CN204392613U - A kind of cooling of induction cooker clock mechanism and hot water utilization system - Google Patents
A kind of cooling of induction cooker clock mechanism and hot water utilization system Download PDFInfo
- Publication number
- CN204392613U CN204392613U CN201520078349.7U CN201520078349U CN204392613U CN 204392613 U CN204392613 U CN 204392613U CN 201520078349 U CN201520078349 U CN 201520078349U CN 204392613 U CN204392613 U CN 204392613U
- Authority
- CN
- China
- Prior art keywords
- pipeline
- operated valve
- electromagnetically operated
- cooler bin
- water
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Cookers (AREA)
Abstract
The utility model belongs to electromagnetic heating technique field, is specifically related to a kind of cooling and hot water utilization system of induction cooker clock mechanism.The utility model provides a kind of like this cooling of induction cooker clock mechanism and hot water utilization system includes three head tube roads, four-head pipeline, aluminum water block, water tank grid, core module group I, core module group II, core module group III, nature cooler bin I, nature cooler bin II, nature cooler bin III, nature cooler bin IV, nature cooler bin V, pipeline I, pipeline II, pipeline III, pipeline IV, pipeline V, pipeline VI, pipeline VII, pipeline VIII, pipeline Ⅸ, pipeline Ⅹ, electromagnetically operated valve I, electromagnetically operated valve II, electromagnetically operated valve III, electromagnetically operated valve IV, electromagnetically operated valve V, electromagnetically operated valve VI, electromagnetically operated valve VII, electromagnetically operated valve VIII, electromagnetically operated valve Ⅸ, electromagnetically operated valve Ⅹ, hot water reservoir, temp probe I, temp probe II, temp probe III, tank hot water manages, water-level probe I, water-level probe II, water pump, evacuated tube, water filter, guidance panel.
Description
Technical field
The utility model belongs to electromagnetic heating technique field, is specifically related to a kind of cooling and hot water utilization system of induction cooker clock mechanism.
Background technology
The main composition part of electromagnetic oven is movement, and the movement of electromagnetic oven inside is made up of several integrated high power module.Module can produce heat in the course of the work, so the bottom surface of module studs with metallic heat radiating plate.And the heating panel depending module self alone is not enough to heat radiation, so module can be arranged on above large-scale Aluminium Radiator.Aluminium Radiator is provided with high-power blower to its radiating and cooling.Thus the heat radiation realized module, allow module work in the temperature of regulation.The wind of blower fan is blown over from the bottom of Aluminium Radiator, temperature is taken out of and becomes hot blast, and hot blast can use ambient temperature to raise, and the noise in high-power blower work is also inevitable.These factors all can allow the operational environment of user be deteriorated.
Electromagnetic oven of the prior art easily produces noise, and the heat distributed can affect environment, and the energy can not reuse, waste resource.
Utility model content
(1) technical problem that will solve
The utility model producing noise to overcome, affecting environment, the energy can not reuse, the shortcoming of the wasting of resources, and the technical problems to be solved in the utility model is to provide a kind of noiselessness, environmental protection, the energy can reuse, the cooling of induction cooker clock mechanism that economizes on resources and hot water utilization system.
(2) technical scheme
In order to solve the problems of the technologies described above, the utility model provides a kind of like this cooling of induction cooker clock mechanism and hot water utilization system includes three head tube roads, four-head pipeline, aluminum water block, water tank grid, core module group I, core module group II, core module group III, nature cooler bin I, nature cooler bin II, nature cooler bin III, nature cooler bin IV, nature cooler bin V, pipeline I, pipeline II, pipeline III, pipeline IV, pipeline V, pipeline VI, pipeline VII, pipeline VIII, pipeline Ⅸ, pipeline Ⅹ, electromagnetically operated valve I, electromagnetically operated valve II, electromagnetically operated valve III, electromagnetically operated valve IV, electromagnetically operated valve V, electromagnetically operated valve VI, electromagnetically operated valve VII, electromagnetically operated valve VIII, electromagnetically operated valve Ⅸ, electromagnetically operated valve Ⅹ, hot water reservoir, temp probe I, temp probe II, temp probe III, tank hot water manages, water-level probe I, water-level probe II, water pump, evacuated tube, water filter, guidance panel,
One of three described head tube roads is connected with described aluminum water block, described water tank grid is installed inside described aluminum water block, described core module group I, described core module group II and described core module group III are installed above described aluminum water block, and are in same level, the side of described aluminum water block is provided with described temp probe II, and the upside of described aluminum water block is provided with described temp probe I, one of three described head tube roads is connected with described electromagnetically operated valve VI, one of three described head tube roads is connected with described electromagnetically operated valve VII, described electromagnetically operated valve VII and described electromagnetically operated valve Ⅸ, described electromagnetically operated valve VIII is connected by described pipeline Ⅹ, described electromagnetically operated valve VIII is connected with described water filter, described electromagnetically operated valve Ⅸ is connected by described pipeline Ⅸ with described electromagnetically operated valve V and described natural cooler bin V with described electromagnetically operated valve Ⅹ, described electromagnetically operated valve Ⅹ is connected with described evacuated tube, described water-level probe II is arranged in described evacuated tube, described water pump is arranged on described pipeline Ⅸ, described temp probe III is arranged on described pipeline Ⅸ, described natural cooler bin IV is connected by described pipeline VIII with described natural cooler bin V, described natural cooler bin III is connected by described pipeline VI with described natural cooler bin IV, described natural cooler bin II is connected by described pipeline VII with described natural cooler bin III, described natural cooler bin I is connected by described pipeline V with described natural cooler bin II, described natural cooler bin I is connected by described four-head pipeline with described electromagnetically operated valve I and described electromagnetically operated valve II with described aluminum water block, described electromagnetically operated valve II is connected by described pipeline I with described hot water reservoir, described tank hot water's pipe is equipped with described water-level probe I, described hot water reservoir is connected with described tank hot water's pipe, described hot water reservoir and described pipeline II, described pipeline III, described pipeline IV connects, described pipeline II is equipped with described electromagnetically operated valve III, described pipeline IV is equipped with described electromagnetically operated valve IV, described temp probe is connected with control system with described water-level probe, and described guidance panel is provided with button.
Preferably, the material of described natural cooler bin is metal.
Preferably, the model of described water pump is ASP.
Operation principle: realized by the radiating mode changing induction cooker clock mechanism module, the module of induction cooker clock mechanism is arranged on aluminum water tank surface, because the conductive coefficient of aluminium is high, there is entery and delivery port aluminum water tank side, have grid inside aluminum water tank, as guide functions, the cross section of grid is equal with the cross section of water inlet, ensure that the water inside aluminum water tank is better circulated, can not inside produce " stagnant water ".The temperature conduction that the module of induction cooker clock mechanism produces is to aluminum water tank, and the temperature that the water of normal temperature can absorb aluminum water tank is the module temperature absorbing induction cooker clock mechanism, thus reaches radiating effect.The water of delivery port, because absorbing the temperature of aluminum water tank, becomes the hot water needed for kitchen, stores just to obtain well to recycle effect.
(3) beneficial effect
The utility model avoids and because of electromagnetic oven work, kitchen temperature is raised, increase the problem of kitchen noise pollution, do not need to use high-power blower, so also save electric energy used in high-power blower work, the heat that the module of induction cooker clock mechanism produces obtains recycling, energy savings, and reduce use cost, the set-up function of cleaning and hot water temperature automatically can also be carried out.
Accompanying drawing explanation
Fig. 1 is the structural representation of the module installation diagram of aluminum water tank cutaway view of the present utility model and induction cooker clock mechanism.
Fig. 2 is guidance panel of the present utility model.
Fig. 3 is of the present utility model is the cooling of induction cooker clock mechanism and the structural map of hot water utilization system.
Being labeled as in accompanying drawing: 1-tri-head tube road, 2-four-head pipeline, 3-aluminum water block, 4-water tank grid, 5-core module group I, 6-core module group II, 7-core module group III, 8-nature cooler bin I, 81-nature cooler bin II, 82-nature cooler bin III, 83-nature cooler bin IV, 84-nature cooler bin V, 9-pipeline I, 91-pipeline II, 92-pipeline III, 93-pipeline IV, 94-pipeline V, 95-pipeline VI, 96-pipeline VII, 97-pipeline VIII, 98-pipeline Ⅸ, 99-pipeline Ⅹ, 10-electromagnetically operated valve I, 101-electromagnetically operated valve II, 102-electromagnetically operated valve III, 103-electromagnetically operated valve IV, 104-electromagnetically operated valve V, 105-electromagnetically operated valve VI, 106-electromagnetically operated valve VII, 107-electromagnetically operated valve VIII, 108-electromagnetically operated valve Ⅸ, 109-electromagnetically operated valve Ⅹ, 11-hot water reservoir, 12-temp probe I, 121-temp probe II, 122-temp probe III, 13-tank hot water manages, 14-water-level probe I, 141-water-level probe II, 15-water pump, 16-evacuated tube, 17-water filter, 18-guidance panel.
Embodiment
Below in conjunction with drawings and Examples, the utility model is further described.
embodiment 1
As Figure 1-3, a kind of cooling of induction cooker clock mechanism and hot water utilization system include three head tube roads 1, four-head pipeline 2, aluminum water block 3, water tank grid 4, core module group I 5, core module group II 6, core module group III 7, nature cooler bin I 8, nature cooler bin II 81, nature cooler bin III 82, nature cooler bin IV 83, nature cooler bin V 84, pipeline I 9, pipeline II 91, pipeline III 92, pipeline IV 93, pipeline V 94, pipeline VI 95, pipeline VII 96, pipeline VIII 97, pipeline Ⅸ 98, pipeline Ⅹ 99, electromagnetically operated valve I 10, electromagnetically operated valve II 101, electromagnetically operated valve III 102, electromagnetically operated valve IV 103, electromagnetically operated valve V 104, electromagnetically operated valve VI 105, electromagnetically operated valve VII 106, electromagnetically operated valve VIII 107, electromagnetically operated valve Ⅸ 108, electromagnetically operated valve Ⅹ 109, hot water reservoir 11, temp probe I 12, temp probe II 121, temp probe III 122, tank hot water's pipe 13, water-level probe I 14, water-level probe II 141, water pump 15, evacuated tube 16, water filter 17, guidance panel 18,
One of three described head tube roads 1 is connected with described aluminum water block 3, inside described aluminum water block 3, described water tank grid 4 is installed, described aluminum water block 3 is provided with described core module group I 5, described core module group II 6 and described core module group III 7 above, and is in same level, the side of described aluminum water block 3 is provided with described temp probe II 121, and the upside of described aluminum water block 3 is provided with described temp probe I 12, one of three described head tube roads 1 is connected with described electromagnetically operated valve VI 105, one of three described head tube roads 1 is connected with described electromagnetically operated valve VII 106, described electromagnetically operated valve VII 106 and described electromagnetically operated valve Ⅸ 108, described electromagnetically operated valve VIII 107 is connected by described pipeline Ⅹ 99, described electromagnetically operated valve VIII 107 is connected with described water filter 17, described electromagnetically operated valve Ⅸ 108 is connected by described pipeline Ⅸ 98 with described electromagnetically operated valve V 104 and described natural cooler bin V 84 with described electromagnetically operated valve Ⅹ 109, described electromagnetically operated valve Ⅹ 109 is connected with described evacuated tube 16, described water-level probe II 141 is arranged in described evacuated tube 16, described water pump 15 is arranged on described pipeline Ⅸ 98, described temp probe III 122 is arranged on described pipeline Ⅸ 98, described natural cooler bin IV 83 is connected by described pipeline VIII 97 with described natural cooler bin V 84, described natural cooler bin III 82 is connected by described pipeline VI 95 with described natural cooler bin IV 83, described natural cooler bin II 81 is connected by described pipeline VII 96 with described natural cooler bin III 82, described natural cooler bin I 8 is connected by described pipeline V 94 with described natural cooler bin II 81, described natural cooler bin I 8 is connected by described four-head pipeline 2 with described electromagnetically operated valve I 10 and described electromagnetically operated valve II 101 with described aluminum water block 3, described electromagnetically operated valve II 101 is connected by described pipeline I 9 with described hot water reservoir 11, described tank hot water's pipe 13 is equipped with described water-level probe I 14, described hot water reservoir 11 is connected with described tank hot water's pipe 13, described hot water reservoir 11 and described pipeline II 91, described pipeline III 92, described pipeline IV 93 connects, described pipeline II 91 is equipped with described electromagnetically operated valve III 102, described pipeline IV 93 is equipped with described electromagnetically operated valve IV 103, described temp probe is connected with control system with described water-level probe, and described guidance panel 18 is provided with button.
embodiment 2
As Figure 1-3, a kind of cooling of induction cooker clock mechanism and hot water utilization system include three head tube roads 1, four-head pipeline 2, aluminum water block 3, water tank grid 4, core module group I 5, core module group II 6, core module group III 7, nature cooler bin I 8, nature cooler bin II 81, nature cooler bin III 82, nature cooler bin IV 83, nature cooler bin V 84, pipeline I 9, pipeline II 91, pipeline III 92, pipeline IV 93, pipeline V 94, pipeline VI 95, pipeline VII 96, pipeline VIII 97, pipeline Ⅸ 98, pipeline Ⅹ 99, electromagnetically operated valve I 10, electromagnetically operated valve II 101, electromagnetically operated valve III 102, electromagnetically operated valve IV 103, electromagnetically operated valve V 104, electromagnetically operated valve VI 105, electromagnetically operated valve VII 106, electromagnetically operated valve VIII 107, electromagnetically operated valve Ⅸ 108, electromagnetically operated valve Ⅹ 109, hot water reservoir 11, temp probe I 12, temp probe II 121, temp probe III 122, tank hot water's pipe 13, water-level probe I 14, water-level probe II 141, water pump 15, evacuated tube 16, water filter 17, guidance panel 18,
One of three described head tube roads 1 is connected with described aluminum water block 3, inside described aluminum water block 3, described water tank grid 4 is installed, described aluminum water block 3 is provided with described core module group I 5, described core module group II 6 and described core module group III 7 above, and is in same level, the side of described aluminum water block 3 is provided with described temp probe II 121, and the upside of described aluminum water block 3 is provided with described temp probe I 12, one of three described head tube roads 1 is connected with described electromagnetically operated valve VI 105, one of three described head tube roads 1 is connected with described electromagnetically operated valve VII 106, described electromagnetically operated valve VII 106 and described electromagnetically operated valve Ⅸ 108, described electromagnetically operated valve VIII 107 is connected by described pipeline Ⅹ 99, described electromagnetically operated valve VIII 107 is connected with described water filter 17, described electromagnetically operated valve Ⅸ 108 is connected by described pipeline Ⅸ 98 with described electromagnetically operated valve V 104 and described natural cooler bin V 84 with described electromagnetically operated valve Ⅹ 109, described electromagnetically operated valve Ⅹ 109 is connected with described evacuated tube 16, described water-level probe II 141 is arranged in described evacuated tube 16, described water pump 15 is arranged on described pipeline Ⅸ 98, described temp probe III 122 is arranged on described pipeline Ⅸ 98, described natural cooler bin IV 83 is connected by described pipeline VIII 97 with described natural cooler bin V 84, described natural cooler bin III 82 is connected by described pipeline VI 95 with described natural cooler bin IV 83, described natural cooler bin II 81 is connected by described pipeline VII 96 with described natural cooler bin III 82, described natural cooler bin I 8 is connected by described pipeline V 94 with described natural cooler bin II 81, described natural cooler bin I 8 is connected by described four-head pipeline 2 with described electromagnetically operated valve I 10 and described electromagnetically operated valve II 101 with described aluminum water block 3, described electromagnetically operated valve II 101 is connected by described pipeline I 9 with described hot water reservoir 11, described tank hot water's pipe 13 is equipped with described water-level probe I 14, described hot water reservoir 11 is connected with described tank hot water's pipe 13, described hot water reservoir 11 and described pipeline II 91, described pipeline III 92, described pipeline IV 93 connects, described pipeline II 91 is equipped with described electromagnetically operated valve III 102, described pipeline IV 93 is equipped with described electromagnetically operated valve IV 103, described temp probe is connected with control system with described water-level probe, and described guidance panel 18 is provided with button.
The material of described natural cooler bin is metal.
embodiment 3
As Figure 1-3, a kind of cooling of induction cooker clock mechanism and hot water utilization system include three head tube roads 1, four-head pipeline 2, aluminum water block 3, water tank grid 4, core module group I 5, core module group II 6, core module group III 7, nature cooler bin I 8, nature cooler bin II 81, nature cooler bin III 82, nature cooler bin IV 83, nature cooler bin V 84, pipeline I 9, pipeline II 91, pipeline III 92, pipeline IV 93, pipeline V 94, pipeline VI 95, pipeline VII 96, pipeline VIII 97, pipeline Ⅸ 98, pipeline Ⅹ 99, electromagnetically operated valve I 10, electromagnetically operated valve II 101, electromagnetically operated valve III 102, electromagnetically operated valve IV 103, electromagnetically operated valve V 104, electromagnetically operated valve VI 105, electromagnetically operated valve VII 106, electromagnetically operated valve VIII 107, electromagnetically operated valve Ⅸ 108, electromagnetically operated valve Ⅹ 109, hot water reservoir 11, temp probe I 12, temp probe II 121, temp probe III 122, tank hot water's pipe 13, water-level probe I 14, water-level probe II 141, water pump 15, evacuated tube 16, water filter 17, guidance panel 18,
One of three described head tube roads 1 is connected with described aluminum water block 3, inside described aluminum water block 3, described water tank grid 4 is installed, described aluminum water block 3 is provided with described core module group I 5, described core module group II 6 and described core module group III 7 above, and is in same level, the side of described aluminum water block 3 is provided with described temp probe II 121, and the upside of described aluminum water block 3 is provided with described temp probe I 12, one of three described head tube roads 1 is connected with described electromagnetically operated valve VI 105, one of three described head tube roads 1 is connected with described electromagnetically operated valve VII 106, described electromagnetically operated valve VII 106 and described electromagnetically operated valve Ⅸ 108, described electromagnetically operated valve VIII 107 is connected by described pipeline Ⅹ 99, described electromagnetically operated valve VIII 107 is connected with described water filter 17, described electromagnetically operated valve Ⅸ 108 is connected by described pipeline Ⅸ 98 with described electromagnetically operated valve V 104 and described natural cooler bin V 84 with described electromagnetically operated valve Ⅹ 109, described electromagnetically operated valve Ⅹ 109 is connected with described evacuated tube 16, described water-level probe II 141 is arranged in described evacuated tube 16, described water pump 15 is arranged on described pipeline Ⅸ 98, described temp probe III 122 is arranged on described pipeline Ⅸ 98, described natural cooler bin IV 83 is connected by described pipeline VIII 97 with described natural cooler bin V 84, described natural cooler bin III 82 is connected by described pipeline VI 95 with described natural cooler bin IV 83, described natural cooler bin II 81 is connected by described pipeline VII 96 with described natural cooler bin III 82, described natural cooler bin I 8 is connected by described pipeline V 94 with described natural cooler bin II 81, described natural cooler bin I 8 is connected by described four-head pipeline 2 with described electromagnetically operated valve I 10 and described electromagnetically operated valve II 101 with described aluminum water block 3, described electromagnetically operated valve II 101 is connected by described pipeline I 9 with described hot water reservoir 11, described tank hot water's pipe 13 is equipped with described water-level probe I 14, described hot water reservoir 11 is connected with described tank hot water's pipe 13, described hot water reservoir 11 and described pipeline II 91, described pipeline III 92, described pipeline IV 93 connects, described pipeline II 91 is equipped with described electromagnetically operated valve III 102, described pipeline IV 93 is equipped with described electromagnetically operated valve IV 103, described temp probe is connected with control system with described water-level probe, and described guidance panel 18 is provided with button.
The material of described natural cooler bin is metal.The model of described water pump 15 is ASP.
embodiment 4
As Figure 1-3, a kind of cooling of induction cooker clock mechanism and hot water utilization system include three head tube roads 1, four-head pipeline 2, aluminum water block 3, water tank grid 4, core module group I 5, core module group II 6, core module group III 7, nature cooler bin I 8, nature cooler bin II 81, nature cooler bin III 82, nature cooler bin IV 83, nature cooler bin V 84, pipeline I 9, pipeline II 91, pipeline III 92, pipeline IV 93, pipeline V 94, pipeline VI 95, pipeline VII 96, pipeline VIII 97, pipeline Ⅸ 98, pipeline Ⅹ 99, electromagnetically operated valve I 10, electromagnetically operated valve II 101, electromagnetically operated valve III 102, electromagnetically operated valve IV 103, electromagnetically operated valve V 104, electromagnetically operated valve VI 105, electromagnetically operated valve VII 106, electromagnetically operated valve VIII 107, electromagnetically operated valve Ⅸ 108, electromagnetically operated valve Ⅹ 109, hot water reservoir 11, temp probe I 12, temp probe II 121, temp probe III 122, tank hot water's pipe 13, water-level probe I 14, water-level probe II 141, water pump 15, evacuated tube 16, water filter 17, guidance panel 18,
One of three described head tube roads 1 is connected with described aluminum water block 3, inside described aluminum water block 3, described water tank grid 4 is installed, described aluminum water block 3 is provided with described core module group I 5, described core module group II 6 and described core module group III 7 above, and is in same level, the side of described aluminum water block 3 is provided with described temp probe II 121, and the upside of described aluminum water block 3 is provided with described temp probe I 12, one of three described head tube roads 1 is connected with described electromagnetically operated valve VI 105, one of three described head tube roads 1 is connected with described electromagnetically operated valve VII 106, described electromagnetically operated valve VII 106 and described electromagnetically operated valve Ⅸ 108, described electromagnetically operated valve VIII 107 is connected by described pipeline Ⅹ 99, described electromagnetically operated valve VIII 107 is connected with described water filter 17, described electromagnetically operated valve Ⅸ 108 is connected by described pipeline Ⅸ 98 with described electromagnetically operated valve V 104 and described natural cooler bin V 84 with described electromagnetically operated valve Ⅹ 109, described electromagnetically operated valve Ⅹ 109 is connected with described evacuated tube 16, described water-level probe II 141 is arranged in described evacuated tube 16, described water pump 15 is arranged on described pipeline Ⅸ 98, described temp probe III 122 is arranged on described pipeline Ⅸ 98, described natural cooler bin IV 83 is connected by described pipeline VIII 97 with described natural cooler bin V 84, described natural cooler bin III 82 is connected by described pipeline VI 95 with described natural cooler bin IV 83, described natural cooler bin II 81 is connected by described pipeline VII 96 with described natural cooler bin III 82, described natural cooler bin I 8 is connected by described pipeline V 94 with described natural cooler bin II 81, described natural cooler bin I 8 is connected by described four-head pipeline 2 with described electromagnetically operated valve I 10 and described electromagnetically operated valve II 101 with described aluminum water block 3, described electromagnetically operated valve II 101 is connected by described pipeline I 9 with described hot water reservoir 11, described tank hot water's pipe 13 is equipped with described water-level probe I 14, described hot water reservoir 11 is connected with described tank hot water's pipe 13, described hot water reservoir 11 and described pipeline II 91, described pipeline III 92, described pipeline IV 93 connects, described pipeline II 91 is equipped with described electromagnetically operated valve III 102, described pipeline IV 93 is equipped with described electromagnetically operated valve IV 103, described temp probe is connected with control system with described water-level probe, and described guidance panel 18 is provided with button.
Operation principle: realized by the radiating mode changing induction cooker clock mechanism module, the module of induction cooker clock mechanism is arranged on aluminum water tank surface, because the conductive coefficient of aluminium is high, there is entery and delivery port aluminum water tank side, have grid inside aluminum water tank, as guide functions, the cross section of grid is equal with the cross section of water inlet, ensure that the water inside aluminum water tank is better circulated, can not inside produce " stagnant water ".The temperature conduction that the module of induction cooker clock mechanism produces is to aluminum water tank, and the temperature that the water of normal temperature can absorb aluminum water tank is the module temperature absorbing induction cooker clock mechanism, thus reaches radiating effect.The water of delivery port, because absorbing the temperature of aluminum water tank, becomes the hot water needed for kitchen, stores just to obtain well to recycle effect.
The above embodiment only have expressed preferred implementation of the present utility model, and it describes comparatively concrete and detailed, but therefore can not be interpreted as the restriction to the utility model the scope of the claims.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, improvement and substitute, these all belong to protection range of the present utility model.Therefore, the protection range of the utility model patent should be as the criterion with claims.
Claims (3)
1. the cooling of induction cooker clock mechanism and a hot water utilization system, is characterized in that, include three head tube roads (1), four-head pipeline (2), aluminum water block (3), water tank grid (4), core module group I (5), core module group II (6), core module group III (7), nature cooler bin I (8), nature cooler bin II (81), nature cooler bin III (82), nature cooler bin IV (83), nature cooler bin V (84), pipeline I (9), pipeline II (91), pipeline III (92), pipeline IV (93), pipeline V (94), pipeline VI (95), pipeline VII (96), pipeline VIII (97), pipeline Ⅸ (98), pipeline Ⅹ (99), electromagnetically operated valve I (10), electromagnetically operated valve II (101), electromagnetically operated valve III (102), electromagnetically operated valve IV (103), electromagnetically operated valve V (104), electromagnetically operated valve VI (105), electromagnetically operated valve VII (106), electromagnetically operated valve VIII (107), electromagnetically operated valve Ⅸ (108), electromagnetically operated valve Ⅹ (109), hot water reservoir (11), temp probe I (12), temp probe II (121), temp probe III (122), tank hot water manages (13), water-level probe I (14), water-level probe II (141), water pump (15), evacuated tube (16), water filter (17), guidance panel (18),
One of three described head tube roads (1) is connected with described aluminum water block (3), described aluminum water block (3) the inside is provided with described water tank grid (4), described aluminum water block (3) is provided with described core module group I (5), described core module group II (6) and described core module group III (7) above, and is in same level; The side of described aluminum water block (3) is provided with described temp probe II (121), and the upside of described aluminum water block (3) is provided with described temp probe I (12); one of three described head tube roads (1) is connected with described electromagnetically operated valve VI (105), one of three described head tube roads (1) is connected with described electromagnetically operated valve VII (106), described electromagnetically operated valve VII (106) and described electromagnetically operated valve Ⅸ (108), described electromagnetically operated valve VIII (107) is connected by described pipeline Ⅹ (99), described electromagnetically operated valve VIII (107) is connected with described water filter (17), described electromagnetically operated valve Ⅸ (108) is connected by described pipeline Ⅸ (98) with described electromagnetically operated valve V (104) and described natural cooler bin V (84) with described electromagnetically operated valve Ⅹ (109), described electromagnetically operated valve Ⅹ (109) is connected with described evacuated tube (16), described water-level probe II (141) is arranged in described evacuated tube (16), described water pump (15) is arranged on described pipeline Ⅸ (98), described temp probe III (122) is arranged on described pipeline Ⅸ (98), described natural cooler bin IV (83) is connected by described pipeline VIII (97) with described natural cooler bin V (84), described natural cooler bin III (82) is connected by described pipeline VI (95) with described natural cooler bin IV (83), described natural cooler bin II (81) is connected by described pipeline VII (96) with described natural cooler bin III (82), described natural cooler bin I (8) is connected by described pipeline V (94) with described natural cooler bin II (81), described natural cooler bin I (8) is connected by described four-head pipeline (2) with described electromagnetically operated valve I (10) and described electromagnetically operated valve II (101) with described aluminum water block (3), described electromagnetically operated valve II (101) is connected by described pipeline I (9) with described hot water reservoir (11), described tank hot water's pipe (13) is equipped with described water-level probe I (14), described hot water reservoir (11) is connected with described tank hot water pipe (13), described hot water reservoir (11) and described pipeline II (91), described pipeline III (92), described pipeline IV (93) connects, described pipeline II (91) is equipped with described electromagnetically operated valve III (102), described pipeline IV (93) is equipped with described electromagnetically operated valve IV (103), described temp probe is connected with control system with described water-level probe, and described guidance panel (18) is provided with button.
2. the cooling of a kind of induction cooker clock mechanism according to claim 1 and hot water utilization system, it is characterized in that, the material of described natural cooler bin is metal.
3. the cooling of a kind of induction cooker clock mechanism according to claim 1 and hot water utilization system, it is characterized in that, the model of described water pump (15) is ASP.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520078349.7U CN204392613U (en) | 2015-02-04 | 2015-02-04 | A kind of cooling of induction cooker clock mechanism and hot water utilization system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520078349.7U CN204392613U (en) | 2015-02-04 | 2015-02-04 | A kind of cooling of induction cooker clock mechanism and hot water utilization system |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN204392613U true CN204392613U (en) | 2015-06-10 |
Family
ID=53365290
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201520078349.7U Expired - Fee Related CN204392613U (en) | 2015-02-04 | 2015-02-04 | A kind of cooling of induction cooker clock mechanism and hot water utilization system |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN204392613U (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113531642A (en) * | 2021-07-28 | 2021-10-22 | 江西摩力斯科技股份有限公司 | Can assemble high-power frequency conversion electromagnetism heating equipment that can make up |
-
2015
- 2015-02-04 CN CN201520078349.7U patent/CN204392613U/en not_active Expired - Fee Related
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113531642A (en) * | 2021-07-28 | 2021-10-22 | 江西摩力斯科技股份有限公司 | Can assemble high-power frequency conversion electromagnetism heating equipment that can make up |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN202757347U (en) | Solar-assisted heat pump system | |
| CN206179630U (en) | Transformer box convenient to temperature regulation | |
| CN201874657U (en) | Radiator of gas generator set | |
| CN204392613U (en) | A kind of cooling of induction cooker clock mechanism and hot water utilization system | |
| CN206533672U (en) | A kind of double water tank ups power | |
| CN205753598U (en) | A kind of emperature-lowering energy-saving system for building | |
| CN204830566U (en) | Energy -conserving refrigeration heating system | |
| CN206574401U (en) | A kind of solar energy animation artistic advertisement board | |
| CN207161275U (en) | A kind of wind-driven generator water-cooling control system | |
| CN203309982U (en) | Auxiliary and compensation device of solar optothermal and photoelectricity combined heating system | |
| CN101915437A (en) | Hydro-thermal recovery system in shower | |
| CN210320616U (en) | Water heater equipment utilizing waste heat of 10KW fuel cell | |
| CN204478619U (en) | A kind of novel by solar powered domestic portable refrigerator | |
| CN203432035U (en) | Energy-saving air conditioner | |
| CN215864036U (en) | Novel bathing magnetic heater | |
| CN204441030U (en) | A kind of low-temperature protection structure of high overload distribution transformer | |
| CN201779769U (en) | Shower reclaimed water heat recovery system | |
| CN108194971A (en) | A kind of radiation panel device | |
| CN104654598A (en) | Novel solar water heating system assisted by air source heat pump | |
| CN204190224U (en) | For the secondary ventilation device of substation transformer room | |
| CN202286914U (en) | Novel energy-saving air-conditioning desk | |
| CN209355352U (en) | Air-cooling apparatus for heat accumulating type electromagnetism heating equipment | |
| CN219083246U (en) | Intelligent solar hot water heating machine | |
| CN203010744U (en) | Low-carbon environment-friendly house heating system | |
| CN209042771U (en) | A kind of solar heater |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150610 Termination date: 20180204 |
|
| CF01 | Termination of patent right due to non-payment of annual fee |