CN204739785U - Heater - Google Patents

Abstract

The utility model relates to a firing equipment field especially relates to the device for the liquid heating. Its the heating module and module of generating heat of connecting including the electricity, the module of generating heat is including generating heat resistance, the resistance that generates heat includes first resistance and second resistance, the heating module includes rectifying and wave -filtering unit, energy storage unit and microprocessor, the energy storage unit with rectifying and wave -filtering unit, second ohmic connection, first resistance is used for being connected with the power, microprocessor is used for receiving the signal of the heater work of opening, and receiving when heating the signal of the module work of opening, control the power does the power supply of first resistance, the simultaneous control the energy storage unit is second resistance release electric energy.

Description

A kind of heater

Technical field

The utility model relates to firing equipment field, particularly relates to the device of a kind of liquid heating.

Background technology

Energy problem and environmental problem are the key subjects of social concerns always.Along with development and town dweller's growth in the living standard of science and technology, day by day urgent to the demand of clean energy resource.But current gas heater burning can discharge carbon dioxide in a large number, and there is a lot of potential safety hazard.

Common electric heater has storage-type electric water heater and common electric heater, and its volume of storage-type electric water heater is large, the efficiency of heating surface is low.Common electric heater normally to be fed water heating by resistance wire, because feedwater heating needs the regular hour, fetching boiling water tap in a flash, inevitably have a certain amount of cold water to flow out, user just can use water after water temperature raises, and this phenomenon is particularly serious in the region that weather is colder.The outflow of cold water is not only made troubles to user, also can cause a large amount of wastes of water resource.

Utility model content

In view of this, the utility model provides a kind of being conducive to avoid water resource waste, Instant heating type heater.

The heater that the utility model provides comprises heating module and the heating module of electrical connection; Described heating module comprises heating resistor, and described heating resistor comprises the first resistance and the second resistance; Described heating module comprises rectification filtering unit, energy-storage units and microprocessor, and described energy-storage units is connected with described rectification filtering unit, the second resistance, and described first resistance is used for being connected with power supply; Described microprocessor is for receiving the signal of described heater unlatching work, and when receiving the signal of described heating module unlatching work, controlling described power supply is that described first resistance is powered, and control described energy-storage units is the second resistance release electric energy simultaneously.

The heater that the utility model provides also comprises an inversion unit, and described inversion unit is connected between described energy-storage units and described second resistance, and described energy-storage units is that described second resistance is powered by described inversion unit.

In the heater that the utility model provides, in the predetermined amount of time of described microprocessor after the signal receiving described heater unlatching work, controlling described power supply is that described first resistance is powered, control described energy-storage units is that the second resistance is powered simultaneously, after described predetermined amount of time, power supply described in described Microprocessor S3C44B0X continues as described first resistance and powers, and stops described energy-storage units to be that described second resistance is powered.

In the heater that the utility model provides, described heating module also comprises a Charge Management unit, described Charge Management unit is connected with microprocessor with described rectification filtering unit, energy-storage units respectively, and Charge Management unit described in described Microprocessor S3C44B0X adjusts the charging current and charging interval that described power supply is the charging of described energy-storage units in real time.

In the heater that the utility model provides, described energy-storage units has a charge threshold voltage, work in described heater stop, and the voltage at described energy-storage units two ends is when being less than described charge threshold voltage, power supply described in described Microprocessor S3C44B0X is the charging of described energy-storage units, after described energy-storage units both end voltage reaches described charge threshold voltage, power supply described in described Microprocessor S3C44B0X stops as described energy-storage units charging.

In the heater that the utility model provides, described energy-storage units also has a discharge threshold voltage, when described energy-storage units both end voltage is put into equal with described discharge threshold voltage, described microprocessor cuts out described energy-storage units, and only controlling described power supply is that described first resistance is powered.

In the heater that the utility model provides, described heating module also comprises the temperature sampling unit and taps that are connected with described microprocessor respectively, described temperature sampling unit is used for the first temperature value of current and sends it to described microprocessor, described microprocessor is for storing the second temperature value for presetting, and according to the difference of described first temperature value and the second temperature value, control described output power of power supply.

In the heater that the utility model provides, described heater also comprises the first gauge tap and the second gauge tap, described first gauge tap is connected between described power supply and described first resistance, described second gauge tap is connected between described energy-storage units and described second resistance, described first gauge tap is also connected with described microprocessor respectively with the second gauge tap, and receive described microprocessor turn on and off signal.

In the heater that the utility model provides, described heating module also comprises the touch-display unit being connected to described microprocessor, described touch-display unit is for receiving the signal of user's input, and give described microprocessor by this signal transmission, described microprocessor controls described heater work according to described signal.

In the heater that the utility model provides, the signal of described user's input comprises the signal of electric power starting or closedown and the signal default to water flow temperature.

In the heater that the utility model provides, described energy-storage units is lithium ion battery, farad capacitor or battery.

In the described heater that the utility model provides, owing to adding an energy-storage units and the second resistance, in described heating module unlatching work in a flash, it is the first resistance charging that described micro-process controls described power supply, control described energy-storage units is described second resistance release electric energy simultaneously simultaneously, thus increase power output, the heating effect of heating module is strengthened, and then just heating up rapidly in a flash that water can be switched on power at heater, thus reduce the waste of the water resource when opening described heater.

Accompanying drawing explanation

Below in conjunction with drawings and Examples, the utility model is described in further detail, in accompanying drawing:

The structural representation of the heater 100 of its better embodiment provided for the utility model of Fig. 1;

The physical circuit schematic diagram that Fig. 2 is heater 100 shown in Fig. 1;

One physical circuit schematic diagram of the described heater 200 of another better embodiment that Fig. 3 provides for the utility model;

Another physical circuit schematic diagram of the described heater 300 of the another better embodiment that Fig. 4 provides for the utility model.

Detailed description of the invention

For the heater that the utility model provides is described, be described in detail below in conjunction with Figure of description and explanatory note.

In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " is connected ", " connection " should be interpreted broadly, can be the electric connection of two element internals; Can be directly be connected, also indirectly can be connected by intermediary, for the ordinary skill in the art, the concrete meaning of above-mentioned term can be understood as the case may be.In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise one or more these features.In addition, label identical in accompanying drawing below represents identical element.

As shown in Figure 1, the structural representation of the heater 100 of its better embodiment provided for the utility model, described heater 100 comprises heating module 110 and heating module 120, and described heating module 110 is electrically connected with heating module 120.Described heating module 110 provides thermal source for described heating module 120.

As shown in Figure 2, its physical circuit schematic diagram being heater 100 shown in Fig. 1.Described heating module 120 comprises heating resistor, and described heating resistor comprises the first resistance 121 and the second resistance 122; Described heating module 110 is for external power supply, it comprises rectification filtering unit 114, energy-storage units 112 and microprocessor 111, described energy-storage units 112 is connected with described rectification filtering unit 114, second resistance 122, and described first resistance 121 is for being connected with power supply; Described microprocessor 111 is when receiving described heating module 110 and opening the signal of work (such as current unlatching), and controlling described power supply is that described first resistance 121 is powered, and control described energy-storage units 112 is that the second resistance 122 is powered simultaneously.

Concrete, in a preferred embodiment, in the predetermined amount of time of described microprocessor after receiving described heater 100 and opening the signal of work, controlling described power supply is that described first resistance is powered, and control described energy-storage units is that the second resistance is powered simultaneously.Timing when described predetermined amount of time is for occurring from described signal.The time length of described predetermined amount of time can be arranged according to actual conditions, arranges according to described energy-storage units stored energy capacitance simultaneously, such as 0-120 second.Described energy-storage units only works in a predetermined amount of time of described heater unlatching work.

Described energy-storage units 113, for when described microprocessor detects described first signal, is powered for described heating resistor 115 together with described power supply simultaneously.Described energy-storage units 113 can be lithium ion battery, super capacitor (farad capacitor), battery etc.Described energy-storage units 113 has a charge threshold voltage, (when current are closed) is started working at described heating module, and the voltage at described energy-storage units 113 two ends is when being less than described charge threshold voltage, it is that described place energy-storage units 113 charges that described microprocessor 112 controls described power supply, after the voltage of described energy-storage units 113 reaches described charge threshold voltage, described microprocessor 112 controls energy-storage units charging described in described power supply position of rest.Namely after described current are closed, described power supply is that described energy-storage units 113 charges, and when opening in order to next current, described energy-storage units 113 has enough energy to discharge.

Generally, because ordinarily resident's power supply capacity is probably 60A, 220V, i.e. about 12kw, remove other household electrical appliances such as 2, air-conditioning, electromagnetic oven etc., residue active volume is probably 6kw, and by the patten's design of energy storage of the present utility model, namely main line is powered 6kw, if energy storage 6kw, within a predetermined period of time, the power of available release 12kw, and the Electrical Safety problem caused due to residential electricity consumption overload can not be produced.Simultaneously when opening described heating module, the high-power heating module that makes provided due to the short time reaches instant heating, what also namely make water can open at heater just can heat up in a flash rapidly, thus solves the problem that existing resident's power supply capacity can not unrestrictedly increase.

As shown in Figure 3, another physical circuit schematic diagram of the described heater 200 of its another better embodiment provided for the utility model.Described heating module 110 also comprises a Charge Management unit 113, described Charge Management unit 113 is connected with microprocessor 111 with described rectification filtering unit 114, energy-storage units 112 respectively, and described microprocessor 111 controls described Charge Management unit 113 and adjusts the charging current and charging interval that described power supply is the charging of described energy-storage units 112 in real time.

Described heating module 110 also comprises the temperature sampling unit 117 and taps 118 that are connected with described microprocessor respectively, described temperature sampling unit 117 for current the first temperature value and send it to described microprocessor 111, described microprocessor 111 is for storing the second temperature value for presetting, and according to the difference of described first temperature value and the second temperature value, control described output power of power supply.

Described heating module 110 also comprises the first gauge tap 115a and the second gauge tap 115b, described first gauge tap 115a is connected between described power supply and described first resistance 121, described second gauge tap 115b is connected between described energy-storage units and described second resistance 122, described first gauge tap 115a is also connected with described microprocessor 111 respectively with the second gauge tap 115b, and receive described microprocessor 111 turn on and off signal.

Described heating module 110 also comprises the touch-display unit 119 being connected to described microprocessor 111, described touch-display unit 119 is for receiving the signal of user's input, and give described microprocessor 111 by this signal transmission, described microprocessor 111 controls described heater 100 according to described signal and works.The signal of described user's input comprises the signal of electric power starting or closedown and the signal default to water flow temperature.

As shown in Figure 4, the another physical circuit schematic diagram of the described heater 300 of its another better embodiment provided for the utility model.Described heater also comprises an adjustment unit 116, and described adjustment unit 116 is connected between described energy-storage units 112 and described second resistance 122, and described energy-storage units 112 is powered for described second resistance 122 by described adjustment unit 116.In a preferred embodiment, described adjustment unit 116 is for being converted into data signal by direct current signal, and in other embodiments, adjustment unit can also have other functions.

Owing to adding an energy-storage units and the second resistance, work is opened in a flash at described heating module 100, it is that the first resistance 121 charges that described microprocessor 111 controls described power supply, control described energy-storage units 112 simultaneously and discharge electric energy for described second resistance 122 simultaneously, thus increase power output, the heating effect of described heating module 120 is strengthened, and then just heating up rapidly in a flash that water can be switched on power at heater, thus reduce the waste of the water resource when opening described heater.

The better embodiment of the heater provided for the utility model above; the restriction to the utility model rights protection scope can not be interpreted as; those skilled in the art should know; without departing from the concept of the premise utility; also can do multiple improvement or replacement; these all improvement or replacement all should within the scope of rights protections of the present utility model, and namely rights protection scope of the present utility model should be as the criterion with claim.

Claims (10)

1. a heater, is characterized in that: it comprises heating module and the heating module of electrical connection;

Described heating module comprises heating resistor, and described heating resistor comprises the first resistance and the second resistance;

Described heating module comprises rectification filtering unit, energy-storage units and microprocessor, and described energy-storage units is connected with described rectification filtering unit, the second resistance, and described first resistance is used for being connected with power supply; Described microprocessor is for receiving the signal of described heater unlatching work, and when receiving the signal of described heating module unlatching work, controlling described power supply is that described first resistance is powered, and control described energy-storage units is the second resistance release electric energy simultaneously.

2. heater as claimed in claim 1, it is characterized in that: described heating module also comprises an adjustment unit, described adjustment unit is connected between described energy-storage units and described second resistance, and described energy-storage units is that described second resistance is powered by described adjustment unit.

3. heater as claimed in claim 1, it is characterized in that: in the predetermined amount of time of described microprocessor after the signal receiving described heater unlatching work, controlling described power supply is that described first resistance is powered, control described energy-storage units is that the second resistance is powered simultaneously, after described predetermined amount of time, power supply described in described Microprocessor S3C44B0X continues as described first resistance and powers, and stops described energy-storage units to be that described second resistance is powered.

4. heater as claimed in claim 1, it is characterized in that: described heating module also comprises a Charge Management unit, described Charge Management unit is connected with microprocessor with described rectification filtering unit, energy-storage units respectively, and Charge Management unit described in described Microprocessor S3C44B0X adjusts the charging current and charging interval that described power supply is the charging of described energy-storage units in real time.

5. heater as claimed in claim 3, it is characterized in that: described energy-storage units has a charge threshold voltage, work in described heater stop, and the voltage at described energy-storage units two ends is when being less than described charge threshold voltage, power supply described in described Microprocessor S3C44B0X is the charging of described energy-storage units, after described energy-storage units both end voltage reaches described charge threshold voltage, power supply described in described Microprocessor S3C44B0X stops as described energy-storage units charging.

6. heater as claimed in claim 1, it is characterized in that: described heating module also comprises the temperature sampling unit and taps that are connected with described microprocessor respectively, described temperature sampling unit is used for the first temperature value of current and sends it to described microprocessor, described microprocessor is for storing the second temperature value for presetting, and according to the difference of described first temperature value and the second temperature value, control described output power of power supply.

7. heater as claimed in claim 1, it is characterized in that: described heater also comprises the first gauge tap and the second gauge tap, described first gauge tap is connected between described power supply and described first resistance, described second gauge tap is connected between described energy-storage units and described second resistance, described first gauge tap is also connected with described microprocessor respectively with the second gauge tap, and receive described microprocessor turn on and off signal.

8. heater as claimed in claim 1, it is characterized in that: described heating module also comprises the touch-display unit being connected to described microprocessor, described touch-display unit is for receiving the signal of user's input, and give described microprocessor by this signal transmission, described microprocessor controls described heater work according to described signal.

9. heater as claimed in claim 8, is characterized in that: the signal of described user's input comprises the signal of electric power starting or closedown and the signal default to water flow temperature.

10. heater as claimed in claim 1, is characterized in that: described energy-storage units is lithium ion battery, farad capacitor or battery.