Disclosure of Invention
The invention aims to provide an energy-saving electric boiler which is reasonable and novel in structure and can continuously keep warm by utilizing sand and heat generated by the operation of the boiler.
Technical scheme
In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides an energy-conserving electric boiler, includes boiler plant, boiler plant's right side is including taking out gas head, air duct, heating jar, heating ring and lead temperature metal needle, the one end of taking out gas head is pegged graft with the upper portion of boiler plant right wall, the one end of air duct is pegged graft with the upper portion on boiler plant right side, the left side of heating jar and boiler plant's right side fixed connection, the one end of heating ring and the inner wall fixed connection of heating jar, the one end of leading temperature metal needle is pegged graft with the lower part of heating jar left wall.
The boiler device comprises a sand-filled heat-insulating wall, a power supply base, a power line, a heating base, a metal heating ball, an inner container, a sand layer, a filling opening, a heating ring, an electric wire, a heat conduction through hole, a first heat conduction pipe, a temperature conduction metal block, an oil-filled copper pipe, a second heat conduction pipe, a heat conduction metal wall and a heating copper pipe, wherein one side of the sand-filled heat-insulating wall is fixedly connected with the inner wall of the boiler device, the bottom wall of the power supply base is fixedly connected with the inner bottom wall of the boiler device, one end of the power line is electrically connected with one side of the power supply base, the bottom of the heating base is electrically connected with the top of the power supply base, the bottom of the metal heating ball is fixedly connected with the top of the heating base, one side of the inner container is fixedly connected with the inner side of the metal heating ball, the sand layer is filled in the metal heating ball, and the filling, one end of the heating ring is fixedly connected with one side of the inner container, one end of the electric wire is electrically connected with the other end of the heating ring, the heat conduction through hole is formed in the lower portion of the metal heating ring, one end of the first heat conduction pipe is connected with the bottom of the inner container in an inserting mode, the top of the heat conduction metal block is fixedly connected with the lower end of the first heat conduction pipe, the outer surface of the oil-filled copper pipe is fixedly connected with the bottom of the heat conduction metal block, one end of the second heat conduction pipe is fixedly connected with one end of the oil-filled copper pipe, the bottom of the heat conduction metal wall is connected with the upper end of the second heat conduction pipe in an inserting mode, and one end of the heating copper pipe.
Furthermore, the upper part of the boiler device comprises a water inlet and a heat-insulating top cover, the water inlet is arranged at the top of the boiler device, and one side of the bottom of the heat-insulating top cover is hinged with one side of the top of the water inlet.
Furthermore, the boiler device is externally provided with a heat-insulating protective cylinder, and the inner wall of the heat-insulating protective cylinder is sleeved with the outer side of the boiler device.
Further, the left side of a section of thick bamboo is protected including tap in the heat preservation, the one end of tap and the left side of a section of thick bamboo that protects in the heat preservation are pegged graft, the one end of tap runs through the left side of a section of thick bamboo that protects in the heat preservation and extends to boiler plant's inside, tap's inner chamber and boiler plant's inner chamber intercommunication.
Furthermore, the bottom of the boiler device comprises supporting legs, and the tops of the supporting legs are fixedly connected with the bottom of the boiler device.
Furthermore, the bottom of the supporting leg comprises a threaded leg, and the top end of the threaded leg is fixedly connected with the lower end of the supporting leg.
Furthermore, the outer side of the threaded leg comprises a nut, a supporting block and a roller, the inner side of the nut is in threaded connection with the upper portion of the threaded leg, the middle portion of the supporting block is sleeved with the middle portion of the threaded leg, and one side of the roller is fixedly connected with one side of the lower portion of the supporting block.
Furthermore, the left end of the temperature-conducting metal needle penetrates through the left side of the heating tank and the right side of the boiler device, and the left end of the temperature-conducting metal needle penetrates through the right side of the metal heating ball and extends to the inside of the sand layer.
Furthermore, one end of the first heat conduction pipe penetrates through the bottom of the liner and the sand layer and extends to the inside of the heat conduction through hole to be fixedly connected with the heat conduction metal block.
The invention provides an energy-saving electric boiler. The method has the following beneficial effects:
1. the energy-saving electric boiler is characterized in that the metal heating ball, the inner container, the sand layer, the sand filling heat preservation wall, the first heat conduction pipe, the temperature conducting metal block, the oil filling copper pipe, the heat conduction metal wall of the second heat conduction pipe and the heating copper pipe are arranged in a matching way, after the metal heating ball is electrified through the heating base, the metal heating ball can generate heat through the heating ring in the inner container, so that the inner container after heating can be preserved heat through the sand layer, the heat in the inner container is not allowed to be lost quickly, the residual temperature in the inner container can be transferred to the temperature conducting metal block through the first heat conduction pipe, the temperature conducting metal block can transfer the heat to the heating copper pipe through the oil filling copper pipe, the second heat conduction pipe and the heat conduction metal wall, the heating copper pipe after being heated and warmed can utilize the heat in the inner container to perform a water heating process, the energy consumption is saved, the water heating efficiency is improved, and the sand in the sand filling heat preservation wall after water boiling can effectively isolate the heat, thereby effectively make electric boiler can save the power consumption through setting up promotion heat preservation time and leading the temperature through the sand and reduce when boiling water time, reduce calorific loss, solved electric boiler on the existing market mostly can only keep warm through constantly heating the heater strip and lead to the problem that the power consumption is high.
2. The energy-saving electric boiler is characterized in that the copper pipe is provided with the air extraction head, the air guide pipe, the heating tank, the heating ring and the temperature-conducting metal needle are arranged in a matching way, so that high-temperature steam generated by the boiler device during water heating can enter the air guide pipe through the air extraction head, thereby leading the high-temperature water vapor into the heating tank by the air duct, leading the heating tank to heat the heating ring to raise the temperature, so that the heating ring after heating and temperature rising can start to rise the temperature in the heating tank, the heating tank after temperature rising can heat the tail part of the temperature-conducting metal needle, so that the heat can be transferred to the sand layer in the metal heating ball by the heat-conducting metal needle after being completely heated, thereby make the sand bed can prolong the heat preservation time to effectively make electric boiler can utilize the heat of self during operation output to keep warm continuously, solved electric boiler on the existing market mostly can only keep warm through constantly heating the heater strip and lead to the problem that the power consumption is high.
3. The energy-saving electric boiler comprises a heat conduction through hole, a first heat conduction pipe, a heat conduction metal block, an oil filling copper pipe, a second heat conduction pipe, a heat conduction metal wall and a heating copper pipe, wherein the heat conduction through hole, the first heat conduction pipe, the heat conduction metal block, the oil filling copper pipe, the second heat conduction pipe, the heat conduction metal wall and the heating copper pipe are arranged, after a heating ring in a liner is operated to emit heat, the first heat conduction pipe can guide the heat in the liner to the heat conduction metal block, so that the heat conduction metal block is heated to be heated and heated, the heat conduction metal block heated and heated can transfer the heat to the oil filling copper pipe in the heat conduction through hole, the oil in the oil filling copper pipe is heated and heated, when the heat of the oil is transferred to the heat conduction metal wall through the second heat conduction pipe, the heat conduction metal wall can be heated and heated, so that the heat can be transferred to the heating copper pipe, so that the heating copper pipe can heat, thereby effectively enabling the electric boiler to perform a water boiling process and to quickly boil water.
4. The energy-saving electric boiler comprises a power supply base, a power line, a heating base, a metal heating ball, a liner, a sand layer, a heating ring and an electric wire, wherein the power supply base is arranged, the power line is inserted into the power supply and then transmits current to the power supply base, the power supply base transmits the current to the heating base, the heating base transmits the current to the electric wire, the electric wire transmits the current to the heating ring, the heating ring starts to work and generate heat in the liner, the heating ring transmits the heat to the sand layer through the liner, the sand layer is prevented from rapidly dissipating the heat in the sand while continuously heating up due to the characteristic of high heat preservation of the density of the sand layer, the sand layer can transmit the heat to the metal heating ball after heating up, the metal heat conducting property is utilized, and the metal heating ball can heat water in the boiler device, thereby effectively enabling the electric boiler to perform a water boiling process.
5. The energy-saving electric boiler is characterized in that the supporting block can slide up and down along the threaded leg through the supporting leg and the matching arrangement of the threaded leg, the nut, the supporting block and the roller, so that the support block can drive the roller to slide up and down, and the nut can move under the thread leg when the nut rotates on the thread leg, so that the supporting block can be continuously pushed downwards when the nut is continuously rotated downwards, and when the supporting block is pushed to the lowest end of the thread leg, the supporting block can contact the ground through the roller, thereby the roller jacks up the boiler device through the supporting block, the thread leg and the supporting leg, thereby the boiler device can move through the roller, so that when the nut is screwed upwards, the lower end of the thread leg can slowly move downwards until contacting the ground, thereby making the screw leg support the boiler device through the supporting leg, thereby effectively making the electric boiler be convenient for to change and place the position.
Detailed Description
As shown in fig. 1-4, an embodiment of the present invention provides an energy-saving electric boiler, which includes a boiler device 1, an upper portion of the boiler device 1 includes a water inlet 2 and a heat-insulating top cover 3, the water inlet 2 is located at a top of the boiler device 1, one side of a bottom of the heat-insulating top cover 3 is hinged to one side of a top of the water inlet 2, so that water can be poured into the boiler device 1 through the water inlet 2, an exterior of the boiler device 1 includes a heat-insulating casing 4, an inner wall of the heat-insulating casing 4 is sleeved to an outer side of the boiler device 1, so that the heat-insulating casing 4 can ensure that heat inside the boiler device 1 is not rapidly lost, a left side of the heat-insulating casing 4 includes a water tap 5, one end of the water tap 5 is inserted into a left side of the heat-insulating casing 4, one end of the water tap 5 penetrates through the left side of the heat-insulating casing 4, thereby enabling a user to receive and take hot water through the water faucet 5, the bottom of the boiler device 1 comprises a supporting leg 6, the top of the supporting leg 6 is fixedly connected with the bottom of the boiler device 1, the bottom of the supporting leg 6 comprises a threaded leg 7, the top end of the threaded leg 7 is fixedly connected with the lower end of the supporting leg 6, thereby enabling the boiler device 1 to be supported through the threaded leg 7 on the supporting leg 6, the outer side of the threaded leg 7 comprises a nut 8, a supporting block 9 and a roller 10, the inner side of the nut 8 is in threaded connection with the upper part of the threaded leg 7, the middle part of the supporting block 9 is sleeved with the middle part of the threaded leg 7, one side of the roller 10 is fixedly connected with one side of the lower part of the supporting block 9, thereby enabling the supporting block 9 to slide up and down along the threaded leg 7, thereby enabling the supporting block 9 to drive the roller 10 to slide up and down, so that the supporting block 9 can be continuously pushed downwards when the nut 8 is continuously rotated downwards, so that when the supporting block 9 is pushed to the lowest end of the threaded leg 7, the supporting block 9 can contact the ground through the roller 10, so that the roller 10 can jack up the boiler device 1 through the supporting block 9, the threaded leg 7 and the supporting leg 6, so that the boiler device 1 can move through the roller 10, so that when the nut 8 is rotated upwards, the lower end of the threaded leg 7 can slowly move downwards until contacting the ground, so that the threaded leg 7 can support the boiler device 1 through the supporting leg 6, the right side of the boiler device 1 comprises an air pumping head 28, an air duct 29, a heating tank 30, a heating ring 31 and a temperature guiding metal needle 32, one end of the air pumping head 28 is inserted into the upper part of the right wall of the boiler device 1, one end of the air duct 29 is inserted into the upper part of the right side of the boiler device 1, and the left side of the heating, one end of the heating ring 31 is fixedly connected with the inner wall of the heating tank 30, one end of the temperature-conducting metal needle 32 is inserted into the lower portion of the left wall of the heating tank 30, the left end of the temperature-conducting metal needle 32 penetrates through the left side of the heating tank 30 and the right side of the boiler device 1, and the left end of the temperature-conducting metal needle 32 penetrates through the right side of the metal heating ball 15 and extends to the inside of the sand layer 17, so that the temperature of the sand layer 17 can be raised by the heat transmitted into the metal heating ball 15 through the temperature-conducting metal needle 32.
The boiler device 1 comprises a sand-filled heat-insulating wall 11, a power supply base 12, a power line 13, a heating base 14, a metal heating ball 15, an inner container 16, a sand layer 17, a filling inlet 18, a heating ring 19, an electric wire 20, a heat-conducting through hole 21, a first heat-conducting pipe 22, a heat-conducting metal block 23, an oil-filled copper pipe 24, a second heat-conducting pipe 25, a heat-conducting metal wall 26 and a heating copper pipe 27, wherein one side of the sand-filled heat-insulating wall 11 is fixedly connected with the inner wall of the boiler device 1, the bottom wall of the power supply base 12 is fixedly connected with the inner bottom wall of the boiler device 1, one end of the power line 13 is electrically connected with one side of the power supply base 12, the bottom of the heating base 14 is electrically connected with the top of the power supply base 12, the bottom of the metal heating ball 15 is fixedly connected with the top of the heating base 14, one side of the inner container 16 is fixedly connected with the inner, the filling port 18 is arranged at the top of the metal heating ball 15, one end of the heating ring 19 is fixedly connected with one side of the inner container 16, one end of the electric wire 20 is electrically connected with the other end of the heating ring 19, the heat conducting through hole 21 is arranged at the lower part of the metal heating ring 31, one end of the first heat conducting pipe 22 penetrates through the bottom of the inner container 16 and the sand layer 17 and extends to the inside of the heat conducting through hole 21 to be fixedly connected with the heat conducting metal block 23, so that the heat in the inner container 16 and the heat in the sand layer 17 can be transferred to the heat conducting metal block 22 in the heat conducting through hole 21 by the first heat conducting pipe 22, one end of the first heat conducting pipe 22 is inserted into the bottom of the inner container 16, the top of the heat conducting metal block 23 is fixedly connected with the lower end of the first heat conducting pipe 22, the outer surface of the oil filling copper pipe 24 is fixedly connected with the bottom of the heat conducting metal block 23, one end of the, the bottom of the heat conducting metal wall 26 is inserted into the upper end of the second heat conducting pipe 25, and one end of the heating copper pipe 27 is inserted into one side of the heat conducting metal wall 26.
When the boiler is used, the supporting block 9 can slide up and down along the threaded leg 7, so that the supporting block 9 can drive the roller 10 to slide up and down, when the nut 8 rotates on the threaded leg 7, the nut 8 can move under the threaded leg 7, when the nut 8 rotates downwards continuously, the supporting block 9 can be pushed downwards continuously, when the supporting block 9 is pushed to the lowest end of the threaded leg 7, the supporting block 9 can contact the ground through the roller 10, so that the roller 10 jacks up the boiler device 1 through the supporting block 9, the threaded leg 7 and the supporting leg 6, so that the boiler device 1 can move through the roller 10, when the nut 8 rotates upwards, the lower end of the threaded leg 7 can move downwards slowly until contacting the ground, so that the threaded leg 7 can support the boiler device 1 through the supporting leg 6, and the electric boiler can be placed conveniently, the power line 13 is inserted into the power supply and then transmits the current to the power supply base 12, so that the power supply base 12 transmits the current to the heating base 14, the heating base 14 transmits the current to the electric wire 20, the electric wire 20 transmits the current to the heating ring 19, the current of the heating ring 19 influences the work in the inner container 16 to generate heat, the heated heating ring transmits the heat to the sand layer 17 through the inner container 16, the sand layer 17 cannot rapidly dissipate the heat in the sand while continuously heating by utilizing the characteristic of high heat preservation property of the density of the sand layer 17, the sand layer 17 can transmit the heat to the metal heating ball 15 after heating, the metal heating ball 15 can heat and water the water in the boiler device 1 by utilizing the temperature guide property of the metal, so that the electric boiler can perform the water heating process, and the heating ring 19 in the inner container 16 operates to dissipate the heat, the first heat conduction pipe 22 can conduct the heat in the inner container 16 to the heat conduction metal block 23, so that the heat conduction metal block 23 is heated to raise the temperature, so that the heat conduction metal block heated to raise the temperature can transfer the heat to the oil filling copper pipe 24 in the heat conduction through hole 21, so that the oil in the oil filling copper pipe 24 is heated to raise the temperature, so that when the heat of the oil is transferred to the heat conduction metal wall 26 through the second heat conduction pipe 25, the heat conduction metal wall 26 can be heated to raise the temperature, so that the heat conduction metal wall 26 heated to raise the temperature can transfer the heat to the heating copper pipe 27, so that the heating copper pipe 27 can be heated to raise the temperature, so that the heating copper pipe 27 can heat and boil the water on the upper part of the boiler device 1 when the metal heating ball 15 works, so that the electric boiler can perform a water boiling process and fast water boiling, after the metal heating ball 15 is electrified through the heating base 14, the heating ring 19 in the inner container 16 can heat, so that the heated inner container 16 can be insulated through the sand layer 17, and the heat in the inner container 16 is not lost rapidly, so that the residual heat in the inner container 16 can be transferred to the heat conducting metal block 23 through the first heat conducting pipe 22, so that the heat conducting metal block 23 can transfer the heat to the heating copper pipe 27 through the oil filling copper pipe 24, the second heat conducting pipe 25 and the heat conducting metal wall 26, so that the heating copper pipe 27 heated to be heated can perform a water boiling process by using the heat in the inner container 16, thereby improving the water boiling efficiency while saving the energy consumption, so that the sand in the sand filling heat insulation wall 11 after the water boiling can effectively isolate the rapid loss of the heat in the water, thereby the electric boiler can save the energy consumption while improving the heat preservation time and reducing the water boiling time through the sand heat conducting, reduce the heat loss, and enable the high-temperature steam generated by the boiler device 1 during the water boiling to enter the air duct 29 through the air extraction head 28, thereby make air duct 29 with the leading-in heating jar 30 of high temperature vapor, thereby make heating jar 30 can heat the ring 31 that generates heat and rise in temperature, thereby make the ring 31 that generates heat after the heating heaies up can the time heating jar 30's inside begin to heat up, thereby make the heating jar 30 after the intensification can heat the afterbody of leading warm metal needle 32, thereby make lead warm metal needle 32 after the complete heating can be with in heat transfer to the sand bed 17 in the metal heating ball 15, thereby make sand bed 17 can prolong the heat preservation time, thereby make the electric boiler can utilize the heat of self during operation output to keep warm continuously.