CN201463217U - Optical-magnetic combination heating body - Google Patents

Optical-magnetic combination heating body Download PDF

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Publication number
CN201463217U
CN201463217U CN2009200792560U CN200920079256U CN201463217U CN 201463217 U CN201463217 U CN 201463217U CN 2009200792560 U CN2009200792560 U CN 2009200792560U CN 200920079256 U CN200920079256 U CN 200920079256U CN 201463217 U CN201463217 U CN 201463217U
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calandria
far
magnetic energy
light wave
infrared light
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Expired - Fee Related
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CN2009200792560U
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Chinese (zh)
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刘春�
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Individual
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Individual
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Abstract

The utility model discloses an optical-magnetic combination heating body which comprises a magnetic energy heating body and at least one far-infrared optical wave heating body, wherein the magnetic energy heating body is internally provided with at least one magnetic energy heating body water conduction body with a water inlet and a water outlet and a magnetic energy heating coil installed on the magnetic energy heating body water conduction body; the far-infrared optical wave heating body is internally provided with a far-infrared heating shell and at least one far-infrared optical wave transmitting tube, a water inlet and a water outlet of the far-infrared heating shell are communicated with the water inlet and/or the water outlet of the magnetic energy heating body water conduction body, the far-infrared optical wave transmitting tube is arranged in the far-infrared heating shell, and both ends of the far-infrared optical wave transmitting tube are supported on the far-infrared heating shell. The utility model has the advantages of energy saving, environment protection, power consumption reduction, convenient installation and use and favorable safety and reliability and can prolong the service life, heat water and also heat other flowing liquids.

Description

Optomagnetic combined heated body
Technical field:
The utility model is relevant with the electrical heating water heater.Particularly with to be applied to the optomagnetic combined heated body that the combination of far red light and magnetic energy heats flowing liquid relevant.
Background technology:
Instant heating type electric heater in the market mainly is the instant electric water heater who adopts the quartz heating of electrolemma technology.Therefore this water heater exists significantly not enough because heat energy conversion efficient is low: the one, and load is big, and power bracket is generally between 6KW-10KW.This situation requires user's house power distribution condition very high, and the above water heater of 8KW is ammeter 40A to the requirement of family's electrical arrangement, and the sectional area of power line is at 6mm 2More than, then general family all can't use; The 2nd, the water heater about 6KW can only use in summer, and water yield is smaller.Because heating needs bigger ammeter, power can guarantee enough water yields and temperature at the water heater of 8KW~10KW in winter; The 3rd, security performance reduces, and for the 6KW water heater that uses in summer, the power line load reaches 27A, if use the water heater of 8KW winter, the load line of power supply reaches 36A especially.The 4th, not energy-conservation, the water heater for the 6KW that uses summer used 60 minutes continuously, 3.6 yuan of RMB of family burden so, and the 8KW water heater for use winter used 60 minutes continuously, and 4.8 yuan of RMB of family burden also are the wastes of the energy so.
Some low-power are also arranged on the market, and (water heater of 3KW~6KW) from actual effect, can not satisfy the requirement of user to bathing, can only be used for washing one's hands.
The utility model content:
The purpose of this utility model is in order to overcome above deficiency, a kind of energy-conserving and environment-protective to be provided, reduce power consumption, installation, easy to use, security, good reliability, the optomagnetic combined heated body that can increase the service life.
The purpose of this utility model is achieved like this:
Optomagnetic group of body calandria of the utility model, comprise the magnetic energy calandria, at least one far infrared light wave calandria, there is at least one to contain in the magnetic energy calandria, the magnetic energy calandria water guide body of delivery port, be loaded on the magnetic energy heater coil on the magnetic energy calandria water guide body, have in the far infrared light wave calandria and contain and advancing that the water inlet of magnetic energy calandria water guide body and/or delivery port are communicated with, the Far-infrared Heating housing of delivery port, be positioned at the Far-infrared Heating housing and at least one piece far infrared light wave transmitting tube of two end supports on the Far-infrared Heating housing, the quantity of magnetic energy heating water guide body depends on the needs, and can be one and also can be a plurality of.Far infrared light wave transmitting tube quantity depends on the needs, and can be one and also can be a plurality of.
Above-mentioned magnetic energy calandria water guide body is one.
Above-mentioned optomagnetic combined heated body, the far infrared light wave calandria is one.
Above-mentioned optomagnetic combined heated body, far infrared light wave calandria are two or three or four, are positioned at a side of magnetic energy calandria or lay respectively at two sides of magnetic energy calandria, and the entery and delivery port of adjacent far infrared light wave calandria is communicated with by pipeline.
Far infrared light wave transmitting tube in the above-mentioned above-mentioned optomagnetic combined heated body, far ultraviolet heated shell is one.
Far infrared light wave transmitting tube in the above-mentioned optomagnetic combined heated body, Far-infrared Heating housing is two or three or four.
Between adjacent far infrared light wave transmitting tube dividing plate is arranged in the above-mentioned optomagnetic combined heated body, Far-infrared Heating housing.Improve the efficient that transform light energy becomes heat energy.
Above-mentioned optomagnetic combined heated body has the spirality aqueduct that is communicated with entery and delivery port in the Far-infrared Heating housing, increase the water heated time, improves water temperature.
Have polylith vertically to arrange the isolating bar that is connected to form broken line shape conduit pipe respectively with top board or base plate in the above-mentioned magnetic energy calandria, the plane heating body can significantly improve the efficient that magnetic field energy converts heat energy to, and conversion efficiency can reach more than 90%.
The water guide aperture is arranged on the above-mentioned isolating bar, and the water guide aperture on the adjacent isolating bar is staggered.Both guaranteed the heated time of water, and can fully satisfy the requirement of user's bathing, guaranteed the flow of water simultaneously again the water yield at calandria,
By lead the far infrared light wave transmitting tube is connected with external power supply respectively with the magnetic energy heater coil.The utility model when work, the water inlet or the delivery port of far infrared light wave calandria and magnetic energy calandria is communicated with feed pipe or outlet pipe.Open switch, water enters in the far infrared light wave calandria, infrared transmitting tube is sealed in enclosure interior, and through repeatedly reflection and refraction, the ray of must composing that makes produces resonance to the spectral locus that transmitting tube produces at annular seal space, its energy is long-pending more big more, spectral energy is received by stainless steel metal, and metal is passed to hydrone with energy, thereby makes hydrone produce the vibration frictional heating, use this heating arrangement, energy conversion efficiency improves greatly.After entering the further magnetization heating of magnetic energy calandria quilt again, the water of heating flowed out from outlet pipe.(flowing out from outlet pipe again after also can entering other far infrared light wave calandria again).
The utility model heats water by far red light and magnetic energy combination, has following advantage:
1, simple in structure.
2, energy-saving and cost-reducing: the input power of this calandria 1600W, its 6000W input power that adds thermal effect and other instant electric water heater is suitable;
The input power of this calandria 2400W, its 7000W input power that adds thermal effect and other instant electric water heater is suitable;
The input power of this calandria 3200W, its 8000W input power that adds thermal effect and other instant electric water heater is suitable.
3, adopt the water heater of optomagnetic combined heated body, user's dwelling house distribution is not had specific (special) requirements, install, easy to use.
4, the total power input because of system is low, and is less relatively by electric current, and device is not had specific (special) requirements, and water, electricity separate during heating, and therefore whole is safe, and long service life is beneficial to environmental protection.
5, purposes is wide, not only can heat water, and can heat other flowing liquid.
Description of drawings:
Fig. 1 is the utility model structural representation.
Fig. 2 is the controller circuitry block diagram.
Fig. 3 is the far infrared light wave transmitting tube position view in the far infrared light wave calandria.
Fig. 4 is two far infrared light wave transmitting tube locations drawing in the far infrared light wave calandria.
Fig. 5 is three far infrared light wave transmitting tube locations drawing in the far infrared light wave calandria.
Fig. 6 is four far infrared light wave transmitting tube locations drawing in the far infrared light wave calandria.
Fig. 7 is a magnetic energy calandria water guide body internal structure schematic diagram.
Fig. 8 is inner another structural representation of magnetic energy calandria water guide body.
Fig. 9 is a magnetic energy calandria water guide body inside structural representation again.
Figure 10 is square electromagnetic induction coil coiling figure.
Figure 11 is rectangle electromagnetic induction coil coiling figure.
Figure 12 is oval electromagnetic induction coil coiling figure.
Figure 13 is circular electromagnetic induction coil coiling figure.
Figure 14 is a far infrared light wave calandria structural representation.
Figure 15 is two the far infrared light wave calandrias and the magnetic energy calandria location drawing.
Figure 16 is three the far infrared light wave calandrias and the magnetic energy calandria location drawing.
Figure 17 is three far infrared light wave calandrias and magnetic energy calandria another location figure.
Figure 18 is four the far infrared light wave calandrias and the magnetic energy calandria location drawing.
Figure 19 is four far infrared light wave calandrias and magnetic energy calandria another location figure.
Figure 20 is four a far infrared light wave calandrias and magnetic energy calandria location drawing again.
Figure 21 is the magnetic energy calandria combination schematic diagram that a magnetic energy calandria water guide body is arranged.
Figure 22 is the magnetic energy calandria combination schematic diagram that two magnetic energy calandria water guide bodies are arranged.
Figure 23 is the magnetic energy calandria combination schematic diagram that three magnetic energy calandria water guide bodies are arranged.
Figure 24 is the magnetic energy calandria combination schematic diagram that four magnetic energy calandria water guide bodies are arranged.
Figure 25 is the magnetic energy calandria combination schematic diagram that five magnetic energy calandria water guide bodies are arranged.
The specific embodiment:
Referring to Fig. 1, the optomagnetic combined heated body of present embodiment comprises magnetic energy calandria 1, is positioned at two far infrared light wave calandrias 2 of magnetic energy calandria both sides.A magnetic energy calandria water guide body 5 that contains water inlet 3, delivery port 4 is arranged in the magnetic energy calandria, be loaded on magnetic energy heater coil 8 on magnetic energy calandria water guide body base plate 6 and the top board 7 respectively by screw.Have in the far infrared light wave calandria to contain the water inlet 9 that is communicated with the water inlet or the delivery port of magnetic energy calandria water guide body, the Far-infrared Heating housing 12 of delivery port, be positioned at the Far-infrared Heating housing and the far infrared light wave transmitting tube 13 of two end supports on the Far-infrared Heating housing.The magnetic energy heater coil is connected with outsourcing controller 14 respectively by lead with the far infrared light wave transmitting tube.
Far infrared light wave transmitting tube in the far ultraviolet heated shell is illustrated in figure 3 as one or be illustrated in figure 4 as two or be illustrated in figure 5 as three or be illustrated in figure 6 as four.
As between Fig. 4~adjacent far infrared light wave transmitting tube shown in Figure 6 dividing plate 15 being arranged.
As shown in Figure 7, there is polylith vertically to arrange the isolating bar 17 that is connected to form broken line shape conduit pipe respectively with top board 7 or base plate 6 in the magnetic energy calandria water guide body.Water guide aperture 18 is arranged on the isolating bar, and the water guide aperture on the adjacent isolating bar is staggered.Entery and delivery port lays respectively at the two ends of the both sides of magnetic energy calandria water guide body.
Water-in and water-out on the magnetic calandria water guide body also can be positioned at the homonymy or the same termination that lays respectively at the both sides of magnetic energy calandria water guide body shown in Figure 9 of magnetic energy heating water guide body as shown in Figure 8.
Figure 10-Figure 13 is respectively square, rectangle, ellipse, circular electromagnetic induction coil coiling figure.
As shown in figure 14, the spirality aqueduct 19 that is communicated with entery and delivery port is arranged in the Far-infrared Heating housing.
As shown in figure 15, the far infrared light wave calandria is two, is positioned at a side of magnetic calandria.
As Figure 16~shown in Figure 20, the far infrared light wave calandria is three or four, is positioned at a side of magnetic energy calandria or lays respectively at two sides of magnetic energy calandria, and the entery and delivery port of adjacent far infrared light wave calandria is communicated with by pipeline.
Figure 21~Figure 25 is respectively the constitutional diagram that or two or three or four or five magnetic energy calandria water bodys and magnetic energy heater coil constitute the magnetic energy calandria. and a plurality of magnetic energy heater coils are connected on the base plate or top board of magnetic energy calandria water guide body by screw 20.
It is JSBPVER080101 that controller adopts model.Referring to Fig. 2, controller comprises the IC control circuit, the reduction voltage circuit that is connected with the IC control circuit, over-voltage detection circuit, current detection circuit, temperature sensing circuit, LED display circuit, power adjusting circuit, pwm circuit respectively, AC power, bridge rectifier, oscillating circuit, power driving circuit.
AC power: for system provides 200V, the system power supply of 50Hz
Bridge rectifier: for IGBT drives the dc source that the loop provides 20V
Oscillation circuit: be the LC oscillating circuit, this circuit absorption system input power according to electromagnetic induction principle, produces galvanomagnetic-effect and calandria is heated on the plane heating body.
Power drive: this circuit will be amplified to the signal that is enough to drive IGBT ON/OFF from the pulse signal of pulse width regulating circuit output, and the high level width of the pulse signal of input is bigger, represent that then power is stronger.
Current detection circuit: in this circuit current transformer is serially connected on the circuit before the bridge rectifier, therefore the AC voltage on the transformer secondary side can obtain the variation of input current, this AC voltage is dc voltage through full-wave rectification again, this voltage is through directly suitable to the AD conversion of CPU after the dividing potential drop, and CPU judges size of current according to the AD value after changing and controls the PWM output pulse width and control power output.
Over-voltage detection circuit: when oscillating voltage when moment surpasses 800V, the locked output of CPU stops the LC vibration, protection IGBT can not press puncture.
Reduction voltage circuit: the 20V DC voltage that this circuit produces bridge rectifier step-down once more becomes 5V, and this voltage is the power supply of IC main control circuit.
Temperature sensing circuit: this circuit major function is the temperature according to the water of temperature-sensitive (NTC) the sensing output that places the water heater output, the change resistance value obtains temperature variant voltage analog signal and is sent to master control IC (CPU), the CPU processing that the controlled temperature setting value is relatively made heating or stopped to heat after the A/D conversion.
The LED display circuit: showing the water temperature of calandria, also is the operation interface of calandria power setting simultaneously.
The IC control circuit: power source ON/OFF switching controls, heating and temperature control, shutdown automatically, the keypress function input detects, the control of pwm signal pulse width, LED shows functions such as control.
Calandria system parameter
Infrared tube spectrum calandria: input voltage: 220V, 50Hz
Length: 200mm~600mm
Housing internal diameter (Φ): 12mm
Housing external diameter (Φ): 14mm~22mm
Case material: select stainless steel (304 type) for use
Magnetic energy calandria: input: LC oscillatory system
Length: 200mm~600mm
Width: 100mm~400mm
Thickness: 2mm~300mm
Heater coil: 2 groups~8 groups
Material: select stainless steel for use

Claims (10)

1. optomagnetic combined heated body, it is characterized in that comprising magnetic energy calandria, at least one far infrared light wave calandria, at least one magnetic energy calandria water guide body that contains entery and delivery port is arranged in the magnetic energy calandria, be loaded on the magnetic energy heater coil on the magnetic energy calandria water guide body, the Far-infrared Heating housing that contains the entery and delivery port that is communicated with the water inlet and/or the delivery port of magnetic energy calandria water guide body is arranged in the far infrared light wave calandria, be positioned at the Far-infrared Heating housing and at least one piece far infrared light wave transmitting tube of two end supports on the Far-infrared Heating housing.
2. optomagnetic combined heated body as claimed in claim 1 is characterized in that magnetic energy calandria water guide body is one.
3. optomagnetic combined heated body as claimed in claim 1 or 2 is characterized in that the far infrared light wave calandria is one.
4. optomagnetic combined heated body as claimed in claim 1 or 2, it is characterized in that the far infrared light wave calandria is two or three or four, be positioned at a side of magnetic energy calandria or lay respectively at two sides of magnetic energy calandria, the entery and delivery port of adjacent far infrared light wave calandria is communicated with by pipeline.
5. optomagnetic combined heated body as claimed in claim 1 or 2 is characterized in that the far infrared light wave transmitting tube in the far ultraviolet heated shell is one.
6. optomagnetic combined heated body as claimed in claim 1 or 2 is characterized in that the far infrared light wave transmitting tube in the Far-infrared Heating housing is two or three or four.
7. optomagnetic combined heated body as claimed in claim 6 is characterized in that between adjacent far infrared light wave transmitting tube dividing plate being arranged in the Far-infrared Heating housing.
8. optomagnetic combined heated body as claimed in claim 1 or 2 is characterized in that the spirality aqueduct that is communicated with entery and delivery port is arranged in the Far-infrared Heating housing.
9. optomagnetic combined heated body as claimed in claim 1 or 2 is characterized in that having in the magnetic energy calandria polylith vertically to arrange the isolating bar that is connected to form broken line shape conduit pipe respectively with top board or base plate.
10. optomagnetic combined heated body as claimed in claim 9 is characterized in that the water guide aperture is arranged on the isolating bar, and the water guide aperture on the adjacent isolating bar is staggered.
CN2009200792560U 2009-02-27 2009-02-27 Optical-magnetic combination heating body Expired - Fee Related CN201463217U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2009200792560U CN201463217U (en) 2009-02-27 2009-02-27 Optical-magnetic combination heating body

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2009200792560U CN201463217U (en) 2009-02-27 2009-02-27 Optical-magnetic combination heating body

Publications (1)

Publication Number Publication Date
CN201463217U true CN201463217U (en) 2010-05-12

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Family Applications (1)

Application Number Title Priority Date Filing Date
CN2009200792560U Expired - Fee Related CN201463217U (en) 2009-02-27 2009-02-27 Optical-magnetic combination heating body

Country Status (1)

Country Link
CN (1) CN201463217U (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102858042A (en) * 2011-07-01 2013-01-02 刘朝辉 Open type multimode electromagnetic heater
CN104807179A (en) * 2015-04-15 2015-07-29 肖元斌 Light wave wall-hanging stove

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102858042A (en) * 2011-07-01 2013-01-02 刘朝辉 Open type multimode electromagnetic heater
CN104807179A (en) * 2015-04-15 2015-07-29 肖元斌 Light wave wall-hanging stove
CN104807179B (en) * 2015-04-15 2018-04-27 肖元斌 Light wave wall-hung boiler

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C14 Grant of patent or utility model
GR01 Patent grant
C17 Cessation of patent right
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20100512

Termination date: 20120227