CN207486759U - A kind of heat-exchange device - Google Patents

Abstract

The utility model discloses a kind of heat-exchange device, including housing, light source, the first wind turbine, the first radiating subassembly, condenser pipe and the second radiating subassembly；In hollow structure and equipped with the thermal cycle channel being closed in housing, the first wind turbine, the first radiating subassembly and light source are successively set in housing and are respectively positioned in thermal cycle channel from the bottom to top；First radiating subassembly is connected by condenser pipe with the second radiating subassembly cycle.In the utility model, it can solve the problems, such as that light source part can not be provided simultaneously with heat dissipation and rainproof effect in the prior art.

Description

A kind of heat-exchange device

Technical field

The utility model is related to stage lighting technical field, more particularly to a kind of heat-exchange device.

Background technology

Modern stage lamp use scope is more and more wider, is no longer only satisfied with indoor performance, is also widely used outdoors Live action performance, theme park, city lighting engineering, this proposes lamps and lanterns more waterproof requirements in itself.Actually make in previous In, in rainwater weather, lamps and lanterns can only could meet outdoor actual operation requirements by auxiliary rain-proof equipment.Modern stage lighting Tool (stage lamp of particularly shaking the head) generally can be divided into pedestal, U-shaped frame and head three parts, and pedestal is mainly responsible for power supply supply And main body control, U-shaped frame mainly realize level, vertical orientations rotation sweep, transformation angle, head is mainly various light efficiency functions Variation.The main securement head tail end of lamp light source, for the benefit of light source heat radiation, is often set as split type, and in lamp by the shell of lamp cap Therefore the two sides of tail face setting open type heat radiating slot of head, is difficult to outdoor outdoors for radiating using stage lighting at present Occasion use, easily cause at rainy day the key positions such as lamp cap light source intake, light source part can not be provided simultaneously with heat dissipation with Rainproof effect is damaged so as to cause lamps and lanterns.

Utility model content

For overcome the deficiencies in the prior art, the purpose of this utility model is to provide a kind of heat-exchange devices.It can solve Light source part can not be provided simultaneously with the problem of heat dissipation and rainproof effect in the prior art, can meet stage lamp to greatest extent The requirement that can not be independently used by auxiliary rain-proof equipment in rainwater environment.

The purpose of this utility model is realized using following technical scheme：

A kind of heat-exchange device, including housing, light source, the first wind turbine, the first radiating subassembly, condenser pipe and the second heat dissipation group Part；

In hollow structure and equipped with the thermal cycle channel being closed in housing, the first wind turbine, the first radiating subassembly and light source by Under supreme be successively set in housing and be respectively positioned in thermal cycle channel；

First radiating subassembly is connected by condenser pipe with the second radiating subassembly cycle.

Further, the second wind turbine is further included, the second wind turbine is fixed in thermal cycle channel and above light source.

Further, the first radiating subassembly is equipped with first through hole, and the second radiating subassembly is equipped with the second through-hole, condenser pipe Head end is connected with end, also, condenser pipe sequentially passes through first through hole and the second through-hole.

Further, kinetic pump is further included, kinetic pump is located on condenser pipe.

Further, condenser pipe is equipped with the first full of twists and turns portion, and first through hole is run through in the first full of twists and turns portion.

Further, several first bending parts are equipped at intervals in the first full of twists and turns portion.

Further, condenser pipe is equipped with the second full of twists and turns portion, and the second through-hole is run through in the second full of twists and turns portion.

Further, several second bending parts are equipped at intervals in the second full of twists and turns portion.

Further, the first radiating subassembly includes several first heat transmission fins, and several first heat transmission fins overlap Form complete first radiating subassembly；

Second radiating subassembly includes several second heat transmission fins, and several second heat transmission fins overlap composition completely Second radiating subassembly.

Further, water-proof fan is further included, water-proof fan is fixed above the second radiating subassembly.

Compared with prior art, the beneficial effects of the utility model are：Due to including housing, light source, the first wind turbine, first Radiating subassembly, condenser pipe and the second radiating subassembly, the housing is interior in hollow structure, and the heat of closure is formed in the housing First wind turbine, the first radiating subassembly and light source are fixedly mounted in housing by circulation canal successively from the bottom to top, and ensure first Wind turbine, the first radiating subassembly and light source are respectively positioned in thermal cycle channel, in addition, the first radiating subassembly is dissipated by condenser pipe and second Hot component realizes cycle connection.When the heat-exchange device is worked, heat major part quilt caused by light source working First radiating subassembly is absorbed, still, still have fraction heat not by the first radiating subassembly absorb, this fraction heat from The first wind turbine opened in being rotated after the first radiating subassembly extracts so that this fraction heat is flowed in thermal cycle channel It is logical, to arrive at the first radiating subassembly again and to be absorbed by the first radiating subassembly (i.e. so that not inhaled by the first radiating subassembly Circulation can be carried out in thermal cycle channel by receiving heat), and the heat that the first radiating subassembly is absorbed is passed by condenser pipe It is directed in the second radiating subassembly, and then the heat is distributed to the external world, radiating efficiency can be improved, and do not need in light source The back side be mounted directly cooling fin and radiate, greatly reduce the volume of stage lamp and reduce the weight of stage lamp.It solves Light source part can not be provided simultaneously with the problem of heat dissipation and rainproof effect in the prior art, can meet stage lamp to greatest extent The requirement that can not be independently used by auxiliary rain-proof equipment in rainwater environment.

Description of the drawings

Fig. 1 is a kind of structure diagram of embodiment of the utility model heat-exchange device；

Fig. 2 is the schematic cross-sectional view of heat-exchange device shown in Fig. 1；

Fig. 3 is the group of the first radiating subassembly in heat-exchange device shown in Fig. 1, the second radiating subassembly, kinetic pump and condenser pipe Close structure diagram；

Fig. 4 is the structural scheme of mechanism of the first radiating subassembly in heat-exchange device shown in Fig. 1；

Fig. 5 is the structural scheme of mechanism of the second radiating subassembly in heat-exchange device shown in Fig. 1；

Fig. 6 is the structural scheme of mechanism of condenser pipe in heat-exchange device shown in Fig. 1.

In figure：1st, housing；2nd, light source；3rd, the first wind turbine；4th, the first radiating subassembly；41st, first through hole；5th, condenser pipe； 511st, the first bending part；521st, the second bending part；6th, the second radiating subassembly；61st, the second through-hole；7th, the second wind turbine；8th, kinetic pump； 9th, water-proof fan.

Specific embodiment

In the following, with reference to attached drawing and specific embodiment, the utility model is described further：

Refer to Fig. 1-Fig. 6, the utility model is related to a kind of heat-exchange device, including housing 1, light source 2, the first wind turbine 3, First radiating subassembly 4, condenser pipe 5, the second radiating subassembly 6, the second wind turbine 7, kinetic pump 8 and water-proof fan 9.

In hollow structure in housing 1, and the thermal cycle channel of closure is formed in housing 1, by the first wind turbine 3, the One radiating subassembly 4,2 and second wind turbine 7 of light source are fixedly mounted in housing 1 successively from the bottom to top, and the first wind turbine 3 of guarantee, (i.e. the second wind turbine 7 is fixedly mounted in thermal cycle channel from the bottom to top for first radiating subassembly 4,2 and second wind turbine 7 of light source In thermal cycle channel and positioned at 2 top of light source).

When the heat-exchange device is worked, light source 2 works generated heat major part by the first heat dissipation group Part 4 is absorbed, and still, still has fraction heat not absorbed by the first radiating subassembly 4, this fraction heat leaves first and dissipates The first wind turbine 3 and the second wind turbine 7 in being rotated successively after hot component 4 extract so that this fraction heat is in thermal cycle channel It inside circulates, to arrive at the first radiating subassembly 4 again and to be absorbed by the first radiating subassembly 4 (i.e. so that not by first Radiating subassembly 4 absorbs heat can carry out circulation in thermal cycle channel), the efficiency of heat absorption can be improved, and then Improve radiating efficiency.

Eight first through hole 41 are formed on the first radiating subassembly 4, and eight first through hole 41 are evenly distributed on On first radiating subassembly 4, eight the second through-holes 61 are formed on the second radiating subassembly 6, and this eight the second through-holes 61 are It is even to be distributed on the second radiating subassembly 6, and 5 head end of condenser pipe and end are connected with each other (so that being flooded with the condenser pipe 5 of condensate liquid One SAPMAC method system of Inner Constitution), and condenser pipe 5 sequentially passes through 41 and second through-hole 61 of first through hole, i.e., so that first Radiating subassembly 4 is connected by condenser pipe 5 with the second radiating subassembly 6 cycle.

In the present embodiment, eight first through hole 41 are formed on the first radiating subassembly 4.In other embodiments, first is logical The quantity in hole 41 can be changed according to actual conditions, for example, the quantity of first through hole 41 can be six, alternatively, first The quantity of through-hole 41 can be seven or, the quantity of first through hole 41 can be nine.

In the present embodiment, eight the second through-holes 61 are formed on the second radiating subassembly 6.In other embodiments, second is logical The quantity in hole 61 can be changed according to actual conditions, for example, the quantity of the second through-hole 61 can be six, alternatively, second The quantity of through-hole 61 can be seven or, the quantity of the second through-hole 61 can be nine.

Condenser pipe 5 forms the first full of twists and turns portion, which runs through first through hole 41, wherein first is circuitous It goes back to interval on zigzag part and forms seven the first bending parts 511, the first full of twists and turns portion can be allowd more to be uniformly distributed On the first radiating subassembly 4, when the heat-exchange device is worked, the first radiating subassembly 4 can preferably absorb heat It measures and so that the heat absorbed is conducted to the first full of twists and turns portion.

In the present embodiment, the quantity of the first bending part 511 is seven.In other embodiments, the number of the first bending part 511 Amount can be changed according to actual conditions, for example, the quantity of the first bending part 511 can be six, alternatively, the first bending part 511 quantity can be seven or, the quantity of the first bending part 511 can be nine, as long as ensureing in the first detour song Molding first bending part 511 on folding part, can allow the first full of twists and turns portion to be more evenly distributed on the first heat dissipation group On part 4.

Condenser pipe 5 forms the second full of twists and turns portion, which runs through the second through-hole 61, wherein second is circuitous It goes back to interval on zigzag part and forms seven the second bending parts 521, the second full of twists and turns portion can be allowd more to be uniformly distributed On the second radiating subassembly 6, when the heat-exchange device is worked, the second radiating subassembly 6 can preferably absorb heat Amount is distributed to the external world.

In the present embodiment, the quantity of the second bending part 521 is seven.In other embodiments, the number of the second bending part 521 Amount can be changed according to actual conditions, for example, the quantity of the second bending part 521 can be six, alternatively, the second bending part 521 quantity can be seven or, the quantity of the second bending part 521 can be nine, as long as ensureing in the second detour song Molding second bending part 521 on folding part, can allow the second full of twists and turns portion to be more evenly distributed on the second heat dissipation group On part 6.

Kinetic pump 8 is mounted on condenser pipe 5, which can provide power for the cycle of SAPMAC method system, at this When heat-exchange device is worked, the generated heat that worked by the first radiating subassembly 4 light source 2 absorbs, and The heat that first radiating subassembly 4 is absorbed is conducted into the first full of twists and turns portion of condenser pipe 5, due to 5 head end of condenser pipe and end End is mutually communicated so that is flooded with condenser pipe 5 Inner Constitution, one SAPMAC method system of condensate liquid, is conducted to the of condenser pipe 5 Heat in one full of twists and turns portion is conducted again by the condensate liquid in condenser pipe 5 into the second full of twists and turns portion of condenser pipe 5, And pass through the second radiating subassembly 6 and distribute the heat to the external world, and dissipate effect of the condensate liquid in kinetic pump 8 of heat Under turn again in the first full of twists and turns portion, so as to form a SAPMAC method system so that heat can constantly from first dissipate In hot component 4 in conduction to the second radiating subassembly 6, in addition, water-proof fan 9 is fixedly mounted on 6 top of the second radiating subassembly, turn Water-proof fan 9 in dynamic can accelerate to distribute to the external world so that conducting to the heat of the second radiating subassembly 6, can improve heat dissipation effect Rate.Wherein, the first radiating subassembly 4 includes several first heat transmission fins, which, which overlaps, has been formed The first whole radiating subassembly 4, the second radiating subassembly 6 include several second heat transmission fins, which overlaps Complete second radiating subassembly 6 is formed together.

In the present embodiment, the quantity of the first heat transmission fin is 38.In other embodiments, first heat transmission fin Quantity can be changed according to actual conditions, for example, the quantity of the first heat transmission fin can be 30, alternatively, first leads The quantity of hot fin can be 34, alternatively, the first heat transmission fin can be 42 or, the first heat conduction wing The quantity of piece can be 46, as long as ensureing that several first heat transmission fins overlap forms complete first heat dissipation Component 4.

In the present embodiment, the quantity of the second heat transmission fin is 38.In other embodiments, second heat transmission fin Quantity can be changed according to actual conditions, for example, the quantity of the second heat transmission fin can be 30, alternatively, second leads The quantity of hot fin can be 34, alternatively, the second heat transmission fin can be 42 or, the second heat conduction wing The quantity of piece can be 46, as long as ensureing that several second heat transmission fins overlap forms complete second heat dissipation Component 6.

During using the utility model, due to include housing 1, light source 2, the first wind turbine 3, the first radiating subassembly 4, condenser pipe 5, Second radiating subassembly 6, the second wind turbine 7, kinetic pump 8 and water-proof fan 9, the housing 1 is interior in hollow structure, and in the housing 1 Inside form the thermal cycle channel of closure, by the first wind turbine 3, the first radiating subassembly 4,2 and second wind turbine 7 of light source from the bottom to top according to It is secondary to be fixedly mounted in housing 1, and ensure that the first wind turbine 3, the first radiating subassembly 4,2 and second wind turbine 7 of light source are respectively positioned on heat and follow In ring channel, in addition, the first radiating subassembly 4 realizes that cycle is connected (in the first heat dissipation by condenser pipe 5 with the second radiating subassembly 6 First through hole 41 is formed on component 4, the second through-hole 61 is formed on the second radiating subassembly 6,5 head end of condenser pipe and end connect It connects (so that being flooded with 5 Inner Constitution of condenser pipe, one SAPMAC method system of condensate liquid), and condenser pipe 5 sequentially passes through first and leads to In addition kinetic pump 8 is mounted on condenser pipe 5 by 41 and second through-hole 61 of hole, which can be the cycle of SAPMAC method system There is provided power).When the heat-exchange device is worked, light source 2 works, and generated heat is most of to be radiated by first Component 4 is absorbed, and still, still has fraction heat not absorbed by the first radiating subassembly 4, this fraction heat leaves first The first wind turbine 3 and the second wind turbine 7 in being rotated after radiating subassembly 4 extract so that this fraction heat is in thermal cycle channel It circulates, to arrive at the first radiating subassembly 4 again and to be absorbed by the first radiating subassembly 4 (i.e. so that not dissipated by first Hot component 4 absorbs heat can carry out circulation in thermal cycle channel), and the heat that the first radiating subassembly 4 is absorbed leads to It crosses condenser pipe 5 to conduct into the second radiating subassembly 6, in addition, water-proof fan 9 is fixedly mounted on 6 top of the second radiating subassembly, turn Water-proof fan 9 in dynamic can accelerate to distribute to the external world so that conducting to the heat of the second radiating subassembly 6, can improve heat dissipation effect Rate, and do not need to be mounted directly cooling fin at the back side of light source 2 and radiate, greatly reduce volume and the reduction of stage lamp The weight of stage lamp.Solve the problems, such as that light source part can not be provided simultaneously with heat dissipation and rainproof effect in the prior art, it can be most The requirement that meets stage lamp and can not independently be used by auxiliary rain-proof equipment in rainwater environment of limits.

It will be apparent to those skilled in the art that technical solution that can be as described above and design, make other various Corresponding change and deformation, and all these changes and deformation should all belong to the protection of the utility model claims Within the scope of.

Claims (10)

1. a kind of heat-exchange device, it is characterised in that：Including housing, light source, the first wind turbine, the first radiating subassembly, condenser pipe and Second radiating subassembly；

In hollow structure and equipped with the thermal cycle channel being closed, first wind turbine, the first radiating subassembly and light in the housing Source is successively set in the housing and is respectively positioned in the thermal cycle channel from the bottom to top；

First radiating subassembly is connected by the condenser pipe with second radiating subassembly cycle.

2. heat-exchange device according to claim 1, it is characterised in that：The second wind turbine is further included, second wind turbine is consolidated Surely it is arranged in the thermal cycle channel and above light source.

3. heat-exchange device according to claim 1, it is characterised in that：It is logical that first radiating subassembly is equipped with first Hole, second radiating subassembly are equipped with the second through-hole, and the condenser pipe head end connects with end, also, the condenser pipe according to It is secondary to run through first through hole and the second through-hole.

4. heat-exchange device according to claim 3, it is characterised in that：Kinetic pump is further included, the kinetic pump is located at cold On solidifying pipe.

5. heat-exchange device according to claim 3, it is characterised in that：The condenser pipe is equipped with the first full of twists and turns portion, First through hole is run through in the first full of twists and turns portion.

6. heat-exchange device according to claim 5, it is characterised in that：If it is equipped at intervals in the first full of twists and turns portion Dry first bending part.

7. heat-exchange device according to claim 3, it is characterised in that：The condenser pipe is equipped with the second full of twists and turns portion, The second through-hole is run through in the second full of twists and turns portion.

8. heat-exchange device according to claim 7, it is characterised in that：If it is equipped at intervals in the second full of twists and turns portion Dry second bending part.

9. heat-exchange device according to claim 1, it is characterised in that：First radiating subassembly is led including several first Hot fin, several first heat transmission fins, which overlap, forms complete first radiating subassembly；

Second radiating subassembly includes several second heat transmission fins, and several second heat transmission fins, which overlap, have been formed The second whole radiating subassembly.

10. according to the heat-exchange device described in any one of claim 1-9, it is characterised in that：Water-proof fan is further included, it is described Water-proof fan is fixed above the second radiating subassembly.