cold air then discharges through two openings of big annular plate 2 and dispels the heat to the storage module in drop feed mechanism 4, so relapse, can make big annular plate 2 hot-air constantly taken out, cold air constantly discharges and dispels the heat to storage module. When the storage module needs to be taken out, the material pushing mechanism 5 can be pulled to move upwards, the material pushing mechanism 5 moves upwards to drive the material placing mechanism 4 to move upwards, the material placing mechanism 4 moves upwards to drive the storage module to move upwards, when the storage module moves upwards to a proper position, the material pushing mechanism 5 stops being pulled, the material pushing mechanism 5 stops driving the storage module to move upwards through the material placing mechanism 4, the required storage module can be taken out for checking, after the required storage module is taken out, the material pushing mechanism 5 is loosened, the material pushing mechanism 5 moves downwards to reset to drive the material placing mechanism 4 to move downwards, the material placing mechanism 4 moves downwards to reset to drive the rest storage modules to move downwards to reset, and when the storage module needs to be placed in, the storage module can be directly placed into the material placing mechanism 4. When a storage module is not placed in the drop feed mechanism 4, the fan 3 may be turned off.

Firstly, an operator can put eighteen storage modules into eighteen placing frames 43 for management, when the fan 3 is started, hot air in the large circular plate 2 is continuously sucked, cold air is continuously sucked into the storage modules for heat dissipation, the heat dissipation fins 44 can improve the heat dissipation effect, the storage modules can be better dissipated, when the storage modules need to be used, the pushing mechanism 5 can be pulled to move upwards, the pushing mechanism 5 moves upwards to drive the heat dissipation fins 44 to move upwards, the heat dissipation fins 44 move upwards to drive the placing frames 43 to move upwards, the placing frames 43 move upwards to drive the storage modules to move upwards, when the storage modules move upwards to a proper position, the pushing mechanism 5 is stopped to be pulled, the pushing mechanism 5 stops driving the heat dissipation fins 44 to move upwards, the placing frames 43 stop driving the storage modules to move upwards, and then the required storage modules can be taken out of the placing frames 43, after the storage module of demand is taken out from placing frame 43, loosen pushing equipment 5, because of the effect of gravity, pushing equipment 5 moves down and resets and does not carry out spacing to heat radiation fins 44, and heat radiation fins 44 move down and drive and place frame 43 and move down and reset, and place frame 43 and move down and reset and drive storage module and move down and reset, when needing to place the storage module, can directly put back the storage module in placing frame 43.

When a required storage module needs to be taken out, the annular knob 51 can be pulled to move upwards, the annular knob 51 moves upwards to drive the vertical rod 52 to move upwards, the vertical rod 52 moves upwards to drive the annular guide plate 54 to move upwards, the annular guide plate 54 moves upwards to drive the material pushing plate 53 to move upwards, the material pushing plate 53 moves upwards to drive the heat dissipation fins 44 to move upwards, so that the placing frame 43 drives the storage module to move upwards, when the storage module moves upwards to a proper position, the annular knob 51 stops being pulled, the required storage module can be taken out from the placing frame 43, the annular knob 51 is released, due to the action of gravity, the annular guide plate 54 moves downwards to reset, the annular knob 51 is driven by the vertical rod 52 to move downwards to reset, the annular guide plate 54 moves downwards to drive the material pushing plate 53 to move downwards to reset, the material pushing plate 53 resets without limiting the heat dissipation fins 44, the heat dissipation fins 44 drive the placing frame 43 to move downwards to reset, the placing frame 43 drives the storage module to move downwards for resetting. Therefore, the operator can conveniently take the required storage module out of the placing frame 43.

Example 2

On the basis of embodiment 1, the sealing mechanism 6 further comprises a porous disc 61, a swinging plate 62, an annular strip 63, a guide block 64, a gear 65 and a rack 66, as shown in fig. 1, 2, 8, 12, 13 and 14, the porous disc 61 is installed at the top of the large annular plate 2 along the circumferential direction in a bolt connection manner, the swinging plate 62 is symmetrically and rotatably penetrated in the hole of the porous disc 61, the number of the swinging plates 62 in each hole of the porous disc 61 is two, each two swinging plates 62 correspond to each placing frame 43, the gear 65 is installed at the rear end of the shaft of each swinging plate 62 in a welding connection manner, the guide block 64 is connected at the top of the small annular plate 42 along the circumferential direction in a sliding manner, the annular strip 63 is fixedly connected between the upper parts of the outer side surfaces of the four guide blocks 64, the gear 65 is located in the annular strip 63, eighteen racks 66 are installed at the top and the bottom of the annular strip 63 at even intervals in a welding connection manner, the racks 66 on the upper and lower sides are arranged in a staggered manner, and when the racks 66 rotate reversely, the racks 66 can drive the gears 65 to rotate inwards.

The pushing mechanism 7 is further included, the pushing mechanism 7 includes an L-shaped guide block 71, a rotary circular plate 72, an inner six diamond-shaped frame 73, a first L-shaped plate 75, a first circular plate 76, a first u-shaped push plate 77, a second L-shaped plate 78, a second circular plate 79 and a second u-shaped push plate 710, please refer to fig. 2, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8 and fig. 12, the bottom of the small circular plate 42 is connected with the six L-shaped guide blocks 71 in a sliding manner along the circumferential direction, the rotary circular plate 72 is installed between the tail ends of the six L-shaped guide blocks 71 in a welding connection manner, two sets of L-shaped guide grooves 74 are formed on the outer side of the rotary circular plate 72 along the circumferential direction, the number of each set of L-shaped guide grooves 74 is two, and each set of two L-shaped guide grooves 74 are symmetrically arranged, wherein the second u-shaped push plates 710 are installed between the upper portions of the outer two side faces of the nine placing frames 43 in a welding connection manner, the second u-shaped push plates 710 are installed between the bottom ends of all the second u-shaped push plates in a welding connection manner, two second L-shaped plates 78 are arranged at the bottom of a second circular plate 79 in a circumferential direction in a bolt connection mode, the two second L-shaped plates 78 are symmetrically arranged, the inner ends of the two second L-shaped plates 78 are positioned in the two L-shaped guide grooves 74, when the L-shaped guide grooves 74 rotate, the L-shaped guide grooves 74 can drive the second L-shaped plates 78 to move, a first u-shaped push plate 77 is arranged between the outer two side surfaces of the other nine placing frames 43 in a welding connection mode, first circular plates 76 are arranged between the bottom ends of all the first u-shaped push plates 77 in a welding connection mode, first L-shaped plates 75 are arranged at the bottom of the first circular plates 76 in a bolt connection mode, the inner ends of the two first L-shaped plates 75 are positioned in the other two L-shaped guide grooves 74, when the L-shaped guide grooves 74 rotate, the L-shaped guide grooves 74 can drive the first L-shaped plates 75 to move, two hexagonal holes 711 are formed in the circumferential direction on the rotary circular plate 72, the two hexagonal diamond holes 711 are symmetrically arranged, when an operator inserts a hexagonal diamond rod into the hexagonal diamond holes 711, the hexagonal diamond rod can be pulled to drive the rotating circular plate 72 to rotate, and the inner hexagonal diamond frame 73 is installed on the upper portion of the inner side of the rotating circular plate 72 in a welding connection mode along the circumferential direction.

The auxiliary mechanism 8 further comprises an auxiliary mechanism 8, the auxiliary mechanism 8 comprises a sliding frame 81, an annular fixed plate 82, a circular block 83, a hexagonal prism driving rod 84, a sliding block 86 and a triggering rod 87, please refer to fig. 1, fig. 2, fig. 8, fig. 10, fig. 11, fig. 12 and fig. 13, the triggering rod 87 is installed at the middle part of the inner side surface of the guide block 64 in a bolt connection mode, the hexagonal prism driving rod 84 is connected in the inner hexagonal prism frame 73 in a sliding mode in a penetrating mode, the top end of the hexagonal prism driving rod 84 penetrates through the small annular plate 42 and is located in the annular knob 51, when the hexagonal prism driving rod 84 rotates, the hexagonal prism driving rod 84 can drive the inner hexagonal prism frame 73 to rotate, the sliding frame 81 is installed at the top end of the hexagonal prism driving rod 84 in a welding connection mode, the sliding frame 81 is in contact with the inner wall of the annular knob 51, the annular fixed plate 82 is installed between the four ends of the bottom of the sliding frame 81 in a welding connection mode, the nine sliding block 86 is installed at the bottom of the annular fixed plate 82 in a bolt connection mode, the nine sliding blocks 86 are sleeved with round blocks 83 in a sliding mode, the lower portions of the round blocks 83 are located in the small annular plate 42, four L-shaped grooves 85 are formed in the outer sides of the round blocks 83 at intervals along the circumferential direction, the inner ends of the trigger rods 87 are located in the L-shaped grooves 85, and when the L-shaped grooves 85 move upwards, the L-shaped grooves 85 can drive the trigger rods 87 to move upwards.

When a storage module in need is taken out of the placing frame 43, the annular strip 63 can be pulled to rotate reversely, the annular strip 63 rotates reversely to drive the rack 66 to rotate reversely, the rack 66 rotates reversely to drive the gear 65 to rotate inwards, the gear 65 rotates inwards to drive the swinging plates 62 to swing downwards, the two swinging plates 62 in each hole of the porous disc 61 swing downwards without blocking the placing frame 43, the annular strip 63 stops twisting the annular strip 63, the annular strip 63 stops driving the rack 66 to rotate reversely, the rack 66 stops driving the gear 65 to rotate inwards, the swinging plates 62 also stop swinging downwards, the annular knob 51 can be pulled to move upwards, the placing frame 43 drives the storage module to move upwards to a proper position, the storage module in need is taken out of the placing frame 43, the annular knob 51 is loosened after the storage module in need is taken out, the placing frame 43 drives the storage module to move downwards to reset, and the annular strip 63 is pulled to rotate forwards to reset, the annular strip 63 is reset in positive rotation to drive the rack 66 to reset in positive rotation, the rack 66 is reset in positive rotation to drive the gear 65 to reset in outward rotation, the gear 65 is reset in outward rotation to drive the swinging plate 62 to swing upwards to reset, and the swinging plate 62 is reset to continue to block the placing frame 43. Therefore, the storage module can be prevented from being damaged by falling foreign matters into the placing frame 43.

When a required storage module is placed in the placing frame 43 connected with the first u-shaped push plate 77, an operator inserts the six diamond rods into the six diamond holes 711 through the opening of the large circular plate 2, pulls the six diamond rods to drive the rotary circular plate 72 to rotate forward, the rotary circular plate 72 rotates forward to drive the L-shaped guide grooves 74 to rotate forward, when the L-shaped guide grooves 74 on one side rotate forward to enable the inclined surfaces to be in contact with the first L-shaped plate 75, the L-shaped guide grooves 74 drive the first L-shaped plate 75 to move upward, the inclined surfaces of the L-shaped guide grooves 74 on the other side cannot be in contact with the second L-shaped plate 78, the second L-shaped plate 78 cannot be driven to move upward, the first L-shaped plate 75 moves upward to drive the second circular plate 79 to move upward, the second circular plate 79 moves upward to drive the first u-shaped push plate 77 to move upward, the first u-shaped push plate 77 moves upward to drive nine placing frames 43 to move upward, wherein the nine placing frames 43 move upward to drive nine storage modules to move upward, when the nine storage modules move upwards to a proper position, the six diamond rods are stopped to pull the rotary circular plate 72 to rotate forwards, the required storage module can be taken out from the placing frame 43, when the required storage module is taken out from the placing frame 43, the six diamond rods are pulled to pull the rotary circular plate 72 to rotate backwards and reset, the rotary circular plate 72 rotates backwards and resets to drive the L-shaped guide groove 74 to rotate backwards and reset, the L-shaped guide groove 74 resets to drive the first L-shaped plate 75 to move downwards and reset, the first L-shaped plate 75 moves downwards and resets to drive the first u-shaped push plate 77 to move downwards and reset through the first circular plate 76, the first u-shaped push plate 77 resets to drive the nine placing frames 43 to move downwards and reset, and similarly, when the required storage module is placed in the placing frame 43 connected with the second u-shaped push plate 710, the six diamond rods can be pulled to drive the rotary circular plate 72 to rotate backwards, the rotating circular ring plate 72 rotates reversely to drive the L-shaped guide groove 74 to rotate reversely, when the L-shaped guide groove 74 on one side rotates reversely to enable the inclined surface to be in contact with the second L-shaped plate 78, the L-shaped guide groove 74 drives the second L-shaped plate 78 to move upwards, the inclined surface of the L-shaped guide groove 74 on the other side cannot be in contact with the first L-shaped plate 75, and the first L-shaped plate 75 cannot be driven to move upwards, the second L-shaped plate 78 moves upwards to drive the second circular ring plate 79 to move upwards, the second circular ring plate 79 moves upwards to drive the second u-shaped push plate 710 to move upwards, the second u-shaped push plate 710 moves upwards to drive the other nine placing frames 43 to move upwards, the placing frames 43 move upwards to drive the other nine storage modules to move upwards, when the nine storage modules move upwards to proper positions, the six diamond rods are stopped to pull to drive the rotating circular ring plate 72 to rotate reversely, so that the required storage module can be taken out from the placing frame 43, and the required storage module is taken out, the six diamond rods are pulled to drive the rotary circular plate 72 to rotate forwards for resetting, the rotary circular plate 72 resets to drive the L-shaped guide groove 74 to reset, the L-shaped guide groove 74 resets to drive the second L-shaped plate 78 to move downwards for resetting, the second L-shaped plate 78 resets to drive the placing frame 43 to move downwards for resetting, and the storage module is also driven to move downwards for resetting. Thus, the situation that the placing frame 43 moves upwards completely to cause inconvenience in taking out the required storage module by an operator can be avoided.

When a storage module in need is taken out, firstly, the sliding frame 81 is pulled to move upwards, the sliding frame 81 moves upwards to drive the hexagonal prism driving rod 84 to move upwards, the sliding frame 81 also drives the annular fixing plate 82 to move upwards, the annular fixing plate 82 moves upwards to drive the sliding block 86 to move upwards, the sliding block 86 moves upwards to drive the circular block 83 to move upwards, the circular block 83 moves upwards to drive the L-shaped groove 85 to move upwards, when the L-shaped groove 85 moves upwards to enable the inclined surface to be in contact with the trigger rod 87, the L-shaped groove 85 drives the trigger rod 87 to rotate reversely, the trigger rod 87 rotates reversely to drive the guide block 64 to rotate reversely, the guide block 64 rotates reversely to drive the annular strip 63 to rotate reversely, so that the swinging plate 62 swings downwards without blocking the placing frame 43, the sliding frame 81 stops being pulled to move upwards, the L-shaped groove 85 stops driving the trigger rod 87 to rotate reversely, when the storage module in need is placed in the placing frame 43 connected with the first u-shaped push plate 77, twisting the sliding frame 81 to rotate forwards, rotating the sliding frame 81 to drive the hexagonal prism driving rod 84 to rotate forwards, rotating the hexagonal prism driving rod 84 to drive the inner hexagonal prism frame 73 to rotate forwards, rotating the inner hexagonal prism frame 73 to rotate forwards to drive the rotary circular ring plate 72 to rotate forwards, so that the first u-shaped push plate 77 drives nine placing frames 43 to move upwards, the required storage module moves upwards to a proper position, stopping twisting the sliding frame 81, rotating the sliding frame 81 to reset in a reverse direction after the required storage module is taken out, rotating the inner hexagonal prism frame 73 to reset in a reverse direction by the hexagonal prism driving rod 84, driving the placing frames 43 to move downwards to reset by the first u-shaped push plate 77, similarly, when the required storage module is placed in the placing frame 43 connected with the second u-shaped push plate 710, rotating the sliding frame 81 in a reverse direction by the operation, rotating the inner hexagonal prism driving rod 84 to drive the inner hexagonal prism frame 73 to rotate in a reverse direction, driving the other nine placing frames 43 to move upwards by the second u-shaped push plate 710, make the storage module of demand upwards remove to suitable position, the storage module of demand takes out the back, it is resetting to twist sliding frame 81, second u type push pedal 710 then drives and places frame 43 downstream and reset, after placing frame 43 and drive the storage module downstream and reset, promote sliding frame 81 downstream and reset, sliding frame 81 downstream and reset drives slider 86 downstream through annular fixed plate 82, slider 86 resets and drives circular block 83 downstream and resets, circular block 83 moves downstream and resets and drives L type groove 85 downstream and reset, L type groove 85 resets and drives trigger lever 87 reversal reset, trigger lever 87 resets and drives annular strip 63 reversal reset through guide block 64, just also make swing board 62 upwards swing reset and continue to block placing frame 43. In this manner, it is more convenient for the operator to rotate the annular bar 63 of the rotating annular plate 72.

Example 3

On the basis of embodiment 1 and embodiment 2, still include perforated plate 9 and actuating cylinder 10, please refer to fig. 1 and fig. 2, the inboard rotary type in big shaped plate 2 lower part is connected with perforated plate 9, and when air got into big shaped plate 2, perforated plate 9 can realize filtering the impurity in the air, and actuating cylinder 10 has all been fixed to cross-under in the middle part of both sides around perforated plate 9, and the mode installation that the inboard of actuating cylinder 10 passes through welded connection with rotatory ring plate 72 lateral surface.

The multi-functional plate is characterized by further comprising L-shaped brush blocks 12 and springs 13, please refer to fig. 2, 8 and 9, the lower portions of the left side and the right side in the large circular plate 2 are evenly spaced and embedded to be connected with the L-shaped brush blocks 12 in a sliding mode, the L-shaped brush blocks 12 are in contact with the porous plate 9, when the porous plate 9 rotates, the L-shaped brush blocks 12 can remove impurities on the porous plate 9, and the springs 13 are mounted between the outer ends of the L-shaped brush blocks 12 and the inner side of the large circular plate 2 in a welded connection mode.

When the fan 3 is started to pump out hot air in the large circular plate 2, cold air is discharged into the large circular plate 2 through the opening, the porous plate 9 filters impurities in the cold air, and the cold air after the impurities are filtered is discharged into the large circular plate 2. When the rotary circular plate 72 rotates forwards or backwards, the rotary circular plate 72 can drive the driving column 10 to rotate forwards or backwards, the driving column 10 rotates forwards or backwards to drive the porous plate 9 to rotate forwards or backwards, and when the rotary circular plate 72 stops rotating forwards or backwards, the rotary circular plate 72 stops driving the porous plate 9 to rotate forwards or backwards through the driving column 10. Thus, the cold air can be prevented from being mixed with a large amount of impurities and remaining in the large annular plate 2.

When the perforated plate 9 rotates forwards or backwards, the L-shaped brush block 12 removes the impurities remained on the perforated plate 9, and due to the action of the spring 13, the L-shaped brush block 12 can better remove the impurities on the perforated plate 9. Thus, the influence of a large amount of impurities left on the porous plate 9 on the discharge of the cold air can be avoided.

Finally, it is necessary to state that: the above-mentioned contents are only used to help understanding the technical solution of the present invention, and should not be interpreted as limiting the scope of the present invention; insubstantial modifications and adaptations of the invention as described above will occur to those skilled in the art and are intended to be within the scope of the invention as claimed.

Claims (8)

1. The utility model provides an engineering cost data management storage module heat dissipation case, including base (1), big ring plate (2) and fan (3), base (1) top has big ring plate (2) along the circumference rigid coupling, both sides are uncovered setting around big ring plate (2) lower part, big ring plate (2) upper portion has worn to connect along the even spaced fixed of circumference and is used for carrying out radiating nine fan (3) to storage module, characterized by, still including drop feed mechanism (4) and pushing equipment (5), install drop feed mechanism (4) that are used for storage module to place on big ring plate (2), install pushing equipment (5) on drop feed mechanism (4).

2. The engineering cost data management storage module heat dissipation box as claimed in claim 1, wherein the drop feed mechanism (4) comprises a disc (41), a small annular plate (42), a placement frame (43) and heat dissipation fins (44), the disc (41) is fixedly connected to the upper portion of the inner side of the large annular plate (2) along the circumferential direction, eighteen placement frames (43) for placing the storage module are slidably connected to the disc (41) in a penetrating manner at uniform intervals along the circumferential direction, the heat dissipation fins (44) for dissipating heat are mounted on the lower portion of the outer side of the placement frames (43), the small annular plate (42) is fixedly connected to the middle portion of the disc (41) in a penetrating manner, and the small annular plate (42) is connected with the drop feed mechanism (5).

3. The engineering cost data management storage module heat dissipation box according to claim 2, characterized in that the pushing mechanism (5) comprises an annular knob (51), vertical rods (52), pushing plates (53) and a circular guide plate (54), eighteen pushing plates (53) for driving the heat dissipation fins (44) to move upwards are slidably connected to the lower portion of the small circular plate (42) at uniform intervals along the circumferential direction, the pushing plates (53) correspond to the placement frame (43), the circular guide plate (54) is fixedly connected between the inner ends of all the pushing plates (53), the top of the circular guide plate (54) is slidably connected with four vertical rods (52) along the circumferential direction, and the annular knob (51) is fixedly connected between the top ends of the four vertical rods (52).

4. The heat dissipation box of the project cost data management storage module according to claim 3, characterized in that, it further comprises a closing mechanism (6) for blocking the placing frame (43), the closing mechanism (6) comprises a porous disc (61), a swinging plate (62), a ring-shaped strip (63), a guide block (64), a gear (65) and a rack (66), the top of the large circular plate (2) is fixedly connected with the porous disc (61) along the circumferential direction, the swinging plate (62) for blocking the placing frame (43) is symmetrically and rotatably connected in the hole of the porous disc (61), the number of the swinging plate (62) in each hole of the porous disc (61) is two, every two swinging plates (62) correspond to each placing frame (43), the gear (65) is fixedly connected at the rear end of the shaft of the swinging plate (62), the top of the small circular plate (42) is connected with the guide block (64) along the circumferential direction in a sliding manner, annular strips (63) are fixedly connected between the upper parts of the outer side surfaces of the four guide blocks (64), gears (65) are located in the annular strips (63), eighteen racks (66) used for driving the gears (65) to rotate inwards are fixedly connected to the tops and the bottoms of the annular strips (63) at uniform intervals, and the racks (66) on the upper side and the lower side are arranged in a staggered mode.

5. The heat dissipation box of the engineering cost data management storage module according to claim 4, further comprising a pushing mechanism (7) for driving the placement frame (43) to move, wherein the pushing mechanism (7) comprises L-shaped guide blocks (71), a rotating circular plate (72), an inner six-diamond frame (73), a first L-shaped plate (75), a first circular plate (76), a first u-shaped push plate (77), a second L-shaped plate (78), a second circular plate (79) and a second u-shaped push plate (710), the bottom of the small circular plate (42) is connected with six L-shaped guide blocks (71) in a sliding manner along the circumferential direction, the rotating circular plate (72) is fixedly connected between the tail ends of the six L-shaped guide blocks (71), two groups of L-shaped guide grooves (74) are formed along the circumferential direction on the outer side of the rotating circular plate (72), the number of each group of L-shaped guide grooves (74) is two, and each group of two L-shaped guide grooves (74) are symmetrically arranged, wherein, the upper parts of the outer two side surfaces of nine placing frames (43) are fixedly connected with second u-shaped push plates (710), the bottom ends of all the second u-shaped push plates (710) are fixedly connected with second circular ring plates (79), the bottom parts of the second circular ring plates (79) are fixedly connected with two second L-shaped plates (78) along the circumferential direction, the two second L-shaped plates (78) are symmetrically arranged, the inner ends of the two second L-shaped plates (78) are positioned in two L-shaped guide grooves (74), the other two outer two side surfaces of the nine placing frames (43) are fixedly connected with first u-shaped push plates (77), the bottom ends of all the first u-shaped push plates (77) are fixedly connected with first circular ring plates (76), the bottom parts of the first circular ring plates (76) are fixedly connected with first L-shaped plates (75), the inner ends of the two first L-shaped plates (75) are positioned in the other two L-shaped guide grooves (74), the rotary circular ring plate (72) is circumferentially provided with two six diamond holes (711), and the two six diamond holes (711) are symmetrically arranged, an inner hexagonal diamond frame (73) is fixedly connected to the upper part of the inner side of the rotary circular plate (72) along the circumferential direction.

6. The heat dissipation box of the engineering cost data management storage module according to claim 5, further comprising an auxiliary mechanism (8) for assisting, wherein the auxiliary mechanism (8) comprises a sliding frame (81), an annular fixing plate (82), a circular block (83), a hexagonal prism driving rod (84), a sliding block (86) and a triggering rod (87), the triggering rod (87) is fixedly connected to the middle of the inner side surface of the guide block (64), the hexagonal prism driving rod (84) is connected to the inner hexagonal prism frame (73) in a sliding manner in a penetrating manner, the top end of the hexagonal prism driving rod (84) penetrates through the small annular plate (42) and is located in the annular knob (51), the sliding frame (81) is fixedly connected to the top end of the hexagonal prism driving rod (84), the sliding frame (81) is in contact with the inner wall of the annular knob (51), the annular fixing plate (82) is fixedly connected between four ends of the bottom of the sliding frame (81), and nine sliding blocks (86) are fixedly connected to the bottom of the annular fixing plate (82), nine sliding type covers between slider (86) are equipped with circular block (83), and circular block (83) lower part is located little annular plate (42), and the outside of circular block (83) is separated along circumference interval has four L type grooves (85) that are used for driving trigger bar (87) rebound, and trigger bar (87) inner is located L type groove (85).

7. The heat dissipation box of the engineering cost data management and storage module as claimed in claim 6, further comprising a porous plate (9) and a driving column (10), wherein the porous plate (9) for filtering impurities in air is rotatably connected to the inner side of the lower portion of the large circular plate (2), the driving column (10) is fixedly connected to the middle portions of the front side and the rear side of the porous plate (9) in a penetrating manner, and the inner end of the driving column (10) is fixedly connected to the outer side of the rotating circular plate (72).

8. The heat dissipation box of the engineering cost data management and storage module as claimed in claim 7, further comprising L-shaped brush blocks (12) and springs (13), wherein the lower portions of the left and right sides of the inside of the large circular plate (2) are respectively and evenly connected with the L-shaped brush blocks (12) for removing impurities on the porous plate (9) in an embedded manner at intervals, the L-shaped brush blocks (12) are in contact with the porous plate (9), and the springs (13) are fixedly connected between the outer ends of the L-shaped brush blocks (12) and the inner side of the large circular plate (2).

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