CN111121146A

CN111121146A - A regenerative heating device for clean heating

Info

Publication number: CN111121146A
Application number: CN201911425751.7A
Authority: CN
Inventors: 李效禹; 王选
Original assignee: China Academy of Building Research CABR
Current assignee: China Academy of Building Research CABR
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-05-08
Anticipated expiration: 2039-12-31
Also published as: CN111121146B

Abstract

The present invention is specifically a regenerative heating device for cleaning and heating. In the present invention, a heat storage module is provided, and a heat exchange tube group is arranged inside the heat storage module. In this way, when the temperature in the heat exchange tube is high, the The heat is used for heat storage, and after the indoor temperature becomes low, the heat storage energy can be used for heating, which improves the heating effect, ensures the balance of the indoor temperature, reduces the indoor temperature difference, and improves the comfort; the multi-section stepped medium inlet pipe of the present invention A heat exchange branch pipe is connected between each medium inlet pipe and each medium discharge pipe of the corresponding multi-section stepped medium discharge pipe, and each of the heat exchange branch pipes is connected in parallel, so that not only the heat exchange effect and the Heat transfer capacity, and the use of stepped tubes, through the change of diameter at the steps, can change the flow of the medium to prevent the adhesion of scales, etc. At the same time, the change of the medium flow rate can also improve the heat transfer effect and enhance the heat transfer capacity.

Description

Heat accumulating type heating device for cleaning and heating

Technical Field

The invention relates to the technical field of clean energy heating equipment, in particular to a heat accumulating type heating device for clean heating.

Background

The existing heating device generally utilizes heat exchange fins to exchange heat for heat supply of a heat supply medium so as to realize the heating effect. However, the heat exchanger fin cannot realize the function of heat storage, and in practical use, the heat exchanger fin often leads to the indoor temperature being too high in daytime and very low in night temperature, and even in night, the former night chamber in night is relatively hot, and then the latter night is along with the reduction of outside air temperature, the condition that the temperature is lower can appear indoors, leads to indoor temperature change great, makes the travelling comfort reduce, moreover, can not realize saving and controlling the heat. In addition, the current heat exchange fins or heat exchange tubes generally use water as a medium to realize heat exchange, the water often contains some minerals and scales, and the minerals and scales can adhere to the tubes for a long time to cause the problem of blockage, and the situation is particularly obvious in the heat exchange tube network because the inner diameter in the heat exchange tube network is generally small.

Accordingly, a regenerative heater for clean heating has been provided to solve the above-mentioned problems occurring in the related art.

Disclosure of Invention

The present invention is directed to a regenerative heater for clean heating, which solves the above problems.

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

a heat accumulating type heating device for cleaning and heating comprises a device body, wherein a supporting and protecting component is arranged at the top of the device body in a height-adjustable manner, heat dissipation holes are formed in two sides of the device body, a heat insulation sliding cover is arranged on the surface of each heat dissipation hole of the device body in a sliding and opening manner, a heat accumulating module is arranged in the device body, and a heat exchange tube set is arranged in the heat accumulating module and is characterized in that the heat exchange tube set comprises a medium inlet tube joint, a medium discharge tube joint, a multi-section stepped medium inlet tube, a multi-section stepped medium discharge tube and heat exchange branch tubes, wherein the medium inlet tube joint and the medium discharge tube joint are arranged on the device body in parallel and extend into the heat accumulating module, and the heat exchange branch tubes are connected between each section of medium inlet tube of the multi-section stepped medium inlet tube and each section of medium discharge tube of the multi-section stepped, and the heat exchange branch pipes are connected in parallel.

Further, preferably, each heat exchange branch pipe is also a stepped pipe, and the inner diameter of the stepped pipe at the middle position is the smallest, and the inner diameters of the two ends are the largest.

Further, preferably, the heat exchange branch pipes at least comprise an inlet large pipe, an inlet small pipe, a connecting pipe, a discharge small pipe and a discharge large pipe which are sequentially connected, the inlet large pipe and the inlet small pipe and the discharge large pipe are coaxially connected, and the inlet large pipe and the discharge large pipe are arranged in parallel and correspondingly.

Further, as preferred, the multiple sections of stepped medium inlet pipes include a first section of medium inlet pipe, a second section of medium inlet pipe, a third section of medium inlet pipe and a fourth section of medium inlet pipe which are connected in sequence and have sequentially reduced inner diameters, and chamfers are arranged at the stepped connection positions of the first section of medium inlet pipe, the second section of medium inlet pipe, the third section of medium inlet pipe and the fourth section of medium inlet pipe.

Further, as a preferred option, the multi-section stepped medium discharge pipe comprises a first section of medium discharge pipe, a second section of medium discharge pipe, a third section of medium discharge pipe and a fourth section of medium discharge pipe which are connected in sequence and have sequentially increased inner diameters, the first section of medium inlet pipe corresponds to the first section of medium discharge pipe in position, the second section of medium inlet pipe corresponds to the second section of medium discharge pipe in position, the third section of medium inlet pipe corresponds to the third section of medium discharge pipe in position, and the fourth section of medium inlet pipe corresponds to the fourth section of medium discharge pipe in position.

Further preferably, the heat storage module is a phase change heat storage module.

Further, as preferred, support protection component including supporting connecting rod and support frame, top one side of device main part is provided with the heating fan housing, the interior top both sides of device main part all run through and are provided with the support connecting rod, top one side fixed mounting who supports the connecting rod has the support frame, the side tip of device main part is provided with the spout, and heat preservation sliding closure sliding fit is on the spout, interior bottom one side fixed mounting of device main part has interior frame, the interior bottom of interior frame passes through the supporting shoe and connects the heat accumulation module, the equal fixed mounting in one side that the interior top of device main part is close to the support connecting rod has adjustment mechanism.

Preferably, a connecting pipe is fixedly installed on one side of the top end of the inner frame, the inner frame is communicated with the heating fan cover through the connecting pipe, and a heat sending fan is fixedly installed on one side of the inner wall of the heating fan cover.

Further, as preferred, the device main part's one side fixed mounting that the interior top corresponds adjustment mechanism has a fixing base, and the device main part passes through fixing base and adjustment mechanism fixed connection, the equal fixed mounting adapter sleeve of support connecting rod is corresponded to the bottom of support frame, and the internal diameter of adapter sleeve is slightly bigger than the external diameter of support connecting rod.

Further preferably, a screw rod is fixedly arranged at one side of the inside of the adjusting mechanism corresponding to the supporting connecting rod, and the supporting connecting rod is sleeved on one side of the outer wall of the screw rod, a thrust bearing is fixedly arranged on one side of the inner bottom of the adjusting mechanism corresponding to the screw rod, the adjusting mechanism is fixedly connected with the screw rod through a thrust bearing, a connecting block is fixedly arranged on one side of the inner wall of the supporting and supporting connecting rod, which corresponds to the screw rod, and a ball nut is fixedly arranged in the connecting block corresponding to one side of the screw rod, and the connecting block is meshed with the screw rod through the ball nut, a first gear is fixedly arranged on one side of the outer wall of the screw rod, a driving wheel is fixedly arranged on one side of the inner part of the adjusting mechanism close to the first gear, and a second gear is fixedly arranged on one side of the output shaft of the driving wheel, which corresponds to the first gear, and a driving groove cavity is arranged on the device body, which corresponds to the driving wheel.

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

1. according to the invention, the heat storage module is arranged, and the heat exchange tube group is arranged in the heat storage module, so that heat can be stored when the temperature in the heat exchange tube is higher, and the heat stored energy can be utilized for heating after the indoor temperature is lowered, so that the heating effect is improved, the balance of the indoor temperature is ensured, the indoor temperature difference is reduced, and the comfort is improved;

2. in the invention, each medium inlet pipe of the multi-section stepped medium inlet pipe and each medium outlet pipe of the corresponding multi-section stepped medium outlet pipe are connected with the heat exchange branch pipes in parallel, so that the heat exchange effect and the heat exchange capability can be ensured, the flow of the medium can be changed by utilizing the stepped pipe through the reducing at the step part, the adhesion of scale and the like can be prevented, meanwhile, the heat exchange effect can be improved and the heat exchange capability can be enhanced due to the change of the flow speed of the medium.

3. The invention can also realize drying of clothes and the like, and can also realize heat dissipation control by utilizing the heat-preservation sliding cover, thereby improving the using capability and the effect.

Drawings

Fig. 1 is a schematic view showing an external structure of a device body in a regenerative heating apparatus for clean heating;

fig. 2 is a schematic structural diagram of a heat exchange tube set and a heat storage module in a regenerative heating apparatus for clean heating;

fig. 3 is a schematic view showing an internal structure of a device body in a regenerative heating apparatus for clean heating;

fig. 4 is a schematic view showing an adjusting mechanism of a regenerative heater for clean heating.

Detailed Description

Referring to fig. 1 to 4, in an embodiment of the present invention, a heat accumulating type heating apparatus for clean heating includes an apparatus main body 1, a supporting and protecting component is disposed on a top of the apparatus main body, the height of the apparatus main body is adjustable, heat dissipating holes 6 are disposed on both sides of the apparatus main body, a heat insulating sliding cover 5 is disposed on a surface of the heat dissipating holes of the apparatus main body in a slidable and openable manner, a heat accumulating module 21 is disposed inside the apparatus main body, and a heat exchanging tube set is disposed inside the heat accumulating module 21, wherein the heat exchanging tube set includes a medium inlet tube joint 22, a medium outlet tube joint 23, a multi-section stepped medium inlet tube, a multi-section stepped medium outlet tube, and a heat exchanging branch tube, wherein the medium inlet tube joint 22 and the medium outlet tube joint 23 are disposed on the apparatus main body in parallel, and extend into the heat accumulating module 21, and each medium inlet tube of the multi-section stepped medium inlet tube and the heat exchange branch pipes are connected between the mass discharge pipes, and the heat exchange branch pipes are connected in parallel.

In this embodiment, each of the heat exchange branch pipes is also a stepped pipe, and the inner diameter of the middle position of the stepped pipe is the smallest, and the inner diameters of the two ends are the largest.

The heat exchange branch pipe at least comprises an inlet large pipe 32, an inlet small pipe 28, a connecting pipe 29, an outlet small pipe 30 and an outlet large pipe 27 which are sequentially connected, the inlet large pipe 32 and the inlet small pipe 28 and the outlet small pipe 30 and the outlet large pipe 27 are coaxially connected, and the inlet large pipe 32 and the outlet large pipe 27 are arranged in parallel and correspondingly. The multi-section stepped medium inlet pipe comprises a first section of medium inlet pipe 31, a second section of medium inlet pipe 24, a third section of medium inlet pipe 25 and a fourth section of medium inlet pipe 26 which are sequentially connected and have sequentially reduced inner diameters, and chamfers are arranged at the stepped connection positions of the first section of medium inlet pipe 31, the second section of medium inlet pipe 24, the third section of medium inlet pipe 25 and the fourth section of medium inlet pipe 26.

The multi-section stepped medium discharge pipe comprises a first section of medium discharge pipe, a second section of medium discharge pipe, a third section of medium discharge pipe and a fourth section of medium discharge pipe which are sequentially connected and have sequentially increased inner diameters, a first section of medium inlet pipe corresponds to the first section of medium discharge pipe in position, a second section of medium inlet pipe 25 corresponds to the second section of medium discharge pipe in position, a third section of medium inlet pipe corresponds to the third section of medium discharge pipe in position, and a fourth section of medium inlet pipe corresponds to the fourth section of medium discharge pipe in position.

In a preferred embodiment, the thermal storage module 21 is a phase change thermal storage module.

The supporting protection component comprises a supporting connecting rod 3 and a supporting frame 4, a heating fan housing 2 is arranged on one side of the top end of a main body 1 of the device, the supporting connecting rod 3 is arranged on two sides of the inner top end of the main body 1 of the device in a penetrating mode, the supporting frame 4 is fixedly arranged on one side of the top end of the supporting connecting rod 3, a sliding groove 7 is formed in the end portion of the side face of the main body 1 of the device, a heat-preservation sliding cover 5 is in sliding fit with the sliding groove 7, an inner frame 8 is fixedly arranged on one side of the inner bottom of the main body 1 of the device, the inner bottom of the inner frame 8 is connected with a heat storage module 21 through a supporting block 9.

The top end one side fixed mounting of inner tower 8 has connecting pipe 11, and inner tower 8 passes through connecting pipe 11 and heating fan housing 2 intercommunication, inner wall one side fixed mounting of heating fan housing 2 has send hot fan 12. The device main part 1 is characterized in that a fixing seat 13 is fixedly arranged on one side, corresponding to the adjusting mechanism 10, of the inner top end of the device main part 1, the device main part 1 is fixedly connected with the adjusting mechanism 10 through the fixing seat 13, a connecting sleeve 14 is fixedly arranged on the bottom end of the supporting frame 4 corresponding to the supporting connecting rod 3, and the inner diameter of the connecting sleeve 14 is slightly larger than the outer diameter of the supporting connecting rod 3.

A lead screw 15 is fixedly mounted in the adjusting mechanism 10 corresponding to one side of the supporting connecting rod 3, the supporting connecting rod 3 is sleeved on one side of the outer wall of the lead screw 15, a thrust bearing 16 is fixedly mounted at one side of the inner bottom of the adjusting mechanism 10 corresponding to the lead screw 15, the adjusting mechanism 10 is fixedly connected with the lead screw 15 through the thrust bearing 16, a connecting block 17 is fixedly mounted at one side of the inner wall of the supporting connecting rod 3 corresponding to the lead screw 15, a ball nut is fixedly mounted in one side of the connecting block 17 corresponding to the lead screw 15, the connecting block 17 is meshed with the lead screw 15 through the ball nut, a first gear 18 is fixedly mounted at one side of the outer wall of the lead screw 15, a driving wheel 19 is fixedly mounted at one side of the inner part of the adjusting mechanism 10 close to the first gear 18, and a second gear 20 is, a driving groove cavity is arranged on the device body corresponding to the driving wheel 19.

According to the invention, the heat storage module is arranged, and the heat exchange tube group is arranged in the heat storage module, so that heat can be stored when the temperature in the heat exchange tube is higher, and the heat stored energy can be utilized for heating after the indoor temperature is lowered, so that the heating effect is improved, the balance of the indoor temperature is ensured, the indoor temperature difference is reduced, and the comfort is improved; in the invention, each medium inlet pipe of the multi-section stepped medium inlet pipe and each medium outlet pipe of the corresponding multi-section stepped medium outlet pipe are connected with the heat exchange branch pipes in parallel, so that the heat exchange effect and the heat exchange capability can be ensured, the flow of the medium can be changed by utilizing the stepped pipe through the reducing at the step part, the adhesion of scale and the like can be prevented, meanwhile, the heat exchange effect can be improved and the heat exchange capability can be enhanced due to the change of the flow speed of the medium. The invention can also realize drying of clothes and the like, and can also realize heat dissipation control by utilizing the heat-preservation sliding cover, thereby improving the using capability and the effect.

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

Claims

1. A regenerative heating device for cleaning and heating, comprising a device main body (1), the top of the device main body is provided with a height-adjustable support protection component, and both sides of the device main body are provided with cooling holes (6), a thermal insulation sliding cover (5) is provided on the surface of the heat dissipation hole of the main body of the device that can be slidably opened and closed, and a heat storage module (21) is arranged inside the main body of the device, and the heat storage module (21) A heat exchange tube group is arranged inside, and it is characterized in that the heat exchange tube group includes a medium inlet pipe joint (22), a medium discharge pipe joint (23), a multi-section stepped medium inlet pipe, a multi-section stepped medium discharge pipe and an exchange pipe. A heat branch pipe, wherein the medium inlet pipe joint (22) and the medium discharge pipe joint (23) are arranged in parallel on the device main body, and extend into the heat storage module (21), and the multi-section steps The heat exchange branch pipes are connected between each section of the medium inlet pipe of the medium inlet pipe and each section of the corresponding medium discharge pipe of the multi-section stepped medium discharge pipe, and the heat exchange branch pipes are connected in parallel.

2 . The regenerative heating device for cleaning and heating according to claim 1 , wherein each of the heat exchange branch pipes is also a stepped pipe, and the inner diameter of the middle position of the stepped pipe is the smallest, 2 . The inner diameter at both ends is the largest.

3. A regenerative heating device for cleaning and heating according to claim 1, wherein the heat exchange branch pipe at least comprises an inlet large pipe (32), an inlet small pipe (28), a connection The pipe (29), the small discharge pipe (30), and the large discharge pipe (27) are all between the large inlet pipe (32) and the small pipe (28), and between the small pipe (30) and the large pipe (27). are coaxially connected, and the inlet large pipe (32) and the discharge large pipe (27) are arranged in parallel and correspondingly.

4. A regenerative heating device for cleaning and heating according to claim 1, wherein the multi-section stepped medium inlet pipe comprises a first section of medium inlet pipes ( 31), the second medium inlet pipe (24), the third medium inlet pipe (25) and the fourth medium inlet pipe (26), the first medium inlet pipe (31), the second medium inlet pipe ( 24), chamfers are provided at the junctions of the mutually stepped connection between the third section of medium inlet pipe (25) and the fourth section of medium inlet pipe (26).

5. A regenerative heating device for cleaning and heating according to claim 1, wherein the multi-section stepped medium discharge pipe comprises a first medium discharge pipe, a second medium discharge pipe, a second medium A medium discharge pipe, a third medium discharge pipe and a fourth medium discharge pipe, the first medium inlet pipe corresponds to the first medium discharge pipe, and the second medium inlet pipe (25) corresponds to the second medium inlet pipe (25). The positions of the medium discharge pipes correspond to the positions of the third medium inlet pipes and the third medium discharge pipes, and the fourth medium inlet pipes correspond to the fourth medium discharge pipes.

6. The regenerative heating device for cleaning and heating according to any one of claims 1-5, wherein the thermal storage module (21) is a phase-change thermal storage module.

7. A regenerative heating device for cleaning and heating according to any one of claims 1-5, characterized in that the support and protection assembly comprises a support connecting rod (3) and a support frame (4), A heating air hood (2) is provided on the top side of the device main body (1), and support connecting rods (3) are provided through both sides of the inner top end of the device main body (1). A support frame (4) is fixedly installed on the top side of the device body (1), a chute (7) is arranged on the side end of the device main body (1), and the thermal insulation sliding cover (5) is slidably fitted on the chute (7), so An inner frame (8) is fixedly installed on one side of the inner bottom of the device main body (1), and the inner bottom of the inner frame (8) is connected to the heat storage module (21) through a support block (9). The device main body (1) An adjustment mechanism (10) is fixedly installed on one side of the inner top end of the ) close to the support connecting rod (3).

8. A regenerative heating device for cleaning and heating according to claim 7, characterized in that a connecting pipe (11) is fixedly installed on the top side of the inner frame (8), and the inner frame ( 8) It is communicated with the heating hood (2) through the connecting pipe (11), and a heating fan (12) is fixedly installed on one side of the inner wall of the heating hood (2).

9 . The regenerative heating device for cleaning and heating according to claim 8 , wherein a fixing seat is fixedly installed on the inner top end of the device main body ( 1 ) corresponding to one side of the adjusting mechanism ( 10 ). 10 . (13), and the device main body (1) is fixedly connected with the adjusting mechanism (10) through the fixing seat (13), and the bottom end of the supporting frame (4) corresponding to the supporting connecting rod (3) is fixedly installed with the connecting sleeve (14) , and the inner diameter of the connecting sleeve (14) is slightly larger than the outer diameter of the supporting connecting rod (3).

10. A regenerative heating device for cleaning and heating according to claim 9, characterized in that a lead screw is fixedly installed inside the adjusting mechanism (10) corresponding to one side of the supporting connecting rod (3) (15), and the support connecting rod (3) is sleeved on one side of the outer wall of the lead screw (15), and a thrust bearing ( 16), and the adjusting mechanism (10) is fixedly connected with the lead screw (15) through the thrust bearing (16), and a connecting block is fixedly installed on the inner wall of the supporting and supporting connecting rod (3) corresponding to one side of the lead screw (15). (17), and the inner side of the connecting block (17) corresponding to the side of the lead screw (15) is fixedly installed with a ball nut, and the connecting block (17) is engaged with the lead screw (15) through the ball nut, and the lead screw ( 15) A first gear (18) is fixedly installed on one side of the outer wall, and a drive wheel (19) is fixedly installed on the side of the inside of the adjusting mechanism (10) close to the first gear (18), and the output of the drive wheel A second gear (20) is fixedly mounted on one side of the shaft corresponding to the first gear (18), and a driving groove cavity is provided on the device body at a position corresponding to the driving wheel (19).