CN112577132A

CN112577132A - Radiant panel with heating and anion releasing functions

Info

Publication number: CN112577132A
Application number: CN201911262843.8A
Authority: CN
Inventors: 宗陆群
Original assignee: Chengdu Pinxin Tiannuan Energy Saving Technology Co ltd
Current assignee: Chengdu Pinxin Tiannuan Energy Saving Technology Co ltd
Priority date: 2019-12-10
Filing date: 2019-12-10
Publication date: 2021-03-30

Abstract

The invention discloses a radiant panel with the effects of heating and releasing negative ions, which comprises a radiant panel shell, a heat-insulating layer, an infrared reflecting layer, an electric heating pipe, a negative ion spraying pipe network and a negative ion emitting unit, wherein the radiant panel shell is flat and box-shaped, the surface of the radiant panel shell facing to the outside is of an open structure, the heat-insulating layer is adhered to the inner wall of the radiant panel shell, the infrared reflecting layer is adhered to the outer side wall of the heat-insulating layer, power supply plugs of the electric heating pipe are installed at two ends of the inner side of the radiant panel shell and used for connecting the electric heating pipe, the negative ion spraying pipe network is arranged at the opening of the radiant panel shell, and the negative ion spraying pipe network is communicated with the negative ion emitting. The invention is also provided with the negative ion spraying pipe network which can play a role in protecting the electric heating pipe and reduce the temperature fluctuation amplitude when the temperature control system participates in temperature regulation. The negative ion spraying pipe network is communicated with the negative ion emission unit, so that the negative ion dispersing effect and the coverage area are improved.

Description

Radiant panel with heating and anion releasing functions

Technical Field

The invention relates to the field of heating, in particular to a radiant panel with the effects of heating and releasing negative ions.

Background

The radiation plate is a plate-shaped heating ventilation air conditioning device, and is a heater emitting infrared radiation or a refrigerator absorbing infrared radiation. The process of heat transfer from the high-temperature object to the low-temperature object by means of infrared radiation is called thermal radiation; the radiant panel heating is mainly applied to public places with high spaces, such as industrial plants, warehouses, stadiums, airplane repair warehouses, auditoriums, schools, hospitals, natatoriums, farms, market supermarkets and the like, and even in indoor or even semi-open full-open spaces with poor heat insulation, a good heating effect can be achieved.

The radiation plate is a plate material used for heating articles, and the current radiation plates are various in types, such as an electric heating radiation plate, an infrared combustion radiation plate and the like; and the current radiation plate has single function, does not have the position adjusting function and has great practical limitation.

Disclosure of Invention

The present invention is directed to a radiant panel with heating and anion releasing functions, so as to solve the above problems in the prior art.

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

the utility model provides a radiant panel of heating and release anion efficiency, includes radiant panel shell, heat preservation, infrared reflection stratum, electric heating pipe, anion blowout pipe network and anion emission unit, the radiant panel shell is flat box-like, and the radiant panel shell is used for the one side towards the outside to be open structure, and the inner wall bonding of radiant panel shell has the one deck heat preservation, and the lateral wall bonding of heat preservation has one deck infrared reflection stratum, electric heating pipe power supply plug is installed at the inboard both ends of radiant panel shell and is used for connecting electric heating pipe, the opening part of radiant panel shell is provided with anion blowout pipe network, anion blowout pipe network and anion emission unit intercommunication.

As a further scheme of the invention: the infrared reflecting layer is ZS-high temperature heat reflecting paint.

As a further scheme of the invention: the opening edge of the radiation plate shell is provided with a plurality of threaded holes, the connecting frame is provided with a plurality of through holes corresponding to the threaded holes, and the fixing screws penetrate through the through holes in the connecting frame and are in threaded connection with the threaded holes, so that the whole negative ion spraying pipe network is fixed at the opening of the radiation plate shell.

As a further scheme of the invention: the anion blowout pipe network mainly has many to violently manage and adjacent two root canal between the many longitudinal pipes of welded constitute, and violently manage and communicate each other between the longitudinal pipe to the anion is through the smooth outside injection of this anion blowout pipe network, violently manage and set up a plurality of air pocket that is used for spraying paint with the surface that the longitudinal pipe deviates from electric heating pipe, and the both ends of violently managing are sealed and pass through screw fixed connection on linking frame.

As a further scheme of the invention: the surface of any horizontal pipe in the anion ejection pipe network is welded with a connector communicated with the horizontal pipe, and the connector is connected with the output end of the anion emission unit through a pipeline, so that anions can enter the anion ejection pipe network and are finally dispersed and quickly ejected into the air.

As a further scheme of the invention: the negative ion emission unit mainly comprises a unit shell, an intermediate tank body, a negative ion generator, an air pump and an aviation plug, wherein a clamping groove is formed in the unit shell and used for fixing the intermediate tank body, through holes are formed in the surface of the intermediate tank body, the working end of the negative ion generator is inserted into the through hole in the surface of the intermediate tank body, and a rubber layer is filled between the outer surface of the negative ion generator and the inner wall of the through hole in the surface of the intermediate tank body, so that sealing is realized; an air inlet and an air outlet are formed in one end of the intermediate tank body, the air inlet of the intermediate tank body is fixedly connected inside the unit shell through a pipeline connection air pump, and the air outlet of the intermediate tank body is connected with a connector on the anion spraying pipe network through a pipeline to realize air supply.

As a further scheme of the invention: the power supply sections of the air pump and the negative ion generator are connected with the wiring ends of the aviation plugs fixed on the surface of the unit shell through wires.

As a further scheme of the invention: the back of the radiation plate shell is also connected with an adjusting support, the adjusting support mainly comprises a connecting rod, a rotating arm, a sliding chute, a locking bolt and a mounting plate, one end of the connecting rod and one end of the rotating arm are respectively hinged to the back of the radiation plate shell at positions close to the two ends through a hinge structure, the middle of the rotating arm is provided with the sliding chute, the other end of the connecting rod is provided with a threaded hole, the locking bolt penetrates through one side of the sliding chute and is in threaded connection with the threaded hole, meanwhile, a rubber pad is arranged between the rotating arm and the connecting rod and sleeved on the bolt, the rotating arm and the connecting rod extrude the rubber pad through the locking bolt, and positioning at a certain; the other end of the rotating arm is hinged on the mounting plate, and the four corners of the mounting plate are provided with through holes and are fixedly connected on the carrier through screws.

As a further scheme of the invention: the outer surfaces of the two sides of the radiation plate shell are also connected with handrails.

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

the invention realizes the purposes of heat preservation and directional reflection of temperature radiation by arranging the heat preservation layer and the infrared reflection layer in the shell of the radiation plate, improves the radiation amount of a single surface and improves the heating effect.

The negative ion spraying pipe network can play a role in protecting the electric heating pipe, in addition, the negative ion spraying pipe network is made of a material that a black paint layer is sprayed on the outer surface of the stainless steel pipeline, and the negative ion spraying pipe network can play a role in energy storage due to the fact that the interior of the negative ion spraying pipe network is a hollow structure, and the temperature fluctuation range of the temperature control system when the temperature control system participates in temperature regulation is reduced.

The negative ion spraying pipe network is communicated with the negative ion emission unit, and the negative ions are conveyed to the negative ion spraying pipe network and finally sent into the air by utilizing the air supply pressurization of the air pump in the negative ion emission unit, so that the dispersing effect and the coverage area are improved.

Drawings

Fig. 1 is a schematic structural view of a radiation plate with the effects of heating and releasing negative ions.

Fig. 2 is a bottom view of a radiant panel with heating and anion releasing functions.

Fig. 3 is a schematic structural view of an anion ejection pipe network in a radiation plate with the effects of heating and releasing anions.

Fig. 4 is a schematic structural diagram of an anion emission unit in a radiation plate with the effects of heating and releasing anions.

Fig. 5 is a schematic view of a connection structure of a radiant panel housing, an adjusting bracket and a handrail in the radiant panel with the effects of heating and releasing negative ions.

In the figure: the device comprises a radiation plate shell 1, a heat preservation layer 2, an infrared reflection layer 3, an electric heating pipe 4, an anion spraying pipe network 5, an anion emission unit 6, a transverse pipe 7, a longitudinal pipe 8, a unit shell 9, a middle tank body 10, an anion generator 11, an air pump 12, an aviation plug 13, a handrail 14, a connecting rod 15, a rotating arm 16, a sliding groove 17, a locking bolt 18, a mounting plate 19 and a connecting frame 20.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 5, in an embodiment of the present invention, a radiation plate with a heating and negative ion releasing function includes a radiation plate housing 1, a heat insulating layer 2, an infrared reflecting layer 3, an electric heating pipe 4, a negative ion spraying pipe network 5, a negative ion emitting unit 6, a horizontal pipe 7, a vertical pipe 8, a unit housing 9, an intermediate tank 10, a negative ion generator 11, an air pump 12, an aviation plug 13, a handrail 14, a connecting rod 15, a rotating arm 16, a sliding groove 17, a locking bolt 18, a mounting plate 19 and a connecting frame 20, wherein the radiation plate housing 1 is in a flat box shape, a surface of the radiation plate housing 1 facing outward is in an open structure, the heat insulating layer 2 is bonded to an inner wall of the radiation plate housing 1, a layer of the infrared reflecting layer 3 is bonded to an outer side wall of the heat insulating layer 2, the infrared reflecting layer 3 may be ZS-233 high temperature heat reflecting paint, so as to reflect heat quantity of the heat toward, the heat loss is reduced, and meanwhile, the unidirectional heat radiation quantity is increased; and power supply plugs 20 of the electric heating pipes 4 are installed at two ends of the inner side of the radiant panel shell 1 and are used for connecting the electric heating pipes 4 to realize the emission of a heat source.

The opening part of radiant panel shell 1 is provided with anion blowout pipe network 5, and anion blowout pipe network 5 mainly have many violently to manage 7 and adjacent two root canal between 7 welded many vertical pipes 8 constitute, and violently manage and communicate each other between 7 and the vertical pipe 8 to anion through this anion blowout pipe network 5 smooth outside injection, violently manage 7 and vertical pipe 8 and set up a plurality of air pocket that is used for spraying paint on the surface that deviates from electric heating pipe 4, and violently manage 7 both ends sealed and through screw fixed connection on linking frame 20, wherein the connector of the surface welding rather than the intercommunication of any one violently pipe 7, the connector passes through the output of pipe connection anion emission unit 6, so that the anion enters into anion blowout pipe network 5 in, is at last dispersed fast spray to the air.

A plurality of screw holes are formed in the edge of an opening of the radiation plate shell 1, a plurality of through holes corresponding to the screw holes are formed in the connecting frame 20, fixing screws penetrate through the through holes in the connecting frame 20 and are connected into the screw holes in a threaded mode, therefore, the whole anion spraying pipe network 5 is fixed at the opening of the radiation plate shell 1 and can play a role in protection, in addition, the anion spraying pipe network 5 is made of a material of spraying a black paint layer on the outer surface of the stainless steel pipeline, the anion spraying pipe network 5 can play an energy storage effect due to the fact that the interior of the anion spraying pipe network is a hollow structure, and the temperature fluctuation range of the temperature control system when the temperature control system participates in temperature regulation is reduced.

The anion emission unit 6 mainly comprises a unit shell 9, an intermediate tank body 10, an anion generator 11, an air pump 12 and an aviation plug 13, wherein a clamping groove is formed in the unit shell 9 and used for fixing the intermediate tank body 10, through holes are formed in the surface of the intermediate tank body 10, the working end of the anion generator 11 is inserted into the through hole in the surface of the intermediate tank body 10, and meanwhile, a rubber layer is filled between the outer surface of the anion generator 11 and the inner wall of the through hole in the surface of the intermediate tank body 10, so that sealing is realized; one end of the intermediate tank body 10 is provided with an air inlet and an air outlet, the air inlet of the intermediate tank body 10 is fixedly connected inside the unit shell 9 through a pipeline connecting air pump 12, the air outlet of the intermediate tank body 10 is connected with a connector on the negative ion spraying pipe network 5 through a pipeline to realize air supply, and the power supply sections of the air pump 12 and the negative ion generator 11 are connected with a wiring end of an aviation plug 13 fixed on the surface of the unit shell 9 through a wire to realize power supply; the actual working principle is that the negative ion generator 11 is used for generating negative ions, then the air pump is used for supplying air and increasing pressure to convey the negative ions to the negative ion spraying pipe network 5, and finally the negative ions are sent into the air.

The back of the radiation plate shell 1 is also connected with an adjusting bracket, the adjusting bracket mainly comprises a connecting rod 15, a rotating arm 16, a sliding chute 17, a locking bolt 18 and a mounting plate 19, one end of the connecting rod 15 and one end of the rotating arm 16 are respectively hinged to the back of the radiation plate shell 1 at positions close to two ends through a hinge structure, the middle of the rotating arm 16 is provided with the sliding chute 17, the other end of the connecting rod 15 is provided with a threaded hole, the locking bolt penetrates through one side of the sliding chute 17 and is in threaded connection with the threaded hole, a rubber pad is arranged between the rotating arm 16 and the connecting rod 15 and sleeved on the bolt, and the rotating arm 16 and the connecting rod 15 extrude the rubber pad through the locking bolt, so that the positioning is realized; the other end of the rotating arm 16 is hinged on the mounting plate 19, the four corners of the mounting plate 19 are provided with through holes and fixedly connected on a carrier (a wall or other equipment rack) through screws, and handrails 14 are further connected to the outer surfaces of the two sides of the radiation plate shell 1 so as to be conveniently mounted at positions which can be touched by hands for manual adjustment.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. A radiant panel with the effects of heating and releasing negative ions comprises a radiant panel shell (1), a heat-insulating layer (2), an infrared reflecting layer (3), an electric heating pipe (4), a negative ion spraying pipe network (5) and a negative ion emitting unit (6), it is characterized in that the radiation plate shell (1) is in a flat box shape, the surface of the radiation plate shell (1) facing to the outside is in an open structure, the inner wall of the radiation plate shell (1) is bonded with a heat-insulating layer (2), the outer side wall of the heat-insulating layer (2) is bonded with an infrared reflecting layer (3), the two ends of the inner side of the radiant panel shell (1) are provided with power supply plugs of the electric heating pipes (4) for connecting the electric heating pipes (4), an opening of the radiation plate shell (1) is provided with a negative ion spraying pipe network (5), and the negative ion spraying pipe network (5) is communicated with a negative ion emission unit (6).

2. The radiant panel with heating and anion releasing functions as claimed in claim 1, wherein the infrared reflecting layer (3) is ZS- (233) high temperature heat reflecting paint.

3. The radiant panel with heating and anion releasing functions as claimed in claim 1, wherein the opening edge of the radiant panel housing (1) is provided with a plurality of threaded holes, the connecting frame (20) is provided with a plurality of through holes corresponding to the threaded holes, and the fixing screws pass through the through holes on the connecting frame (20) and are screwed in the threaded holes, so that the whole anion spraying pipe network (5) is fixed at the opening of the radiant panel housing (1).

4. The radiant panel with heating and anion releasing functions as claimed in claim 1 or 3, wherein the anion spraying pipe network (5) mainly comprises a plurality of transverse pipes (7) and a plurality of longitudinal pipes (8) welded between two adjacent transverse pipes (7), the transverse pipes (7) and the longitudinal pipes (8) are communicated with each other so that anions can be smoothly sprayed outwards through the anion spraying pipe network (5), a plurality of air holes for painting are formed on the surfaces of the transverse pipes (7) and the longitudinal pipes (8) departing from the electric heating pipe (4), and two ends of the transverse pipes (7) are sealed and fixedly connected to the connecting frame (20) through screws.

5. The radiant panel with heating and anion releasing functions as claimed in claim 4, wherein the surface of any one horizontal tube (7) in the anion spraying pipe network (5) is welded with a connector communicated with the horizontal tube, and the connector is connected with the output end of the anion emission unit (6) through a pipeline, so that anions can enter the anion spraying pipe network (5) and finally be dispersed and rapidly sprayed into the air.

6. The radiant panel with the effects of heating and releasing negative ions as claimed in claim 5, wherein the negative ion emitting unit (6) mainly comprises a unit housing (9), an intermediate tank body (10), a negative ion generator (11), an air pump (12) and an aviation plug (13), wherein a clamping groove is formed in the unit housing (9) and used for fixing the intermediate tank body (10), a plurality of through holes are formed in the surface of the intermediate tank body (10), the working end of the negative ion generator (11) is inserted into the through hole in the surface of the intermediate tank body (10), and a rubber layer is filled between the outer surface of the negative ion generator (11) and the inner wall of the through hole in the surface of the intermediate tank body (10) so as to realize sealing; an air inlet hole and an air outlet hole are formed in one end of the intermediate tank body (10), the air inlet hole of the intermediate tank body (10) is fixedly connected inside the unit shell (9) through a pipeline connection air pump (12), and the air outlet hole of the intermediate tank body (10) is connected with a connector on the negative ion spraying pipe network (5) through a pipeline to achieve air supply.

7. The radiant panel with heating and anion releasing functions as claimed in claim 6, wherein the power supply sections of the air pump (12) and the anion generator (11) are connected with the terminals of the aviation plug (13) fixed on the surface of the unit housing (9) through wires.

8. The radiant panel with the effects of heating and releasing negative ions as claimed in claim 1, wherein the back of the radiant panel housing (1) is further connected with an adjusting bracket, the adjusting bracket is mainly composed of a connecting rod (15), a rotating arm (16), a sliding slot (17), a locking bolt (18) and a mounting plate (19), one end of the connecting rod (15) and one end of the rotating arm (16) are hinged to the back of the radiant panel housing (1) near to the two ends through a hinge structure, the middle of the rotating arm (16) is provided with the sliding slot (17), the other end of the connecting rod (15) is provided with a threaded hole, the locking bolt penetrates through one side of the sliding slot (17) and is in threaded connection with the threaded hole, a rubber pad is arranged between the rotating arm (16) and the connecting rod (15) and sleeved on the bolt, the rotating arm (16) and the connecting rod (15) extrude the rubber pad through the locking, the positioning is conveniently realized at a certain angle position in the adjusting process; the other end of the rotating arm (16) is hinged on the mounting plate (19), and the four corners of the mounting plate (19) are provided with through holes and fixedly connected on the carrier through screws.

9. The radiant panel with heating and anion releasing functions as claimed in claim 1 or 8, wherein handrails (14) are further connected to the outer surfaces of both sides of the radiant panel housing (1).