CN104764346A - Radiant panel structure and radiant panel heat exchanger - Google Patents

Abstract

The invention provides a radiation plate structure and a radiation plate heat exchanger. The radiation plate structure comprises a reflection assembly, a central tube assembly and an adjusting assembly, wherein the reflection assembly is installed on the central tube assembly, the central tube assembly is located at the focal position of the reflection assembly, the adjusting assembly is installed on the reflection assembly, and the adjusting assembly can adjust the orientation of the reflection assembly; the reflecting assembly comprises a framework mechanism and a reflecting plate, the reflecting plate is installed on the framework mechanism, the central tube assembly comprises a heat exchange tube, and the framework mechanism is installed on the heat exchange tube so as to achieve the purposes of adjusting the orientation of the reflecting assembly and improving the structural efficiency of the radiation plate.

Description

Radiant panel structure and radiant panel heat exchanger

Technical field

The present invention relates to field of heat exchange equipment, particularly relate to a kind of radiant panel structure for radiations heat energy or cold, and the radiant panel heat exchanger containing this radiant panel structure.

Background technology

Existing radiant panel heat exchanger is generally fixing plate armature, and radiant panel heat exchanger is arranged in furred ceiling or wall place by the mode lifting or attach.For ceiling mounting type radiant panel, radiant panel heat exchanger is generally in the place that above space, hot-air is comparatively concentrated, under cooling condition, hot-air convection can make radiant panel heat exchanger heat up, current radiant panel heat exchanger can not adjust after mounting radiant panel towards, in the place that some thermal source can be moved, effectively can not make full use of the refrigerating capacity of radiant panel heat exchanger, thus the temperature difference reduced between radiant panel heat exchanger and thermal source, reduce the radiation effect of radiant panel heat exchanger.

Summary of the invention

Based on this, be necessary for existing radiant panel heat exchanger can not adjust radiant panel towards so that reduce the problem of radiation effect of radiant panel heat exchanger, a kind of radiation direction that can adjust heat is provided, effectively utilize radiant heat energy, improve the radiant panel structure of radiation effect and the radiant panel heat exchanger containing this radiant panel structure.Above-mentioned purpose is achieved through the following technical solutions:

A kind of radiant panel structure, comprise reflection subassembly, central tube assembly and adjusting part, described reflection subassembly is arranged on described central tube assembly, and described central tube assembly is positioned at the focal position of described reflection subassembly, described adjusting part is arranged on described reflection subassembly, described adjusting part can regulate described reflection subassembly towards;

Wherein, described reflection subassembly comprises skeleton mechanism and reflecting plate, and described reflecting plate is arranged in described skeleton mechanism, and described central tube assembly comprises heat exchanger tube, and described skeleton mechanism is arranged on described heat exchanger tube.

Wherein in an embodiment, described adjusting part comprises and hangs muscle and suspension ring, and described suspension ring are arranged in described skeleton mechanism, described in hang muscle and be movably arranged on described suspension ring.

Wherein in an embodiment, described skeleton mechanism comprises parabolic portion and support portion, described parabolic portion is arranged on described support portion, described reflecting plate is arranged in described parabolic portion, described support portion is movably arranged on described heat exchanger tube, and the position that described central tube assembly is installed in described support portion is the focal position in described parabolic portion.

Wherein in an embodiment, described reflecting plate is coated with highly-reflective coating on the surface of described central tube assembly.

Wherein in an embodiment, the cross sectional shape of described reflecting plate is parabola shaped.

Wherein in an embodiment, described reflection subassembly also comprises bearing, and the support portion of described skeleton mechanism is arranged on described central tube assembly by described bearing.

Wherein in an embodiment, described central tube assembly also comprises infrared through pipe and seal, the described infrared outside being contained in described heat exchanger tube through pipe box, described heat exchanger tube and describedly infraredly form vacuum layer through between pipe by described seal.

Wherein in an embodiment, described heat exchanger tube is with described infrared coaxial through managing, and the two ends of described heat exchanger tube protrude from described infrared through pipe.

Wherein in an embodiment, described central tube assembly also comprises pipe joint, and described pipe joint is separately positioned on the two ends of described heat exchanger tube.

Wherein in an embodiment, the outer surface of described heat exchanger tube has for absorbing ultrared absorber coatings.

Also relate to a kind of radiant panel heat exchanger, comprise the radiant panel structure as described in above-mentioned arbitrary technical characteristic.

The invention has the beneficial effects as follows:

Radiant panel structure of the present invention and radiant panel heat exchanger, structural design advantages of simple, reflection subassembly by adjusting part accommodation reflex plate towards, the skeleton mechanism of reflection subassembly can rotate around central tube assembly, and then drive the reflecting plate in skeleton mechanism to rotate, when ensure central tube assembly do not twist and larger displacement, realize accommodation reflex plate towards, the radiation direction of reflecting plate can be changed.When thermal source is moved, accommodation reflex plate towards making reflecting plate to quasi-thermal source so that reflection board structure can make full use of the heat of thermal source, thus improve the efficiency of radiation heat transfer.

Accompanying drawing explanation

Fig. 1 is the stereogram of the radiant panel structure of one embodiment of the invention;

Fig. 2 is the cross sectional representation of the radiant panel structure shown in Fig. 1;

Fig. 3 is for reflection subassembly in the radiant panel structure shown in Fig. 1 being provided with the stereogram of suspension ring;

Fig. 4 is the stereogram of central tube assembly in the radiant panel structure shown in Fig. 1;

Wherein:

100-radiant panel structure;

110-adjusting part;

111-hangs muscle; 112-suspension ring;

120-reflection subassembly;

121-skeleton mechanism; 1211-support portion; 1212-parabolic portion;

122-reflecting plate;

123-bearing;

130-central tube assembly;

131-heat exchanger tube; 132-is infrared through pipe; 133-seal; 134-pipe joint.

Detailed description of the invention

In order to make object of the present invention, technical scheme and advantage clearly understand, by the following examples, and by reference to the accompanying drawings, radiant panel structure of the present invention and radiant panel heat exchanger are further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the present invention, be not intended to limit the present invention.

See Fig. 1 to Fig. 4, the radiant panel structure 100 of one embodiment of the invention comprises reflection subassembly 120, central tube assembly 130 and adjusting part 110, reflection subassembly 120 is arranged on central tube assembly 130, and central tube assembly 130 is positioned at the center of reflection subassembly 120, adjusting part 110 is arranged on reflection subassembly 120, reflection subassembly 120 can rotate around central tube assembly 130, by adjusting part 110 accommodation reflex assembly 120 towards.Regulate reflection subassembly 120 towards rear, the position of reflection subassembly 120 can also be fixed by adjusting part 110, and the position of reflection subassembly 120 can not be offset, can to quasi-thermal source.By machine or manual regulative mode adjusting part 110, adjusting part 110 can accommodation reflex assembly towards, thermal source can send infrared waves, the infrared waves that reflection subassembly 120 sends for reflecting thermal source, by rotate reflection subassembly 120 can accommodation reflex assembly 120 towards, infrared waves can be reflexed on central tube assembly 130 by reflection subassembly 120.

Wherein, reflection subassembly 120 comprises skeleton mechanism 121 and reflecting plate 122, and reflecting plate 122 is arranged in skeleton mechanism 121.Central tube assembly 130 comprises heat exchanger tube 131, and skeleton mechanism 121 is arranged on heat exchanger tube 131.Skeleton mechanism 121 can rotate around heat exchanger tube 131, and then skeleton mechanism 121 drives reflecting plate 122 to rotate.Skeleton mechanism 121 plays a part to support and carrying, and skeleton mechanism 121 can also rotate around the heat exchanger tube 131 of central tube assembly 130 simultaneously.Reflecting plate 122 is installed in skeleton mechanism 121, can form the structure of parabolic trough type, and the infrared waves for being sent by thermal source reflex to the heat exchanger tube 131 of central tube assembly 130.In radiant panel structure 100 of the present invention, reflection subassembly 120 by around central tube assembly 130 rotate come accommodation reflex plate 122 towards, make reflecting plate 122 pairs of quasi-thermal sources, make reflecting plate 122 can reflex on heat exchanger tube 131 by the infrared waves that thermal source sends, so that radiant panel structure 100 can make full use of thermal source, thus improve the efficiency of radiation heat transfer.

At present, for ceiling mounting type radiant panel heat exchanger, radiant panel heat exchanger is generally in the place that above space, hot-air is comparatively concentrated, hot-air convection can make radiant panel heat exchanger heat up, current radiant panel heat exchanger can not adjust after mounting radiant panel towards, in the place that some thermal source can be moved, effectively can not make full use of the refrigerating capacity of radiant panel heat exchanger, thus the temperature difference reduced between radiant panel heat exchanger and thermal source, reduce the radiation effect of radiant panel heat exchanger.Radiant panel structure 100 of the present invention by the reciprocating motion of adjusting part 110 drive reflection subassembly 120 around central tube assembly 130 rotate accommodation reflex plate 122 towards, make reflecting plate 122 pairs of quasi-thermal sources, make reflecting plate 122 can reflex on heat exchanger tube 131 by the infrared waves that thermal source sends, so that radiant panel structure 100 can make full use of thermal source, thus improve the efficiency of radiation heat transfer.

As a kind of embodiment, skeleton mechanism 121 comprises parabolic portion 1212 and support portion 1211, parabolic portion 1212 is arranged on support portion 1211, reflecting plate 122 is arranged in parabolic portion 1212, support portion 1211 is arranged on heat exchanger tube 131, and the position that heat exchanger tube 131 is installed in support portion 1211 is the center in parabolic portion 1212.In the present invention, parabolic portion 1212 comprises two arc seamed edges and two straightedge limits, and straightedge limit and arc seamed edge are connected the parabolic portion 1212 being enclosed to form closed frame-type successively, and reflecting plate 122 is arranged in the parabolic portion 1212 of frame-type.Further, the cross sectional shape of reflecting plate 122 is parabola shaped.The shape of reflecting plate 122 should adapt with the shape in parabolic portion 1212, so that reflecting plate 122 can be installed in parabolic portion 1212.Certainly, reflecting plate 122 can by making the material of bending, and now reflecting plate 122 can be tabular, when mounted, as long as reflecting plate 122 is converted into parabola shaped being installed in parabolic portion 1212.

Simultaneously, the position of support portion 1211 mounting center pipe assembly 130 is the focal position in parabolic portion 1212, and like this, the infrared waves that thermal source sends can reflex on central tube assembly 130 by reflecting plate 122 better, the stability of rotation of reflection subassembly 120 can also be ensured, swelling and hanging down of either of the testes phenomenon can not occur.

As a kind of embodiment, reflecting plate 122 is coated with highly-reflective coating on the surface of central tube assembly 130, and namely reflecting plate 122 is coated with highly-reflective coating on the surface of pipe heat pipe side, and highly-reflective coating can improve the reflectivity of infrared waves.Will reflex to after the infrared waves that thermal source sends touch the highly-reflective coating on reflecting plate 122 on heat exchanger tube 131, highly-reflective coating ensures that infrared waves can effectively concentrate on heat exchanger tube 131.

As a kind of embodiment, reflection subassembly 120 also comprises bearing 123, and the support portion 1211 of skeleton mechanism 121 is arranged on the infrared through on pipe 132 of central tube assembly 130 by bearing 123.Skeleton mechanism 121 around infrared rotate through pipe 132 time, ensure that skeleton mechanism 121 can stability of rotation by bearing 123, simultaneously, the infrared focal position being always in the parabolic portion 1212 of skeleton mechanism 121 through pipe 132 can also be ensured when adjustment skeleton mechanism 121, ensure that skeleton mechanism 121 can not twist.And bearing 123 is rolling bearing, can ensure that skeleton mechanism 121 can stability of rotation further.Certainly, annular rotating ring can be arranged to away from the one end in parabolic portion 1212 in support portion 1211, heat exchanger tube 131 is sleeved in the rotating ring of annular, skeleton mechanism 121 rotates, drive the rotating ring of support portion 1211 to rotate around heat exchanger tube 131, so also can realize regulating radiant panel structure 100 towards.In the present embodiment, annular rotating ring is arranged to away from the one end in parabolic portion 1212 in support portion 1211, and the support portion 1211 of skeleton mechanism 121 is by installing bearing 123 in rotating ring.

As a kind of embodiment, central tube assembly 130 also comprises infrared through pipe 132 and seal 133, is infraredly sleeved on heat exchanger tube 131 through pipe 132.Heat exchanger tube 131 forms vacuum layer through pipe 132 by seal 133 with infrared.Heat exchanger tube 131 is sealed by seal 133 through pipe 132 with infrared, makes heat exchanger tube 131 and infraredly forms vacuum layer through between pipe 132.Now, the skeleton mechanism 121 in reflection subassembly 120 is arranged on infrared through on pipe 132, to improve the service life of heat exchanger tube 131.The infrared infrared waves that thermal source can be allowed to send through pipe 132 pass through, so that infrared waves are absorbed by heat exchanger tube 131, heat are transmitted the fluid in heat exchanger tube 131.The not direct ingress of air of heat exchanger tube 132, the outside condensation of heat exchanger tube 132 can be prevented, reduce the heating of upper strata hot-air exchange heat pipe 132, thus ensure the larger temperature difference, so that radiant panel structure 100 can make full use of the heat of thermal source, thus improve the efficiency of radiation heat transfer.

Further, heat exchanger tube 131 and the infrared axis collinear through pipe 132, to ensure that heat exchanger tube 131 can be positioned at the focal position in parabolic portion 1212.Increasing a coaxial infrared object through pipe 132 at the skin of heat exchanger tube 131 is: the outside condensation that can prevent heat exchanger tube 131 on the one hand; On the other hand, when radiant panel structure 100 of the present invention is positioned at that top, space hot-air comparatively concentrates local time, heat up under preventing the hot-air convection effect in heat exchanger tube 131 spatially portion, reduce the fluid heating in convection current exchange heat pipe 131, thus ensure to there is the larger temperature difference between radiant panel structure 100 and thermal source, improve radiation effect, the heat exchange between the hot-air on top, space can also be reduced simultaneously.

At present, for ceiling mounting type radiant panel heat exchanger, radiant panel heat exchanger is generally in the place that above space, hot-air is comparatively concentrated, under cooling condition, hot-air convection can make radiant panel heat exchanger heat up, thus the temperature difference reduced between radiant panel heat exchanger and thermal source, reduce the radiation effect of radiant panel heat exchanger.Radiant panel structure 100 of the present invention is formed vacuum layer through pipe 132 by the heat exchanger tube of central tube assembly 130 131 and reduces with infrared the heating that the fluid in heat pipe 132 exchange in convection current, thus the efficiency of raising radiation heat transfer.

Further, the two ends of heat exchanger tube 131 protrude from infrared through pipe 132, the infrared two ends through pipe 132 are sealed by seal 133, and heat exchanger tube 131 and infraredly form vacuum layer through between pipe 132, the fluid in heat exchanger tube 131 can be flow in other heat exchanger tubes.Certainly, infraredly heat exchanger tube 131 can be wrapped through pipe 132, to improve the service life of heat exchanger tube 131.Further, central tube assembly 130 also comprises pipe joint 134, pipe joint 134 is separately positioned on the two ends of heat exchanger tube 131, heat exchanger tube 131 is connected with other heat exchanger tube by flexible pipe simultaneously, pipe joint 134 connects heat exchanger tube 131 and the flexible pipe of arbitrary neighborhood, so that the flowing of heat exchanger tube 131 inner fluid.For the ease of tube connector joint 134, protruding from that the two ends of heat exchanger tube 131 can be suitable is infrared through pipe 132.Again further, the outer surface of heat exchanger tube 131 has for absorbing ultrared absorber coatings, makes heat exchanger tube 131 effectively can absorb the infrared waves reflected from reflecting plate 122, increases the absorptivity of heat exchanger tube 131 pairs of infrared waves.

Adjusting part 110 can for coupler construction or latch structure etc. can accommodation reflex assembly 120 towards and reflection subassembly 120 is fixed on the structure on central tube assembly 130.When adjusting part 110 is coupler construction, the hook portion of coupler construction is arranged on central tube assembly 130, the draw-in groove of coupler construction is arranged in skeleton mechanism 121, when reflection subassembly 120 turns to a certain position around central tube assembly 130, hooked by the hook portion of coupler construction and in draw-in groove, reflection subassembly 120 is positioned, to ensure that reflection subassembly 120 can to quasi-thermal source.The hook portion of coupler construction and the position of draw-in groove can exchange.The principle of latch structure is identical with coupler construction.Certainly, adjusting part 110 structure that reflection subassembly 120 can also be driven to rotate for other.

In the present invention, adjusting part 110 is arranged on reflection subassembly 120, and adjusting part 110 moves back and forth and drives reflection subassembly 120 to rotate around central tube assembly 130.Radiant panel structure 100 of the present invention by adjusting part 110 come accommodation reflex assembly 120 towards.Adjusting part 110 comprises and hangs muscle 111 and suspension ring 112, and suspension ring 112 are arranged in skeleton mechanism 121, and hang muscle 111 and be movably arranged on suspension ring 112, hanging muscle 111 can move back and forth simultaneously.Hang muscle 111 to move back and forth and skeleton mechanism 121 can be driven to rotate around central tube assembly 130 by suspension ring 112, skeleton mechanism 121 drives reflecting plate 122 to rotate.Hang muscle 111 can move back and forth, namely hanging muscle 111 can move up and down, and that is, hang muscle 111 and move downward, hang between muscle 111 and suspension ring 112 and there is not active force, skeleton mechanism 121 rotates from side around central tube assembly 130 under self gravitation effect; Hang muscle 111 to move upward, hang muscle 111 and pull suspension ring 112, make to hang the active force that muscle 111 is subject to upwards, hang muscle 111 and drive skeleton mechanism 121 to rotate around central tube assembly 130 from opposite side, by the reflection direction regulating the skeleton mechanism 121 in direction to change reflecting plate 122.

Radiant panel structure 100 of the present invention is arranged on furred ceiling or wall place by adjusting part 110, and regulate adjusting part 110 by machine or manual regulative mode, adjusting part 110 can move back and forth and then drive reflection subassembly 120 to rotate.Can be convenient to like this accommodation reflex plate 122 towards, make reflecting plate 122 can to quasi-thermal source, obtain ascent maximum between reflecting plate 122 and thermal source.Further, suspension ring 112 and skeleton mechanism 121 are integrated.Certainly, suspension ring 112 and skeleton mechanism 121 also can for removably connecting.

At present, for ceiling mounting type radiant panel heat exchanger, radiant panel heat exchanger is generally in the place that above space, hot-air is comparatively concentrated, hot-air convection can make radiant panel heat exchanger heat up, current radiant panel heat exchanger can not adjust after mounting radiant panel towards, in the place that some thermal source can be moved, effectively can not make full use of the refrigerating capacity of radiant panel heat exchanger, reduce the radiation effect of radiant panel heat exchanger.Radiant panel structure 100 of the present invention by the reciprocating motion of adjusting part 110 drive reflection subassembly 120 around central tube assembly 130 rotate accommodation reflex plate 122 towards, make reflecting plate 122 pairs of quasi-thermal sources, make reflecting plate 122 can reflex on heat exchanger tube 131 by the infrared waves that thermal source sends, so that radiant panel structure 100 can make full use of thermal source, thus improve the efficiency of radiation heat transfer.

The operation principle of radiant panel structure 100 of the present invention is: it is infrared through on pipe 132 that the infrared waves that thermal source gives out are reflexed in central tube assembly 130 by the reflecting plate 122 in reflection subassembly 120, infrared waves are by infrared through pipe 132, absorbed by the absorber coatings on heat exchanger tube 131 surface, the heat of thermal source is conducted to the fluid in heat exchanger tube 131 by heat exchanger tube 131.When thermal source is moved, by machine or manual regulative mode, regulate the position of hanging muscle 111 in adjusting part 110, the skeleton mechanism 121 in reflection subassembly 120 can rotate around heat exchanger tube 131, makes reflecting plate 122 just to thermal source.Due between skeleton mechanism 121 with central tube assembly 130 for bearing is connected, so central tube assembly 130 can not twist, just may produce a small amount of lateral displacement.

Radiant panel heat exchanger of the present invention comprises the radiant panel structure 100 described in above-mentioned arbitrary technical characteristic, and radiant panel heat exchanger makes full use of by radiant panel structure 100 heat that thermal source sends, and improves the efficiency of radiant panel heat exchanger radiation heat transfer.

The above embodiment only have expressed several embodiment of the present invention, and it describes comparatively concrete and detailed, but therefore can not be interpreted as the restriction to the scope of the claims of the present invention.It should be pointed out that for the person of ordinary skill of the art, without departing from the inventive concept of the premise, can also make some distortion and improvement, these all belong to protection scope of the present invention.Therefore, the protection domain of patent of the present invention should be as the criterion with claims.

Claims (11)

1. a radiant panel structure, it is characterized in that, comprise reflection subassembly (120), central tube assembly (130) and adjusting part (110), described reflection subassembly (120) is arranged on described central tube assembly (130), and described central tube assembly (130) is positioned at the focal position of described reflection subassembly (120), described adjusting part (110) is arranged on described reflection subassembly (120), described adjusting part (110) can regulate described reflection subassembly (120) towards;

Wherein, described reflection subassembly (120) comprises skeleton mechanism (121) and reflecting plate (122), described reflecting plate (122) is arranged on described skeleton mechanism (121), described central tube assembly (130) comprises heat exchanger tube (131), and described skeleton mechanism (121) is arranged on described heat exchanger tube (131).

2. radiant panel structure according to claim 1, it is characterized in that, described adjusting part (110) comprises and hangs muscle (111) and suspension ring (112), described suspension ring (112) are arranged on described skeleton mechanism (121), described in hang muscle (111) and be movably arranged on described suspension ring (112).

3. radiant panel structure according to claim 1, it is characterized in that, described skeleton mechanism (121) comprises parabolic portion (1212) and support portion (1211), described parabolic portion (1212) is arranged on described support portion (1211), described reflecting plate (122) is arranged on described parabolic portion (1212), described support portion (1211) is movably arranged on described heat exchanger tube (131), and the position that described support portion (1211) install described central tube assembly (130) is the focal position of described parabolic portion (1212).

4. radiant panel structure according to claim 3, is characterized in that, described reflecting plate (122) is coated with highly-reflective coating on the surface of described central tube assembly (130).

5. radiant panel structure according to claim 3, is characterized in that, the cross sectional shape of described reflecting plate (122) is parabola shaped.

6. the radiant panel structure according to any one of claim 3 to 5, it is characterized in that, described reflection subassembly (120) also comprises bearing (123), and the support portion (1211) of described skeleton mechanism (121) is arranged on described central tube assembly (130) by described bearing (123).

7. radiant panel structure according to claim 6, it is characterized in that, described central tube assembly (130) also comprises infrared through pipe (132) and seal (133), describedly infraredly be sleeved on the outside of described heat exchanger tube (131) through pipe (132), described heat exchanger tube (131) and describedly infraredly form vacuum layer through managing between (132) by described seal (133).

8. radiant panel structure according to claim 7, it is characterized in that, described heat exchanger tube (131) is with infrared coaxial through managing (132), and the two ends of described heat exchanger tube (131) protrude from described infrared through pipe (132).

9. radiant panel structure according to claim 8, it is characterized in that, described central tube assembly (130) also comprises pipe joint (134), and described pipe joint (134) is separately positioned on the two ends of described heat exchanger tube (131).

10. radiant panel structure according to claim 7, is characterized in that, the outer surface of described heat exchanger tube (131) has for absorbing ultrared absorber coatings.

11. 1 kinds of radiant panel heat exchangers, is characterized in that, comprise the radiant panel structure (100) as described in any one of claim 1 to 10.