CN201706576U - Individual self-service geothermal radiation heating supply system - Google Patents

Abstract

The utility model provides an individual self-service geothermal radiation heating supply system, which comprises a geothermal heating supply unit and a temperature control unit. The geothermal heating supply unit includes a heater, a boiler, an indoor geothermal radiation coil pipe and a pipeline, wherein the heater is an induction cooker, the boiler is connected with the heater, and the pipeline is connected to the boiler and the geothermal radiation coil pipe. The temperature control unit includes a processor, a storage device and an input module, wherein the storage device and the input module are connected with the processor, and the temperature control unit controls the state of the geothermal heating supply unit. The individual self-service geothermal radiation heating supply system has the advantages of adopting the induction cooker to heat current-carrying media, being clean and sanitary, generating no harmful gas and not polluting environment. In addition, the control unit is adopted to separately control the temperature inside each room, reduce electric consumption power when load is small, improve electric consumption power when load is large, and reasonably save electric energy. The temperature inside an individual room can be freely set according to the need of residents, and the set information is timely fed back to a controller, thereby the heating power of the induction cooker is adjusted.

Description

Separated self-service geothermal radiant heating system

Technical field

The utility model relates to the indoor heating system, particularly a kind of separated self-service geothermal radiant heating system.

Background technology

Existing geothermal heating system system, it is central heating, promptly in whole sub-district or the area one central thermal source is set, provide heat-carrying agent to each minute family by this central authorities' thermal source, heat-carrying agent flow through each minute heat conduction during the family, heat radiation, thus the indoor temperature in each minute family improved, realize indoor heating.

Because the inhabitation situation in the inhabitation situation difference of each resident family, its each room of single resident family is also different in whole sub-district or the area, so adopt the sub-district central heating, the thermal loss that causes is very big, has also damaged the interests of each resident family when wasting natural resources greatly.

Summary of the invention

In order to solve existing technical problem, the utility model provides a kind of separated self-service geothermal radiant heating system, it adopts electromagnetic oven to carry out the heating of heat-carrying agent, adopt free control mode to realize the adjusting of heating system temperature, thus energy savings to greatest extent when satisfying the user and heat demand.

The utility model solves existing technical problem, and a kind of separated self-service geothermal radiant heating system is provided, and it comprises geothermal heating system unit and temperature control unit; Described geothermal heating system unit comprises heater, the boiler that links to each other with described heater, is arranged at indoor underground heat radiant coil and is connected in described boiler and the pipeline of described underground heat radiant coil; Described heater is an electromagnetic oven; Described temperature control unit comprises processor, the memory and the input module that link to each other with described processor, and described temperature control unit is controlled the state of described geothermal heating system unit.

The utility model further improves,

Described geothermal heating system unit comprises water knockout drum and magnetic valve, and described boiler and described water knockout drum, described magnetic valve, described pipeline, described underground heat radiant coil form a circulatory system, establish mobile heat-carrying agent in this circulatory system.

This separated self-service geothermal radiant heating system comprises a plurality of underground heat radiant coil, and these a plurality of underground heat radiant coil are divided into a plurality of rooms;

Described temperature control unit links to each other with described magnetic valve; Described temperature control unit is controlled the underground heat radiant coil state in described a plurality of rooms.

This separated self-service geothermal radiant heating system comprises the water supply unit, and described water supply unit links to each other with the described circulatory system.

This separated self-service geothermal radiant heating system comprises infrared sensor, and described infrared sensor is arranged at the indoor human body signal in the sensing chamber that is used for, and described infrared sensor links to each other with described processor.

This separated self-service geothermal radiant heating system comprises the remote controller that links to each other with described temperature control unit.

This separated self-service geothermal radiant heating system comprises temperature sensor, and described temperature sensor is divided in a plurality of rooms.

Described processor links to each other with described electromagnetic oven, controls the output pulses of described electromagnetic oven.

Be provided with by-pass line between described a plurality of circulatory system, on this by-pass line bypass solenoid valve be set, described bypass solenoid valve links to each other with described processor.

Compared to prior art, the beneficial effects of the utility model are: adopt electromagnetic oven heating current-carrying medium, and clean, sanitary, do not produce pernicious gas, free from environmental pollution.In addition, employing control module locellus is controlled the room temperature in each room, and load hour reduction power consumption improves power consumption, rationally saves energy when load is big; Divide indoor temperature freely to set, thereby in time feed back this set information is regulated electromagnetic oven to controller heating power according to resident family's demand.

Description of drawings

Fig. 1 is the principle schematic of the utility model separated self-service geothermal radiant heating system.

The specific embodiment

Below in conjunction with the description of drawings and the specific embodiment the utility model is further specified.

As shown in Figure 1, a kind of separated self-service geothermal radiant heating system, it comprises geothermal heating system unit 1 and temperature control unit 2; Geothermal heating system unit 1 provides heat-carrying agent, and with this heat-carrying agent each indoor ground thermal radiation coil pipe of flowing through, by indoor underground heat radiant coil heat is reached indoor floor, by the floor heat is passed in the air at last, thereby improves room temperature; Temperature control unit 2 is according to the concrete needs of resident family, at concrete room, set concrete temperature, thereby rationally regulates the state of geothermal heating system unit 1, saves its power consumption.Described geothermal heating system unit 1 comprises heater 11, the boiler 12 that links to each other with described heater 11, be arranged at indoor underground heat radiant coil 14 and be connected in the pipeline 13 of described boiler 12 and described underground heat radiant coil 14; Heater 11 changes into heat energy with electric energy.Boiler 12, pipeline 13 and underground heat radiant coil 14 constitute a hydraulic system, and heat-carrying agent circulation time in this hydraulic system transmits heat.Described temperature control unit 2 comprises processor 21, the memory 22 and the input module 23 that link to each other with described processor 21, the state of the described geothermal heating system of described temperature control unit 2 controls unit 1 is promptly controlled the temperature of each underground heat radiant coil 14 and the thermal conversion rate of heater 11.The preferred electromagnetic oven of the utility model is as heater 11.

Electromagnetic oven has another name called electromagnetic stove, is the product of modern heating revolution, and it need not naked light or conduction-type heating, directly allows heat produce in boiler bottom, so the thermal efficiency is greatly improved.Be a kind of energy-efficient heater, be different from all fire being arranged or do not have fire conduction heating tool of tradition fully.Electromagnetic oven is the hot plate tool that utilizes electromagnetic inductive heating principle to make.Partly form by high-frequency induction heating coil (being magnet exciting coil), RF power conversion equipment and controller.During use, feed alternating current in the heater coil, just produce an alternating magnetic field around the coil, the magnetic line of force of alternating magnetic field is most of by the metal boiler, produces a large amount of eddy current in boiler, thereby produces the required heat of heating.In heating process, there is not naked light, so safety, health.

Geothermal heating system described in the utility model unit 1 comprises water knockout drum and magnetic valve, described boiler 12 forms a circulatory system with described water knockout drum, described magnetic valve, described pipeline 13, described underground heat radiant coil 14, establish mobile heat-carrying agent in this circulatory system, this heat-carrying agent is water.Water in the described boiler 12 after the heating is shunted through water knockout drum, and the underground heat radiant coil 14 of the hot water after this shunting in pipeline 13 is flowed through each room is back to boiler 13 by water return pipeline 13 again.Hot water circuit flows its heat is carried out indoor heat radiation from the underground heat radiant coil.Generally speaking, a room is provided with a underground heat radiant coil, different rooms such as bedroom, parlor, bathroom all set up the underground heat radiant coil separately, for room area when excessive, the underground heat radiant coil of at least one can be set in same room, the short distance of being convenient to hot water like this flows fast, accelerates temperature increase speed.

In the bleeder of water knockout drum, be connected on the pipeline 13 of various places heat radiation coil pipe 14 magnetic valve be set, underground heat radiant coil state by this a certain room of magnetic valve master control, idle as a certain room, do not require the heating demand in its room, this moment need only be with the closed electromagnetic valve that links to each other with the underground heat radiant coil in this room, and heat-carrying agent heats with regard to not entering this house interior so.Resident family sets the temperature in each room according to temperature requirements, and this moment, processor 21 was promptly controlled the open and-shut mode or the aperture size of each magnetic valve, thereby changed the heat flow in each underground heat radiant coil, promptly changed radiations heat energy.

In addition, this separated self-service geothermal radiant heating system comprises the domestic water unit, promptly the boiler heated hot water or return by the underground heat radiant coil after warm water enter the domestic water unit, satisfy the needs that people use hot water to wash one's face and rinse one's mouth.At this moment, a water supply unit is set links to each other, immediately the water in the native system is replenished, or regulate after the temperature of hot water to the underground heat radiant coil with this separated self-service geothermal radiant heating system.

This separated self-service geothermal radiant heating system comprises infrared sensor 24, and described infrared sensor 24 is arranged at the indoor human body signal in the sensing chamber that is used for, and described infrared sensor 24 links to each other with described processor.For energy savings, when in the room nobody the time, its heating system can stop or being arranged to the temperature of heat-preserving anti-freezing, so signal that this separated self-service geothermal radiant heating system detects according to infrared sensor 24, if unmanned in the room, the opening amount of promptly closing the magnetic valve in this room or dwindling magnetic valve; If whole indoor unmanned, then close whole heating system, thereby cut the waste.

This separated self-service geothermal radiant heating system comprises the remote controller 25 that links to each other with described temperature control unit, makes resident family make things convenient for the remote control and regulation temperature, in different rooms, as required, anytime anywhere arbitrarily sets the required temperature in each room.Can also pre-set starting time and temperature, or shut-in time and temperature.

This separated self-service geothermal radiant heating system comprises temperature sensor 26, described temperature sensor 26 is divided in a plurality of rooms, temperature value according to temperature sensor 26 detections, compare the temperature value that resident family presets again, if both unanimities are then kept this state of temperature, if be lower than design temperature, then promote the temperature in this room,, then stop the heating in this room if be higher than design temperature.

Described processor links to each other with described electromagnetic oven, controls the output pulses mode of described electromagnetic oven, turns down output pulses when hanging down load, heightens output pulses during high capacity.Its power consumption difference of different output pulses.Described processor also links to each other with described boiler, on described boiler temperature sensor is set, and in time detects the furnace temperature signal to controller, thereby monitors working in the safe temperature scope of boiler.

In addition, between described a plurality of circulatory systems, be provided with by-pass line, on this by-pass line bypass solenoid valve is set, described bypass solenoid valve links to each other with described processor, according to resident family's needs,, can directly use the hot water that returns in high temperature room to heat for the room of specific low temperature demand, thereby rationally utilize and return warm water, cut down the consumption of energy as far as possible.

The utility model adopts electromagnetic oven heating current-carrying medium, and is clean, sanitary, do not produce pernicious gas, free from environmental pollution.In addition, employing control module locellus is controlled the room temperature in each room, and load hour reduction power consumption improves power consumption, rationally saves energy when load is big.Adopt the amount regulative mode of unsteady flow amount stage by stage, in the different heat load demand phases, change the circulation water for heating amount to adapt to the variation of load, be aided with the matter regulative mode that becomes supply water temperature simultaneously, be higher than a certain value for outdoor temperature, the heating period that the thermic load demand is less, do not adopt the amount regulative mode of unsteady flow amount, and employing becomes the matter regulative mode of supply water temperature, the heating flow set can guarantee like this that for guaranteeing the flow value of heating system stable operation system moves stably in the whole heating cycle.

In separated self-service geothermal radiant heating system, the end of underground heat radiant coil has all been reserved temperature-sensing valve, after temperature-sensing valve is installed, the value that can regulate the output pulses of electromagnetic oven according to the difference for backwater pressure reduction and setting value of least favorable end, can both oneself control under the condition of room temperature at each heating terminal temperature difference of assurance, system still can stable operation.

In order further to reduce operating cost, can introduce forecasting mechanism.At first according to the following 24 hours required thermic loads of system of weather forecast data prediction, utilize this numerical value that following 24 hours operating condition of system is estimated, satisfy under the prerequisite of heat demand and indoor comfort degree in assurance, take all factors into consideration factors such as low ebb electricity price period, power failure period, equipment operating efficiency, be optimized calculating, adjust desired temperature, as far as possible at low ebb electricity price period quantity of heat given up.Optimize when calculating, two kinds of schemes are arranged, a kind of taking into account system steady-state characteristic and outdoor mean temperature predicted value; Another kind is under equipment high efficiency operation prerequisite, utilizes the dynamic thermal characteristics Mathematical Modeling of outdoor temperature instantaneous value and system of prediction to adopt the least square method optimizing to make institute's calorific requirement obtain optimum distribution.

The utility model separated self-service geothermal radiant heating system one mount scheme is as follows:

One family comprises parlor, bedroom, kitchen, toilet, and the underground heat radiant coil need be installed in the parlor, uses maximum places because the parlor is a resident family, and its warming requirement is high; The bedroom is the longest place of time of having a rest, also needs warming requirement, and resident family is had a rest under the environment of an appropriateness; The underground heat radiant coil can not be installed in the kitchen, because the heating appliances in kitchen is more, simultaneously, can be arranged on the kitchen to electromagnetic oven of this separated self-service geothermal radiant heating system and boiler, heat is led to the underground heat radiant coil in each room through pipeline; The underground heat radiant coil is preferably installed in the toilet, and resident family can bathing as summer in warm room like this, simultaneously, economizes the bath equipment that dashes of heating services such as first toilet water heater, super bath, reduces life cost.

The utility model separated self-service geothermal radiant heating system, it adopts resident family freely to set the temperature in each room, or freely selects the temperature model in each room, makes the very comfortable of resident family's inhabitation as the antifreeze pattern of low temperature, warm pattern etc.Because low temperature mode or " shut " mode" are arranged to according to the needs of resident family in movable less room, so this heating system is more humane, liberalization, the energy has been saved in maximized minimizing heat waste.

Above content be in conjunction with concrete preferred implementation to further describing that the utility model is done, can not assert that concrete enforcement of the present utility model is confined to these explanations.For the utility model person of an ordinary skill in the technical field, under the prerequisite that does not break away from the utility model design, can also make some simple deduction or replace, all should be considered as belonging to protection domain of the present utility model.

Claims (10)

1. separated self-service geothermal radiant heating system, it comprises geothermal heating system unit and temperature control unit; It is characterized in that: described geothermal heating system unit comprises heater, the boiler that links to each other with described heater, is arranged at indoor underground heat radiant coil and is connected in described boiler and the pipeline of described underground heat radiant coil; Described heater is an electromagnetic oven; Described temperature control unit comprises processor, the memory and the input module that link to each other with described processor, and described temperature control unit is controlled the state of described geothermal heating system unit.

2. separated self-service geothermal radiant heating system according to claim 1, it is characterized in that: described geothermal heating system unit comprises water knockout drum and magnetic valve, described boiler and described water knockout drum, described magnetic valve, described pipeline, described underground heat radiant coil form a circulatory system, establish mobile heat-carrying agent in this circulatory system.

3. separated self-service geothermal radiant heating system according to claim 2 is characterized in that: this separated self-service geothermal radiant heating system comprises a plurality of underground heat radiant coil, and these a plurality of underground heat radiant coil are divided into a plurality of rooms.

4. separated self-service geothermal radiant heating system according to claim 3 is characterized in that: described temperature control unit links to each other with described magnetic valve; Described temperature control unit is controlled the underground heat radiant coil state in described a plurality of rooms.

5. according to any described separated self-service geothermal radiant heating system of claim 1 to 4, it is characterized in that: this separated self-service geothermal radiant heating system comprises the water supply unit, and described water supply unit links to each other with the described circulatory system.

6. according to any described separated self-service geothermal radiant heating system of claim 1 to 4, it is characterized in that: this separated self-service geothermal radiant heating system comprises infrared sensor, described infrared sensor is arranged at the indoor human body signal in the sensing chamber that is used for, and described infrared sensor links to each other with described processor.

7. according to any described separated self-service geothermal radiant heating system of claim 1 to 4, it is characterized in that: this separated self-service geothermal radiant heating system comprises the remote controller that links to each other with described temperature control unit.

8. according to any described separated self-service geothermal radiant heating system of claim 2 to 4, it is characterized in that: this separated self-service geothermal radiant heating system comprises temperature sensor, and described temperature sensor is divided in a plurality of rooms.

9. separated self-service geothermal radiant heating system according to claim 8 is characterized in that: described processor links to each other with described electromagnetic oven, controls the output pulses of described electromagnetic oven.

10. separated self-service geothermal radiant heating system according to claim 9 is characterized in that: be provided with by-pass line between a plurality of described circulatory systems, on this by-pass line bypass solenoid valve be set, described bypass solenoid valve links to each other with described processor.