阅读说明：本技术 一种便于散热的led节能灯加工的系统 (System convenient for radiating LED electricity-saving lamp processing ) 是由 陈婷婷 于 2020-05-27 设计创作，主要内容包括：本发明公开了一种便于散热的LED节能灯加工的系统,涉及LED灯领域,包括支撑底箱,所述支撑底箱的顶面水平焊接有固定底板,所述固定底板的一侧边水平焊接有进水管道,所述固定底板在远离进水管道的一侧边水平焊接有出水管道,所述固定底板的一侧边斜焊接有控制面板,所述控制面板的顶面镶嵌有显示屏,所述控制面板的顶面镶嵌有设置键,所述控制面板的内侧边水平卡接有控制主板,所述控制面板的内侧边水平卡接有温度主板,所述控制面板的内侧边水平卡接有计量主板,本发明装置设计一体化结构简单操作方便快捷,采用了双模式设计使得在进行加工时更加的具有多选性,同时在进行操作时可以更加的人性化,且加工步骤简单快速使得灯体的散热更佳。(The invention discloses a system for processing an LED energy-saving lamp convenient for heat dissipation, which relates to the field of LED lamps and comprises a supporting bottom box, wherein a fixed bottom plate is horizontally welded on the top surface of the supporting bottom box, a water inlet pipeline is horizontally welded on one side edge of the fixed bottom plate, a water outlet pipeline is horizontally welded on one side edge of the fixed bottom plate far away from the water inlet pipeline, a control panel is obliquely welded on one side edge of the fixed bottom plate, a display screen is embedded on the top surface of the control panel, a set key is embedded on the top surface of the control panel, a control mainboard is horizontally clamped on the inner side edge of the control panel, a temperature mainboard is horizontally clamped on the inner side edge of the control panel, and a metering mainboard is horizontally clamped on the inner side edge of the control panel. Simultaneously can be more humanized when operating, and the simple quick heat dissipation that makes the lamp body of processing step is better.)

1. The system convenient for processing the heat-dissipating LED energy-saving lamp comprises a supporting bottom box (1) and is characterized in that a fixing bottom plate (2) is horizontally welded to the top surface of the supporting bottom box (1), a water inlet pipeline (3) is horizontally welded to one side of the fixing bottom plate (2), a water outlet pipeline (4) is horizontally welded to one side of the fixing bottom plate (2) far away from the water inlet pipeline (3), a control panel (5) is obliquely welded to one side of the fixing bottom plate (2), a display screen (51) is embedded to the top surface of the control panel (5), a setting key (52) is embedded to the top surface of the control panel (5), a control main board (53) is horizontally clamped to the inner side of the control panel (5), a temperature main board (54) is horizontally clamped to the inner side of the control panel (5), a metering main board (55) is horizontally clamped to the inner side of the control panel (5), the horizontal bolt of one side of the fixed bottom plate (2) is connected with a supporting plate (6), the top surface of the supporting plate (6) is connected with a manual key (7) in a clamping manner, the top surface of the fixed bottom plate (2) is provided with a clamping groove (8), the inner side edge of the clamping groove (8) is symmetrically provided with a limiting clamping groove (9), the inner side edge of the clamping groove (8) is connected with a forming main plate (10) in a clamping manner, clamping strips (11) are symmetrically welded on the two side edges of the forming main plate (10), one side edge of the forming main plate (10) is connected with a pulling handle (12) in a bolt manner, forming holes (13) are uniformly formed in the top surface of the forming main plate (10), forming modules (14) are fixedly clamped on the inner side edges of the forming holes (13), a supporting vertical plate (15) is vertically welded upwards on one side edge of the supporting bottom box (1), and a clamping vertical groove (16), the supporting vertical plate (15) is connected with a pushing cylinder (17) through a vertical bolt at one side far away from the supporting bottom box (1), a transmission motor (18) is connected with one side of the supporting vertical plate (15), a sliding block (19) is butt-jointed at one side close to the supporting bottom box (1) of the supporting vertical plate (15), a material box body (20) is vertically and fixedly welded at one side far away from the supporting vertical plate (15) of the sliding block (19), a feeding pipe (21) is vertically welded at the top surface of the material box body (20), a discharging pipeline (22) is vertically and downwardly welded at the bottom surface of the material box body (20), a control switch (23) is bolted at the outer side of the material box body (20), forming grooves (24) are uniformly formed at the inner side of the forming template (14), and a heating layer (25) is fixedly sleeved at the inner side of the material box, the even winding of inboard side of zone of heating (25) has heating pipeline (26), insulation can (27) have been cup jointed to the inboard side of zone of heating (25) is fixed, the inboard top surface level of ejection of compact pipeline (22) is provided with closing plate (28), the fixed joint in outside limit of ejection of compact pipeline (22) has control valve (29), sliding block (19) have slip fixture block (30) in the fixed welding of a side of keeping away from material box (20), transmission tooth (31) have evenly been seted up to a side of slip fixture block (30), interlude hole (32) have been seted up to a side level of support riser (15), the fixed cover of output of driving motor (18) has been cup jointed drive gear (33), the fixed joint in inboard limit of support layer board (6) has manual piece (34).

2. The system for processing the LED energy-saving lamp convenient for heat dissipation according to claim 1, wherein the supporting bottom box (1) is arranged in a U-shaped inverted buckle shape, the top surface of the supporting bottom box (1) is vertically welded at the center of the bottom surface of the fixing bottom plate (2), the inside of the fixing bottom plate (2) is of a hollow structure, the water inlet pipeline (3) and the water outlet pipeline (4) are respectively and symmetrically and horizontally welded at two side edges of the fixing bottom plate (2) near one end, and the insides of the water inlet pipeline (3) and the water outlet pipeline (4) are in through connection with the inside of the fixing bottom plate (2).

3. The system for processing the LED energy-saving lamp convenient for heat dissipation according to claim 1, wherein the control panel (5) is welded to a side of the fixing base plate (2) at a position close to one end, the display screen (51), the setting key (52) and the control main board (53) are electrically connected to each other, the temperature main board (54) and the metering main board (55) are electrically connected to the control main board (53), the temperature main board (54) is electrically connected to the heating pipeline (26), the metering main board (55) is electrically connected to the control switch (23), and the supporting plate (6) is horizontally and fixedly arranged at a position of one side of the fixing base plate (2) far away from the control panel (5).

4. The system for processing the LED energy-saving lamp convenient for heat dissipation according to claim 1, wherein the bottom end of the manual key (7) extends through the top surface of the supporting support plate (6) to the inside, the extending end is fixedly connected with a top surface control key of the manual control block (34) in a clamping manner, the clamping groove (8) is transversely formed in the center of the top surface of the fixing bottom plate (2), two ends of the clamping groove (8) extend through two side edges of the fixing bottom plate (2) to the outer side edge, the top surface of the clamping groove (8) extends through the top surface of the fixing bottom plate (2), the number of the limiting clamping grooves (9) is two, the two limiting clamping grooves (9) are respectively formed in two inner side edge positions of the clamping groove (8) in a parallel and symmetrical manner, and the limiting clamping grooves (9) extend through two side edges of the fixing bottom plate (2) to the outer side.

5. The system convenient for processing of the heat-dissipating LED energy-saving lamp is characterized in that the bottom surface of the molding main board (10) is in butt joint with the inner bottom surface of the clamping groove (8), the clamping strips (11) are respectively clamped in the inner side edge positions of the limiting clamping grooves (9) in a one-to-one correspondence manner, the pulling handle (12) is fixedly arranged at the center position of one side edge of the molding main board (10) close to the control panel (5), the molding holes (13) are a plurality of, the molding holes (13) are vertically arranged at the top surface position of the molding main board (10) in parallel, the molding module (14) is vertically and fixedly arranged at the center position of the inner side edge of the molding hole (13), the material injection hole is formed in the central axis of the molding module (14), and the diameter of the inner side edge of the material injection hole is consistent with the diameter of the outer side edge of the discharge pipeline (22).

6. The system for processing the LED energy-saving lamp convenient for heat dissipation according to claim 1, wherein the supporting vertical plate (15) is vertically and fixedly arranged at a central position of a side of the supporting bottom box (1) far away from the control panel (5), a position of a side of the supporting vertical plate (15) close to the bottom end is butted at a position of a side of the molding main board (10), the clamping vertical groove (16) is vertically arranged at a central position of a side of the supporting vertical plate (15), the pushing cylinder (17) is vertically bolted at a position of a side of the supporting vertical plate (15) close to the bottom end, an output end of the pushing cylinder (17) horizontally penetrates through the inside of the supporting vertical plate (15) and extends to an inner side of the clamping vertical groove (16), and an extending end is vertically welded at a central position of a side of the molding main board (10).

7. The system for processing the LED energy-saving lamp convenient for heat dissipation according to claim 1, wherein the transmission motor (18) is vertically and fixedly arranged at a position close to the top surface of one side edge of the supporting vertical plate (15), the output end of the transmission motor (18) horizontally penetrates through the through hole (32) and extends to the inner side position of the clamping vertical slot (16), the material box (20) is vertically arranged at one side edge of the supporting vertical plate (15) and keeps parallel arrangement with each other, the bottom end of the feeding pipe (21) is vertically welded at the center position of the top surface of the material box (20), and the bottom end of the feeding pipe (21) penetrates through the heating layer (25) and extends to the inner side position of the heat insulation box (27).

8. The system for processing the LED energy-saving lamp convenient for heat dissipation according to claim 1, wherein the number of the discharge pipelines (22) is consistent with the number of the forming holes (13), the top end of the discharge pipeline (22) vertically penetrates through the material box body (20) and the heating layer (25) upwards and extends to the inner bottom position of the heat preservation box (27), the number of the control switches (23) is consistent with the number of the discharge pipelines (22), the control switches (23) are electrically connected with the control valve (29), the heating pipelines (26) are uniformly coiled on the outer side of the heat preservation box (27), and the heating layer (25) is made of an isolation heat preservation material.

9. The system for processing the LED energy-saving lamp convenient for heat dissipation as defined in claim 1, wherein the closing plate (28) is horizontally arranged on the inner top surface of the discharge pipe (22) and is electrically controlled, the control valve (29) and the closing plate (28) are electrically connected with each other, the sliding fixture block (30) is vertically and fixedly arranged at the center position of the side edge of the sliding block (19), the sliding fixture block (30) is vertically clamped at the inner side edge of the clamping vertical groove (16), the transmission teeth (31) and the transmission gear (33) are mutually toothed, the inside of the through hole (32) and the inside of the clamping vertical groove (16) are kept in through connection, and the manual control block (34), the pushing cylinder (17) and the transmission motor (18) are electrically connected with each other.

Technical Field

The invention relates to the technical field of LED lamps, in particular to a system for processing an LED energy-saving lamp convenient for heat dissipation.

Background

The LED lamp is an electroluminescent semiconductor material chip, silver glue or white glue is solidified on the support, then the chip and the circuit board are connected through silver wires or gold wires, the periphery of the chip and the circuit board is sealed through epoxy resin, the effect of protecting an internal core wire is achieved, and finally the shell is installed, so that the anti-seismic performance of the LED lamp is good. The core of the light emitting diode is a wafer consisting of a p-type semiconductor and an n-type semiconductor with a transition layer between them, called the p-n junction. In the PN junction of some semiconductor materials, the injected minority carriers and majority carriers when they recombine release excess energy in the form of light, thereby directly converting electrical energy into light energy. The PN junction is added with reverse voltage, and minority carriers are difficult to inject, so that the LED does not emit light. Such a diode manufactured by using the injection electroluminescence principle is called a light emitting diode, which is generally called an LED. When it is in forward working state (i.e. forward voltage is applied to two ends), when the current flows from anode to cathode of LED, the semiconductor crystal can emit light rays with different colors from ultraviolet to infrared, and the intensity of light is related to current. The high-light-efficiency, low-light-attenuation and high-power LED is widely applied to various illumination fields such as street lamps, industrial and mining lamps, tunnel lamps, spot lamps, fluorescent lamps and the like, and is well received by the industry.

Traditional LED lamp need carry out the high radiating shell when using and wrap up fixedly, make LED carry out extensive use, and what adopt when producing and processing to LED's heat dissipation shell is the aluminum product cutting and forms multi-disc fin structure, because cutting at a piece makes production efficiency low, what bring is exactly that the material that produces can have the spaced error condition to take place under the condition of wearing and tearing, make the specification of product have the difference and have LED to the later stage to receive certain influence when using, the mode that has just adopted the monomode when producing simultaneously operates, make do not have the hommization when the operation, the influence that inconvenience was brought when letting mechanical work.

Disclosure of Invention

The invention aims to provide a system for processing an LED energy-saving lamp convenient for heat dissipation, which aims to solve the problems that the traditional LED lamp provided in the background art needs to be wrapped and fixed by a high-heat-dissipation shell when in use, so that the LED is widely used, the heat dissipation shell of the LED is produced and processed by adopting an aluminum material cutting to form a multi-sheet radiating fin structure, the production efficiency is low due to the fact that the LED is cut into one piece, so that the produced material has interval errors under the condition of abrasion, the specification of the product has certain influence on later use due to difference, and meanwhile, the single-mode is adopted for operation during production, so that the operation is not humanized, and the influence is inconvenient during mechanical work.

In order to achieve the purpose, the invention provides the following technical scheme:

a system for processing an LED energy-saving lamp convenient for heat dissipation comprises a supporting bottom box, wherein a fixed bottom plate is horizontally welded on the top surface of the supporting bottom box, a water inlet pipeline is horizontally welded on one side edge of the fixed bottom plate, a water outlet pipeline is horizontally welded on one side edge of the fixed bottom plate far away from the water inlet pipeline, a control panel is obliquely welded on one side edge of the fixed bottom plate, a display screen is embedded on the top surface of the control panel, a setting key is embedded on the top surface of the control panel, a control mainboard is horizontally clamped on the inner side edge of the control panel, a temperature mainboard is horizontally clamped on the inner side edge of the control panel, a metering mainboard is horizontally clamped on the inner side edge of the control panel, a supporting plate is horizontally bolted on one side edge of the fixed bottom plate, a manual key is clamped on the top surface of the supporting plate, a clamping groove is formed in the top surface of, the inner side edge of the clamping groove is clamped with a forming main board, clamping strips are symmetrically welded on two side edges of the forming main board, a pulling handle is connected with one side edge of the forming main board through bolts, forming holes are uniformly formed in the top surface of the forming main board, a forming module is fixedly clamped on the inner side edge of each forming hole, a supporting vertical plate is vertically and upwards welded on one side edge of the supporting bottom box, a clamping vertical groove is vertically formed in one side edge of the supporting vertical plate close to the supporting bottom box, a pushing cylinder is vertically connected with the supporting vertical plate through a bolt on one side edge far away from the supporting bottom box, a transmission motor is connected with one side edge of the supporting vertical plate through a bolt, a sliding block is butt-jointed on one side edge of the supporting vertical plate close to the supporting bottom box, a material box body is vertically and fixedly welded on one side edge, a discharge pipeline is vertically welded downwards on the bottom surface of the material box body, a control switch is connected with the outer side edge of the material box body through bolts, the inner side of the forming template is evenly provided with forming grooves, the inner side of the material box body is fixedly sleeved with a heating layer, the inner side of the heating layer is uniformly wound with a heating pipeline, the inner side of the heating layer is fixedly sleeved with an insulation can, the top surface of the inner side of the discharge pipeline is horizontally provided with a sealing plate, the outer side edge of the discharge pipeline is fixedly clamped with a control valve, a sliding fixture block is fixedly welded on one side edge of the sliding block far away from the material box body, transmission teeth are uniformly arranged on one side edge of the sliding fixture block, a through hole is horizontally formed in one side edge of the supporting vertical plate, a transmission gear is fixedly sleeved at the output end of the transmission motor, and a manual control block is fixedly clamped at the inner side edge of the supporting plate.

As a preferred embodiment of the present invention: the supporting bottom box is arranged in a U-shaped inverted buckle shape, the top surface of the supporting bottom box is perpendicularly welded to the center of the bottom surface of the fixing bottom plate, the inside of the fixing bottom plate is of a hollow structure, the water inlet pipeline and the water outlet pipeline are respectively welded to two side edges of the fixing bottom plate symmetrically and horizontally and are close to one end position, and the inside of the water inlet pipeline and the inside of the water outlet pipeline are all kept connected with the inside of the fixing bottom plate.

As a preferred embodiment of the present invention: control panel welds to one side of PMKD to one side and is close to one end position, and the display screen, set up key and control mainboard pass through electric connection each other, and the temperature mainboard, measurement mainboard all and control mainboard pass through electric connection each other, and temperature mainboard and heated tube electric connection each other, and measurement mainboard and control switch electric connection each other, and the fixed one end position of keeping away from control panel in one side of PMKD of support plate level setting.

As a preferred embodiment of the present invention: the bottom of manual key runs through the top surface that the supporting plate extended to inside, and the fixed joint of extension was at the top surface control key of manual piece, the horizontal top surface central point who sets up at PMKD in the joint groove put, and the both sides limit that the both ends in joint groove all run through PMKD extends to the outside limit, the top surface that the top surface in joint groove runs through PMKD sets up, the number of spacing draw-in groove is two, and two spacing draw-in grooves parallel symmetry respectively set up in the two inboard edge positions in joint groove, the both sides limit that spacing draw-in groove runs through PMKD extends to the outside.

As a preferred embodiment of the present invention: the bottom surface of shaping mainboard docks in the inboard bottom surface position in joint groove, joint strip one-to-one joint is in the inboard side position of spacing draw-in groove respectively, the fixed setting of pulling handle is put at a side central point that the shaping mainboard is close to control panel, the number in shaping hole is a plurality of, and a plurality of shaping holes all are vertical to the parallel top surface position of seting up at the shaping mainboard, the shaping module is vertical to the fixed inboard side central point that sets up at the shaping hole puts, and the axis of shaping module has seted up the notes material hole, the inboard side diameter in notes material hole keeps unanimous with ejection of compact pipeline's outside side diameter.

As a preferred embodiment of the present invention: support the riser vertical fixation and set up a side central point that keeps away from control panel at the support chassis and put, and a side of supporting the riser is close to a side position butt joint at the shaping mainboard of bottom position, the joint erects the groove and is vertical to seting up a side central point at supporting the riser, promote the perpendicular bolted connection of cylinder and be close to the bottom surface position at a side of supporting the riser, and the output level that promotes the cylinder runs through the inside of supporting the riser and extends to the inboard side that the groove was erected to the joint, extend the end and weld perpendicularly and put at a side central point of shaping mainboard.

As a preferred embodiment of the present invention: the transmission motor is that a vertical form is fixed and is set up and be close to the top surface position at a side of supporting the riser, and transmission motor's output level runs through the inside of interlude hole and extends to the inboard side position that the groove was erected to the joint, and the material box is vertical to setting up and keeping parallel arrangement between a side of supporting the riser and each other, and the vertical welding of inlet pipe bottom is put at the top surface central point of material box, and the inlet pipe bottom runs through the inboard side position that the zone of heating extends to the insulation can.

As a preferred embodiment of the present invention: the number of ejection of compact pipeline keeps unanimous with the number in shaping hole, and the top of ejection of compact pipeline upwards runs through material box, the zone of heating perpendicularly and extends to the inboard bottom surface position of insulation can, and control switch's number keeps unanimous with the number of ejection of compact pipeline, and control switch and control valve pass through electric connection each other, and the heating line evenly coils the setting at the outside limit of insulation can, and the zone of heating adopts the preparation of isolation insulation material.

As a preferred embodiment of the present invention: the closing plate level sets up the inboard top surface at ejection of compact pipeline through the electric control setting, and control valve and closing plate are through electric connection each other, and the slip chuck block is vertical to fixed side central point that sets up at the sliding block puts, and the slip chuck block is vertical to the inboard side position that the groove was erect to the joint, and mutual tooth connects between driving tooth and the drive gear sets up, and the inside of interlude hole and the inside that the groove was erect to the joint keep leading to connecing, and manual piece all sets up through electric connection with promotion cylinder, drive motor each other.

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

1. the design of dual-mode operation enables the use to be more humanized, the production efficiency is greatly improved, keys are arranged on the surface of a control panel, signals are transmitted to the inside of a temperature mainboard, the temperature mainboard controls a heating pipeline to be heated to a set position, the materials in the thermal insulation box are heated and melted, then the control mainboard is controlled to select a manual mode or an automatic mode after the setting, the manual key on the top surface of a supporting plate is pressed after the manual mode is selected, a manual control block controls a transmission motor to rotate, the bottom end of a discharge pipeline on the bottom surface of a material box body is vertically downwards inserted into the inner side edge of a corresponding forming hole, a control switch is opened, and a control valve drives a sealing plate to be opened on the inner side edge of the discharge pipeline, the material is discharged from the discharge pipeline and enters the forming hole, the efficiency is higher when the material is produced by adopting the injection type design, and the product specifications produced at the same time are more uniform.

2. The materials are filled under the action of the molding module and the molding groove, and the water enters the pipeline through the water inlet pipeline and the water outlet pipeline so that the water enters the inside of the fixed bottom plate for circulating flow action, the material is accelerated to be cooled and formed under the action of water circulation, the horizontal sliding action is kept under the clamping connection of the limiting clamping groove and the clamping connection strip, the formed material is leaked downwards from the bottom opening of the forming hole after sliding out to be collected and processed, the formed main board is slid out in the clamping connection groove by the pushing cylinder in an automatic mode to complete the material removal action, and the heating and the discharging are automatically controlled, the device is designed into an integral structure, the structure is simple, the operation is convenient and rapid, the double-mode design is adopted, the processing has more multi-selectivity, simultaneously can be more humanized when operating, and the simple quick heat dissipation that makes the lamp body of processing step is better.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic perspective view of a system for processing an LED energy-saving lamp with heat dissipation convenience;

FIG. 2 is a schematic structural diagram of a cross-sectional connection detail of a fixing base plate of a system for conveniently processing a heat-dissipating LED energy-saving lamp;

FIG. 3 is a schematic structural diagram of a top connection detail of a molded motherboard of a system for facilitating heat dissipation LED energy saving lamp processing;

FIG. 4 is a schematic structural diagram of a connection detail of a profile of a formed main board of a system for conveniently processing a heat-dissipating LED energy-saving lamp;

FIG. 5 is a schematic structural diagram of a material box section connection detail of a system for conveniently processing a heat-dissipating LED energy-saving lamp;

FIG. 6 is a schematic structural diagram of a cross-sectional connection detail of a supporting vertical plate of a system for conveniently processing a heat-dissipating LED energy-saving lamp;

FIG. 7 is a schematic structural diagram of a cross-sectional connection detail of a support plate of a system for facilitating heat dissipation LED energy saving lamp processing;

FIG. 8 is a schematic diagram of a connection detail of a control panel section of a system for processing an LED energy-saving lamp for facilitating heat dissipation;

FIG. 9 is a schematic flow chart diagram of a system for processing an LED energy-saving lamp with heat dissipation convenience.

In the figure: 1-supporting the bottom case; 2-fixing the bottom plate; 3-a water inlet pipeline; 4-a water outlet pipeline; 5-a control panel; 51-a display screen; 52-set key; 53-control the mainboard; 54-temperature main board; 55-a metering main board; 6-supporting the supporting plate; 7-manual key; 8-a clamping groove; 9-a limiting clamping groove; 10-forming a main board; 11-a clamping strip; 12-pulling the handle; 13-forming holes; 14-a forming module; 15-supporting a vertical plate; 16-clamping the vertical slot; 17-a push cylinder; 18-a drive motor; 19-a slider; 20-material box body; 21-a feed pipe; 22-a discharge pipe; 23-a control switch; 24-a forming groove; 25-a heating layer; 26-heating the pipeline; 27-an incubator; 28-a closing plate; 29-a control valve; 30-a sliding fixture block; 31-a gear tooth; 32-a through-hole; 33-a transmission gear; 34-manual control block.

Detailed Description

Referring to fig. 1-4 and 8, in the embodiment of the invention, a system for processing a heat-dissipating LED energy-saving lamp includes a supporting bottom case 1, a fixing bottom plate 2 is horizontally welded on the top surface of the supporting bottom case 1, a water inlet pipe 3 is horizontally welded on one side edge of the fixing bottom plate 2, a water outlet pipe 4 is horizontally welded on one side edge of the fixing bottom plate 2 away from the water inlet pipe 3, the supporting bottom case 1 is arranged in a U-shaped inverted buckle shape, the top surface of the supporting bottom case 1 is vertically welded at the center of the bottom surface of the fixing bottom plate 2, the inside of the fixing bottom plate 2 is a hollow structure, the water inlet pipe 3 and the water outlet pipe 4 are respectively and symmetrically and horizontally welded at the position close to one end of the two side edges of the fixing bottom plate 2, the insides of the water inlet pipe 3 and the water outlet pipe 4 are both in through connection with the inside of the fixing bottom plate 2, a control panel, a setting key 52 is embedded on the top surface of the control panel 5, a control mainboard 53 is horizontally clamped on the inner side edge of the control panel 5, the control panel 5 is welded on one side edge of the fixed bottom plate 2 in an inclined manner and is close to one end position, the display screen 51, the setting key 52 and the control mainboard 53 are electrically connected with each other, the temperature mainboard 54 and the metering mainboard 55 are electrically connected with the control mainboard 53, the temperature mainboard 54 is horizontally clamped on the inner side edge of the control panel 5, the metering mainboard 55 is horizontally clamped on the inner side edge of the control panel 5, the temperature mainboard 54 is electrically connected with the heating pipeline 26, the metering mainboard 55 is electrically connected with the control switch 23, a supporting plate 6 is horizontally and fixedly arranged on one side edge of the fixed bottom plate 2 and is far away from one end position of the control panel 5, a manual key 7 is clamped on the top surface of the supporting plate 6, the top surface of the fixed bottom plate 2 is provided with a clamping groove 8, the bottom end of the manual key 7 penetrates through the top surface of the supporting plate 6 and extends to the inside, the extending end is fixedly clamped on a top surface control key of the manual control block 34, the clamping groove 8 is transversely arranged at the central position of the top surface of the fixed bottom plate 2, two ends of the clamping groove 8 penetrate through two side edges of the fixed bottom plate 2 and extend to the outer side edge, the top surface of the clamping groove 8 penetrates through the top surface of the fixed bottom plate 2 and is provided with two limiting clamping grooves 9, the number of the limiting clamping grooves 9 is two, the two limiting clamping grooves 9 are respectively arranged at two inner side edges of the clamping groove 8 in parallel and symmetrical mode, the limiting clamping grooves 9 penetrate through two side edges of the fixed bottom plate 2 and extend to the outer side, the inner side edge of the clamping groove 8 is clamped with a formed main plate 10, two side edges of the formed main plate 10 are symmetrically welded, the clamping strips 11 are correspondingly clamped at the inner side edge positions of the limiting clamping grooves 9 one by one respectively, one side edge of the formed mainboard 10 is in bolted connection with a plurality of pulling handles 12, forming holes 13 are uniformly formed in the top surface of the formed mainboard 10, the pulling handles 12 are fixedly arranged at the central position of one side edge of the formed mainboard 10 close to the control panel 5, the number of the forming holes 13 is a plurality, the forming holes 13 are vertically and parallelly formed in the top surface position of the formed mainboard 10, a forming module 14 is fixedly clamped at the inner side edge of each forming hole 13, the forming module 14 is vertically and fixedly arranged at the central position of the inner side edge of each forming hole 13, a material injection hole is formed in the central axis of each forming module 14, the diameter of the inner side edge of each material injection hole is consistent with the diameter of the outer side edge of the discharge pipeline 22, a supporting vertical plate 15 is welded vertically upwards at one side edge of the supporting bottom box 1, a clamping vertical groove, supporting upright plate 15 vertical fixation sets up in a side central point that supporting under casing 1 kept away from control panel 5 puts, and a side of supporting upright plate 15 is close to a side position of bottom position butt joint at shaping mainboard 10, joint erects groove 16 and is vertical to seting up in a side central point that supports upright plate 15, supporting upright plate 15 has promotion cylinder 17 at a side vertical bolted connection who keeps away from supporting under casing 1, promotion cylinder 17 vertical bolted connection is close to the bottom surface position at a side of supporting upright plate 15, and the output level that promotes cylinder 17 runs through supporting upright plate 15 inside extend to the inboard side of joint erects groove 16, extend the end and weld at a side central point of shaping mainboard 10 perpendicularly, a side bolted connection of supporting upright plate 15 has drive motor 18, drive motor 18 is the vertical fixed setting of form and is close to the top surface position at a side of supporting upright plate 15, and drive motor 18's output level runs through the inside of interlude hole 32 and extends to the inboard side position A sliding block 19 is butted at one side edge of the supporting vertical plate 15 close to the supporting bottom box 1, a material box body 20 is vertically and fixedly welded at one side edge far away from the supporting vertical plate 15 by the sliding block 19, a feeding pipe 21 is vertically welded at the top surface of the material box body 20, the material box body 20 is vertically arranged at one side edge of the supporting vertical plate 15 and keeps parallel arrangement with each other, the bottom end of the feeding pipe 21 is vertically welded at the central position of the top surface of the material box body 20, the bottom end of the feeding pipe 21 penetrates through the heating layer 25 and extends to the inner side edge position of the insulation box 27, a discharging pipeline 22 is vertically and downwards welded at the bottom surface of the material box body 20, a control switch 23 is connected with the outer side edge of the material box body 20 by bolts, the number of the discharging pipelines 22 is consistent with the number of the forming holes 13, the number of the control switches 23 is consistent with that of the discharge pipelines 22, the control switches 23 are electrically connected with the control valves 29, and the inner side edge of the forming template 14 is uniformly provided with forming grooves 24;

referring to fig. 5-7, in the embodiment of the present invention, a system for processing a heat-dissipating LED energy-saving lamp is provided, wherein a heating layer 25 is fixedly sleeved on an inner side of a material box 20, a heating pipeline 26 is uniformly wound on an inner side of the heating layer 25, the heating pipeline 26 is uniformly wound on an outer side of an insulation box 27, the heating layer 25 is made of an insulation material, the insulation box 27 is fixedly sleeved on an inner side of the heating layer 25, a sealing plate 28 is horizontally disposed on an inner side top surface of a discharging pipeline 22, a control valve 29 is fixedly clamped on an outer side edge of the discharging pipeline 22, the sealing plate 28 is horizontally disposed on the inner side top surface of the discharging pipeline 22 through electrical control, the control valve 29 and the sealing plate 28 are electrically connected to each other, a sliding block 30 is fixedly welded on a side edge far from the material box 20, the sliding block 30 is vertically and fixedly disposed at a side, and the vertical inboard side position of joint in the vertical groove 16 of joint of slip fixture block 30, driving tooth 31 has evenly been seted up to one side of slip fixture block 30, a interlude hole 32 has been seted up to one side level of support riser 15, the fixed joint of output of driving motor 18 has drive gear 33, the fixed joint of inboard side of support layer board 6 has manual piece 34, mutual toothing setting between driving tooth 31 and the drive gear 33, the inside of interlude hole 32 keeps leading to with the inside of the vertical groove 16 of joint, manual piece 34 and promotion cylinder 17, driving motor 18 all sets up through electric connection each other.

The components are standard parts in general or known to those skilled in the art, and their structure and principle are known to those skilled in the art through technical manuals or through routine experimentation.

The working principle of the invention is as follows:

the aluminum material is put into the interior of the thermal insulation box 27 from the feeding pipe 21, then the top opening end of the feeding pipe 21 is sealed and connected, the surface of the control panel 5 is provided with a key 52, the display function is performed in the display screen 51, a signal is transmitted to the interior of the temperature main board 54, the temperature main board 54 controls the heating pipeline 26 to heat to a set position, the material in the thermal insulation box 27 is heated and melted, then the control main board 53 controls to select a manual mode or an automatic mode after the setting, the manual key 7 on the top surface of the supporting plate 6 is pressed after the manual mode is selected, the manual control block 34 controls the transmission motor 18 to rotate, the transmission gear 33 drives the transmission teeth 31 of the sliding fixture block 30 on the inner side of the clamping vertical groove 16 to move downwards in the clamping vertical groove 16 under the rotation function of the transmission motor 18, so that the bottom end of the discharge pipeline 22 at the bottom of the material box 20 is vertically inserted downwards to enter the inner side of the corresponding forming hole 13, the control switch 23 is opened to enable the control valve 29 to drive the closing plate 28 to open at the inner side of the discharge pipeline 22, so that the material is discharged from the discharge pipeline 22 to enter the forming hole 13, the material is filled under the action of the forming module 14 and the forming groove 24, the water enters the pipeline through the water inlet pipeline 3 and the water outlet pipeline 4 to enter the inside of the fixed bottom plate 2 for circulating flow, the material is accelerated to cool and form under the action of water circulation, then the pull handle 12 is pulled to enable the forming main plate 10 to continuously slide out from the inside of the clamping groove 8, the horizontal sliding action is kept under the clamping of the limiting clamping groove 9 and the clamping strip 11, the formed material leaks downwards from the bottom opening of the forming hole 13 after sliding out to be collected and processed, adopt automatic mode then to slide out by pushing away cylinder 17 in the inside of joint groove 8 shaping mainboard 10 and accomplish the material effect of taking off, and heating and arrange the material and all adopt automated control.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention are equivalent to or changed within the technical scope of the present invention.