CN209877378U - High-efficient condensing chamber is used to flue gas condenser - Google Patents

Abstract

The utility model relates to a flue gas condenser is with high-efficient condensation chamber, it bears the chamber including keeping warm, the alloy heat dissipation base member, the glass heat exchange tube, the electrical heating membrane, heat transfer copper pipe, wherein the alloy heat dissipation base member inlays in the heat preservation bears the intracavity and coaxial distribution, a bearing groove is established to alloy heat dissipation base member surface, alloy heat dissipation base member surface is through bearing groove and heat transfer copper pipe interconnect, establish two at least location chambeies in the alloy heat dissipation base member, and all establish a glass heat exchange tube and with the coaxial distribution of glass heat exchange tube in every location intracavity, the cladding of electrical heating membrane is at alloy heat dissipation base member both ends terminal surface. This novel one side integrates the degree height, and the commonality is good to have good bearing capacity and anti external force impact ability, on the other hand has good heat exchange ability and the operational capability that adjusts the temperature, and when improving heat exchange ability, has good heat preservation ability in addition, and heat loss when can effectual reduction equipment operation reduces equipment running cost.

Description

High-efficient condensing chamber is used to flue gas condenser

Technical Field

The utility model relates to a flue gas cooling equipment especially relates to a flue gas condenser is with high-efficient condensation chamber.

Background

At present, during operations such as flue gas detection and the like, the flue gas sample is required to be cooled and temperature-regulated, in order to meet the requirements of the flue gas sample cooling operation, the purpose of cooling the flue gas is achieved by mainly utilizing the traditional heat exchanger equipment and a refrigeration compressor system, but in use, the heat exchange cavity for cooling and temperature regulation of the currently used flue gas sample cooling equipment is always of the traditional equipment structure, although the equipment can be used, the equipment has relatively large volume and relatively low heat exchange efficiency, and in the process of cooling and temperature-regulating operation, the heat exchanger equipment used by the currently used equipment has the defect of poor heat preservation capability, the energy consumption of the operation of cooling and temperature-regulating the flue gas sample is relatively large when the operation of cooling and temperature-regulating the flue gas is influenced, meanwhile, when the heat exchanger equipment used by the currently used equipment is in operation, the positioning stability of the device is relatively insufficient, the device is easily damaged due to external force impact and air flow impact, and the stability, reliability and environment of the device operation are seriously influenced.

In addition, the flue gas condensing equipment based on traditional heat exchanger structure that uses in the present period often has better cooling ability to the flue gas in service, but when the flue gas temperature crosses lowly when needing to carry out the operation of heating, traditional heat exchanger equipment often does not all possess this ability, or need carry out equipment structure adjustment to the compressor system for the drive refrigeration to cause equipment operation energy consumption big the while, also leaded to the big and complicated drawback of equipment structure.

Therefore, in view of the current situation, there is an urgent need to develop a new flue gas condensing device to meet the needs of practical use.

SUMMERY OF THE UTILITY MODEL

To the not enough that exists on the prior art, the utility model provides a high-efficient condensation chamber is used to flue gas condenser, when this novel improvement heat exchange capacity, good heat preservation ability has in addition to but the heat loss of effectual reduction equipment operation, reduction equipment running cost.

In order to achieve the above purpose, the present invention is realized by the following technical solution:

a high-efficiency condensation chamber for a flue gas condenser comprises a heat-insulating bearing cavity, an alloy heat-radiating base body, a glass heat exchange tube, an electric heating film and a heat exchange copper tube, wherein the heat-insulating bearing cavity is of a closed cavity structure with a rectangular axial section, the lower end face of the heat-insulating bearing cavity is provided with at least one water outlet, the alloy heat-radiating base body is of a cylindrical structure, is embedded in the heat-insulating bearing cavity and is coaxially distributed with the heat-insulating bearing cavity, the side surface of the alloy heat-radiating base body and the side surface in the heat-insulating bearing cavity are mutually and slidably connected through at least one sliding chute, the lower end face of the alloy heat-radiating base body and the bottom of the heat-insulating bearing cavity are mutually connected through at least three bearing springs, the sliding chutes and the bearing springs are uniformly distributed around the axis of the heat-insulating bearing cavity and are parallel to the axis of the heat-insulating bearing cavity, the outer, the alloy heat dissipation substrate and the heat exchange copper pipes are coaxially distributed, two ends of each heat exchange copper pipe are located outside the heat preservation bearing cavity and are provided with connecting ends, at least two positioning cavities are arranged in the alloy heat dissipation substrate, the positioning cavities are distributed in parallel with the axis of the alloy heat dissipation substrate and are uniformly distributed around the axis of the alloy heat dissipation substrate, and each positioning cavity is internally provided with a glass heat exchange pipe and is coaxially distributed with the glass heat exchange pipe.

The glass heat exchange tube comprises a liquid storage tube, a flow guide tube and a sealing end, wherein the liquid storage tube is of a U-shaped groove-shaped structure with an axial section, a flow guide opening is formed in the lower end face of the liquid storage tube, the upper end face of the liquid storage tube is connected with the sealing end and forms a closed cavity structure, the flow guide tube is of a same shape and is of a U-shaped tubular structure which is coaxially distributed with the liquid storage tube, 80% -95% of the effective length of the flow guide tube is located in the liquid storage tube, two ends of the flow guide tube are located outside the sealing end, the tube section of the flow guide tube located in the liquid storage tube is of a spiral structure, the two ends of the flow guide tube located outside the liquid storage tube are provided with connecting ends, the end faces of the two ends of the flow guide opening and the two.

Furthermore, at least one temperature sensor is arranged on the inner surface of the heat-preservation bearing cavity, and the temperature sensor is abutted against the outer surface of the alloy heat-dissipation base body.

Furthermore, at least one electric heating wire is arranged on the inner surface of the heat-preservation bearing cavity, and the electric heating wires are distributed in a spiral structure around the axis of the heat-preservation bearing cavity.

Furthermore, the cross section of the bearing groove on the outer surface of the alloy heat dissipation base body is any one of an arc structure, a rectangular structure and an isosceles trapezoid structure, the cross section structure of the heat exchange copper pipe in the bearing groove is the same as that of the bearing groove, and the heat exchange copper pipes 1/3-2/3 are partially embedded in the bearing groove.

Furthermore, the alloy heat dissipation substrate corresponding to the bottom of the bearing groove is provided with a plurality of through holes, the aperture of each through hole is not more than 2 mm, the distance between every two adjacent through holes is not less than 10 mm, and the axes of the through holes are perpendicular to and intersected with the axis of the alloy heat dissipation substrate.

Further, a liquid heat exchange medium is arranged in a liquid storage pipe of the glass heat exchange pipe, and the volume of the liquid heat exchange medium is not less than 80% of the volume of the liquid storage pipe.

Furthermore, control valves are arranged between the connecting ends and the connecting positions of the heat exchange copper pipe and the flow guide pipe and at the position of the flow guide pipe opening.

This novel one side integrates the degree height, and the commonality is good to have good bearing capacity and anti external force impact ability, thereby effectual stability, reliability and the environmental suitability when having improved this novel operation, on the other hand has good heat exchange ability and the operational capability that adjusts the temperature, and when improving heat exchange ability, has good heat preservation ability in addition, and can effectually reduce the heat loss when equipment moves, reduces equipment running cost.

Drawings

The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic sectional partial structure view of an alloy heat dissipation substrate.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

The high-efficiency condensation chamber for the flue gas condenser comprises a heat-insulating bearing cavity 1, an alloy heat-radiating base body 2, a glass heat exchange tube 3, an electric heating film 4 and a heat exchange copper tube 5, wherein the heat-insulating bearing cavity 1 is a closed cavity structure with a rectangular axial section, the lower end surface of the heat-insulating bearing cavity is provided with at least one water outlet 6, the alloy heat-radiating base body 2 is a cylindrical columnar structure, is embedded in the heat-insulating bearing cavity 1 and is coaxially distributed with the heat-insulating bearing cavity 1, the side surface of the alloy heat-radiating base body 2 is mutually connected with the inner side surface of the heat-insulating bearing cavity 1 in a sliding way through at least one sliding chute 7, the lower end surface of the alloy heat-radiating base body 2 is mutually connected with the bottom of the heat-insulating bearing cavity 1 through at least three bearing springs 8, the sliding chutes 7 and the bearing springs 8 are uniformly distributed around the axis of the heat-, bearing groove 9 encircles 2 axes of alloy heat dissipation base member and is the heliciform structural distribution, 2 surfaces of alloy heat dissipation base member pass through bearing groove 9 and heat transfer copper pipe 5 interconnect, and mutual coaxial distribution between alloy heat dissipation base member 2 and heat transfer copper pipe 5, heat transfer copper pipe 5 both ends all are located the heat preservation and bear the weight of outside the chamber 1 and establish connection end 10, establish two at least location chambeies 11 in the alloy heat dissipation base member 2, location chamber 11 and 2 axes parallel distribution of alloy heat dissipation base member encircle 2 axes equipartitions of alloy heat dissipation base member, and all establish a glass heat exchange tube 3 and with 3 coaxial distributions of glass heat exchange tube in every location intracavity 11.

In this embodiment, the glass heat exchange tube 3 comprises a liquid storage tube 31, a flow guide tube 32 and a sealing end 33, wherein the liquid storage pipe 31 is a U-shaped groove-shaped structure with an axial section, the lower end surface of the liquid storage pipe is provided with a flow guide port 34, the upper end surface of the liquid storage pipe is connected with a sealing end head 33 to form a closed cavity structure, the flow guide pipes 32 are shared and are of a U-shaped tubular structure which is coaxially distributed with the liquid storage pipe 31, 80-95% of the effective length is positioned in the liquid storage tube 31, the two ends are positioned outside the sealing end head 33, wherein the pipeline section that honeycomb duct 32 is located liquid storage pipe 31 is helical structure, and the honeycomb duct 32 both ends that are located the outside of liquid storage pipe 31 all establish connection end 10, and water conservancy diversion mouth 34 and honeycomb duct 32 both ends terminal surface all surpass the 2 both ends terminal surfaces of alloy heat dissipation base member 5 millimeters at least, and electric heating membrane 4 totally two, the cladding respectively on the 2 both ends terminal surfaces of alloy heat dissipation base member and with the coaxial distribution of alloy heat dissipation base member 2.

At least one temperature sensor 12 is arranged on the inner surface of the heat-insulating bearing cavity 1, the temperature sensor 12 is abutted against the outer surface of the alloy heat-radiating base body 2, at least one electric heating wire 13 is arranged on the inner surface of the heat-insulating bearing cavity 1, and the electric heating wires 13 are distributed in a spiral structure around the axis of the heat-insulating bearing cavity 1.

Meanwhile, the cross section of the bearing groove 9 on the outer surface of the alloy heat dissipation base body 2 is any one of an arc structure, a rectangular structure and an isosceles trapezoid structure, the cross section structure of the heat exchange copper pipe 5 in the bearing groove 9 is the same as that of the bearing groove 9, and 1/3-2/3 parts of the heat exchange copper pipe 5 are embedded in the bearing groove 9.

In addition, the alloy heat dissipation substrate corresponding to the bottom of the bearing groove 9 is provided with a plurality of through holes 14, the aperture of each through hole 14 is not more than 2 mm, the distance between every two adjacent through holes 14 is not less than 10 mm, and the axes of the through holes 14 are perpendicular to and intersected with the axis of the alloy heat dissipation substrate 2.

Preferably, the liquid storage tube 31 of the glass heat exchange tube 3 is internally provided with a liquid heat exchange medium 35, and the volume of the liquid heat exchange medium 35 is not less than 80% of the volume of the liquid storage tube 31.

Further preferably, control valves 15 are arranged between the connecting ends 10 and the heat exchange copper pipe 5 and between the connecting positions of the guide pipe 32 and at the position of the guide pipe opening 34.

This is novel in concrete implementation, at first to constituting this neotype heat preservation bearing cavity, the alloy heat dissipation base member, the glass heat exchange tube, the electrical heating membrane, the heat transfer copper pipe is assembled, accomplish the interior heat transfer medium of glass heat exchange tube and fill the operation promptly in the assembling process, accomplish this novel equipment back, this novel after will assembling bears the cavity at first through the heat preservation and installs on flue gas condensing system's the base, then with heat transfer copper pipe both ends and flue gas condensing system's refrigeration compressor system intercommunication, with the electrical heating membrane, temperature sensor and control valve and flue gas condensing system's circuit system intercommunication, be connected the honeycomb duct both ends and the flue gas circuit of glass heat exchange tube, can accomplish the novel assembly of cost.

When accomplishing this novel assembly and operation, at first pass through the honeycomb duct of glass heat exchange tube with the flue gas, make flue gas and alloy heat dissipation base member carry out the heat exchange, when carrying out preliminary cooling operation, detect the flue gas temperature through temperature sensor, then carry low temperature refrigeration medium to in the heat exchange copper pipe and the circulation flow according to flue gas temperature flue gas condensing system's compressor system, realize that the heat exchange medium carries out the heat exchange and refrigerates alloy heat dissipation base member, then carry out the heat exchange refrigeration by alloy heat dissipation base member and glass heat exchange tube again, thereby reach the cryogenic purpose of flue gas, in addition when the glass heat exchange tube is to the flue gas refrigeration, the heat exchange medium in the accessible glass heat exchange tube carries out the energy storage, effectively reduce compressor system operation energy consumption.

When heating operation is needed, the alloy heat dissipation base body can be directly heated by the electric heating film and the electric heating wire in the heat preservation bearing cavity, so that the heating efficiency is effectively improved, and the structure of the refrigeration compressor system of the flue gas condensation system is simplified.

In addition, this is novel in the concrete implementation, the effectual realization in accessible heat preservation bearing chamber keeps warm the operation and improves the protective capacities that anti external force strikes, and accessible bearing spring carries out elastic absorption to the impact effort that factors such as external force strikes, air pressure fluctuation caused in addition simultaneously to very big improvement this novel stability and the reliability of operation, and from this can be very big improvement this novel service ability to adverse circumstances.

This novel one side integrates the degree height, and the commonality is good to have good bearing capacity and anti external force impact ability, thereby effectual stability, reliability and the environmental suitability when having improved this novel operation, on the other hand has good heat exchange ability and the operational capability that adjusts the temperature, and when improving heat exchange ability, has good heat preservation ability in addition, and can effectually reduce the heat loss when equipment moves, reduces equipment running cost.

Those skilled in the art should understand that the present invention is not limited by the above embodiments. The foregoing embodiments and description have been made only for the purpose of illustrating the principles of the invention. The present invention can be further modified and improved without departing from the spirit and scope of the present invention. Such changes and modifications are intended to be within the scope of the claimed invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a flue gas condenser is with high-efficient condensing chamber which characterized in that: the high-efficiency condensation chamber for the flue gas condenser comprises a heat-insulating bearing cavity, an alloy heat-radiating base body, a glass heat exchange tube, an electric heating film and a heat exchange copper tube, wherein the heat-insulating bearing cavity is of a closed cavity structure with a rectangular axial section, at least one water outlet is formed in the lower end face of the heat-insulating bearing cavity, the alloy heat-radiating base body is of a cylindrical structure, is embedded in the heat-insulating bearing cavity and is distributed coaxially with the heat-insulating bearing cavity, the side surface of the alloy heat-radiating base body is mutually and slidably connected with the side surface of the heat-insulating bearing cavity through at least one sliding chute, the lower end face of the alloy heat-radiating base body is mutually connected with the bottom of the heat-insulating bearing cavity through at least three bearing springs, the sliding chutes and the bearing springs are uniformly distributed around the axis of the heat-insulating bearing cavity and are distributed in parallel with the, alloy heat dissipation base member surface is through bearing groove and heat transfer copper pipe interconnect, and mutual coaxial distribution between alloy heat dissipation base member and the heat transfer copper pipe, heat transfer copper pipe both ends all are located the heat preservation and bear the weight of the chamber outside and establish the connection end, establish two at least location chambeies in the alloy heat dissipation base member, location chamber and alloy heat dissipation base member axis parallel distribution encircle alloy heat dissipation base member axis equipartition, and every location intracavity all establish a glass heat exchange tube and with glass heat exchange tube coaxial distribution.

2. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 1, wherein: the glass heat exchange tube comprises a liquid storage tube, a flow guide tube and a sealing end, wherein the liquid storage tube is of a U-shaped groove-shaped structure for the axial section, a flow guide opening is formed in the lower end face of the liquid storage tube, the upper end face of the liquid storage tube is connected with the sealing end and forms a closed cavity structure, the flow guide tube is one in all and is of a U-shaped tubular structure which is coaxially distributed with the liquid storage tube, 80% -95% of the effective length of the flow guide tube is located in the liquid storage tube, two ends of the flow guide tube are located outside the sealing end, the tube section of the flow guide tube located in the liquid storage tube is of a spiral structure, the two ends of the flow guide tube located outside the liquid storage tube are provided with connecting ends, the end faces of the two ends of the flow guide opening and the two ends of the flow guide tube.

3. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 2, wherein: at least one temperature sensor is arranged on the inner surface of the heat-preservation bearing cavity, and the temperature sensor is abutted against the outer surface of the alloy heat-dissipation base body.

4. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 2, wherein: at least one electric heating wire is arranged on the inner surface of the heat-preservation bearing cavity, and the electric heating wires are distributed in a spiral structure around the axis of the heat-preservation bearing cavity.

5. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 2, wherein: the cross section of the bearing groove on the outer surface of the alloy radiating base body is of any one of an arc structure, a rectangular structure and an isosceles trapezoid structure, the cross section structure of the heat exchange copper pipe in the bearing groove is the same as that of the bearing groove, and the heat exchange copper pipes 1/3-2/3 are partially embedded in the bearing groove.

6. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 1, wherein: the alloy heat dissipation substrate corresponding to the bottom of the bearing groove is provided with a plurality of through holes, the aperture of each through hole is not more than 2 mm, the distance between every two adjacent through holes is not less than 10 mm, and the axes of the through holes are perpendicular to and intersected with the axis of the alloy heat dissipation substrate.

7. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 1, wherein: the liquid storage pipe of the glass heat exchange pipe is internally provided with a liquid heat exchange medium, and the volume of the liquid heat exchange medium is not less than 80% of the volume of the liquid storage pipe.

8. The high-efficiency condensing chamber for the flue gas condenser as claimed in claim 1, wherein: control valves are arranged between the connecting ends and the connecting positions of the heat exchange copper pipe and the flow guide pipe and at the position of the flow guide pipe opening.