CN105509138A - Use method for smart air energy bathtub heat dissipater - Google Patents

Abstract

The invention provides a use method for a smart air energy bathtub heat dissipater. The smart air energy bathtub heat dissipater comprises a heat dissipation bathtub, an air energy device and a controller; the heat dissipation bathtub comprises a double-layer bathtub body, an inner container and an inner plate; the double-layer bathtub body is formed by connecting an outer-layer tub and an inner-layer tub in a sealed mode, a sealing cavity is formed between the outer-layer tub and the inner-layer tub, and the inner container is arranged in the sealing cavity; the inner plate is arranged in the inner-layer tub in a sleeved mode, a heat dissipater is arranged in the inner container, conduction oil is arranged in the inner container, and the heat dissipation bathtub is provided with a hot water pump. When the smart air energy bathtub heat dissipater is used as a heating and heat dissipating device, the air energy device heats water in the sealing cavity of the heat dissipation bathtub, and the heat dissipation bathtub emits heat to the indoor space; when the smart air energy bathtub heat dissipater is used for showering or bathing, the hot water pump pumps the water in the sealing cavity to the inner-layer tub of the heat dissipation bathtub, and the air energy device heats and insulates the bathing water; a mobile phone and the Internet are used for remotely controlling the controller, the smart air energy bathtub heat dissipater can be controlled to work in advance, and hot water can be prepared in advance.

Description

The using method of intelligent air energy bathtub radiator

Technical field

The present invention relates to the using method of a kind of bathtub and radiator, particularly a kind of using method of intelligent air energy bathtub radiator.

Background technology

At present, the bathtub that people use, just uses as bathing, particularly in the north, if bathtub uses as radiator, not only can save the material of radiator, meanwhile, also can save indoor limited space; There is a using method for the intelligent air energy bathtub radiator of radiator function, become people and saved radiator material resource and joint space-efficient needs.

Summary of the invention

The object of the invention is to overcome the deficiencies in the prior art, a kind of using method of intelligent air energy bathtub radiator being provided, for saving radiator material resource, making bathtub have the function of radiator.

The technical solution adopted in the present invention is: intelligent air energy bathtub radiator, include heat radiation bathtub, air energy device and controller, heat radiation bathtub includes double-layer bathtub, inner bag and inner disc, double-layer bathtub is tightly connected by outer cylinder and internal layer cylinder and forms, sealing die cavity is provided with between outer cylinder and internal layer cylinder, inner bag is located in sealing die cavity, utilizes the water in inner bag heated sealant die cavity, as the thermal source of bath hot water and radiator; Inner disc is enclosed within internal layer cylinder, avoids bather directly to step down on the casing wall of internal layer cylinder, is scalded by internal layer cylinder; Internal layer cylinder is provided with Manual water drain valve and electric draining valve, and the water inlet of Manual water drain valve and electric draining valve is located at the cylinder bottom of internal layer cylinder, and the delivery port of Manual water drain valve and electric draining valve is connected with downcomer, for being drained by the bath water in internal layer cylinder; Air energy device includes compressor, radiator, expansion valve and evaporimeter, and the cold-producing medium out splice going splice of compressor is connected with radiator, and radiator is connected with expansion valve, and expansion valve is connected with evaporimeter, and evaporimeter is connected with the cold-producing medium input adapter of compressor; Radiator is located in inner bag, is provided with conduction oil in inner bag; Heat radiation bathtub is provided with heat-exchanger pump, and the joint that draws water of heat-exchanger pump is communicated with sealing die cavity, and the water out adapter of heat-exchanger pump is positioned on internal layer cylinder, for by double-layer bathtub, the hot water sealed in die cavity is extracted in internal layer cylinder; Outer cylinder is provided with water supply electromagnetic valve, and water supply electromagnetic valve out splice going splice is communicated with sealing die cavity, and water supply electromagnetic valve input adapter is connected with running water pipe, for being injected by running water in sealing die cavity; Controller is provided with start button, stop button, water supply button, drain button, hot water button, the first temperature sensor, the second temperature sensor, temperature indicator, the first liquid level sensor, the 4th liquid level sensor, inductive switch, blue-tooth device, temperature controller and Based Intelligent Control button, for Non-follow control and the Based Intelligent Control of intelligent air energy bathtub radiator; First temperature sensor and the first liquid level sensor are positioned at internal layer cylinder, 4th liquid level sensor is positioned at the top of sealing die cavity, and the second temperature sensor is positioned at inner bag, and inductive switch is positioned at the cylinder bottom of internal layer cylinder, temperature controller is located on controller, and the probe of temperature controller is positioned at the interior space; Controller is connected with air energy device, electric draining valve, heat-exchanger pump and water supply electromagnetic valve by control line.

The state of a control of the controller of intelligent air energy bathtub radiator includes Non-follow control state and Based Intelligent Control state; Non-follow control state includes heat radiation Non-follow control state and bathing Non-follow control state; During heat radiation Non-follow control state, the power supply of heat-exchanger pump is cut off by controller, and heat-exchanger pump is in off-position; Based Intelligent Control state includes heat radiation Based Intelligent Control state and bathing Based Intelligent Control state; During heat radiation Based Intelligent Control state, the power supply of heat-exchanger pump is cut off by controller, and heat-exchanger pump is in off-position.

The using method of intelligent air energy bathtub radiator is: when intelligent air energy bathtub radiator uses as heat radiation Non-follow control, press water supply button, water supply button by its Signal transmissions to controller, controller enters heat radiation Non-follow control state, controller controls water supply electromagnetic valve and opens, running water enters sealing die cavity between outer cylinder and internal layer cylinder by running water pipe through water supply electromagnetic valve, when sealing the water level in die cavity and arriving the position of the 4th liquid level sensor, controller controls water supply electromagnetic valve and cuts out, and supplies water and stops; Simultaneously, press start button, start button by its Signal transmissions to controller, controller controls air energy plant running, compressor compresses cold-producing medium runs, evaporimeter is utilized to absorb air energy, radiator is utilized heat to be delivered to conduction oil in inner bag, utilize conduction oil and inner bag that the water in sealing die cavity is heated as hot water, hot water in sealing die cavity transfers heat to the internal layer cylinder of double-layer bathtub, utilize internal layer cylinder to distribute heat to the interior space, intelligent air energy bathtub radiator is used as radiator; When intelligent air energy bathtub radiator uses as bathing Non-follow control, click hot water button, hot water button by its Signal transmissions to controller, controller enters bathing Non-follow control state, controller controls heat-exchanger pump and runs, hot water in sealing die cavity is extracted into internal layer cylinder by heat-exchanger pump, uses as bath water; When the water level arrival of internal layer cylinder requires, then click hot water button, hot water button is by its Signal transmissions to controller, and it is out of service that controller controls heat-exchanger pump, and supplying hot water stops; Meanwhile, along with constantly distributing of internal layer cylinder bath water heat, heat is constantly delivered to internal layer cylinder by the hot water in sealing die cavity, and internal layer cylinder constantly transfers heat to the bath water in internal layer cylinder, reduces the amplitude that bath water temperature reduces, avoids bather to suffer from cold.

When intelligent air energy bathtub radiator uses as radiator Based Intelligent Control, utilize controller to control water supply electromagnetic valve to open, running water enters sealing die cavity by running water pipe through water supply electromagnetic valve, when sealing the water level in die cavity and arriving the position of the 4th liquid level sensor, 4th liquid level sensor by its Signal transmissions to controller, controller controls water supply electromagnetic valve and cuts out, and running water stops entering sealing die cavity; Meanwhile, controller controls the work of air energy device, and compressor operating, utilizes the high temperature heat that the low temperature heat energy of air is converted into by evaporimeter and radiator, by radiator, conduction oil and inner bag by the water heating in sealing die cavity; Heat is delivered to the internal layer cylinder of double-layer bathtub by the hot water in sealing die cavity, utilizes internal layer cylinder to distribute heat to the interior space, implements the heating function of intelligent air energy bathtub radiator; Temperature when indoor is prescribed a time limit higher than in the room temperature of setting, and temperature controller is by its Signal transmissions to controller, and controller controls compressor to be stopped, and radiator stops heat radiation; Along with the continuous reduction of indoor temperature, under the temperature of indoor is lower than the room temperature of setting in limited time, temperature controller is by its Signal transmissions to controller, and controller controls compressor operating, and radiator dispels the heat again; So constantly circulation, controls in the scope of setting by indoor temperature; When intelligent air energy bathtub radiator uses as bathtub Based Intelligent Control, utilize controller to control heat-exchanger pump and run, the hot water in sealing die cavity is extracted in internal layer cylinder by heat-exchanger pump, uses as bath water; When the bath water water level of internal layer cylinder arrives the water level of setting, the first liquid level sensor is by its Signal transmissions to controller, and it is out of service that controller controls heat-exchanger pump, and supplying hot water stops, for user provides the bath water of applicable bathing temperature; Meanwhile, heat is constantly delivered to internal layer cylinder by conduction oil and inner bag by radiator, and heat is constantly transmitted the bath water of internal layer cylinder by internal layer cylinder, avoids bath water temperature to reduce; Bath water along with internal layer cylinder constantly absorbs the heat that internal layer cylinder transmits, when the temperature of bath water rises to the temperature upper limit of setting, first temperature sensor is by its Signal transmissions to controller, and it is out of service that controller controls compressor operating, and radiator stops heat radiation; Bathing or bathing complete, press drain button, drain button by its Signal transmissions to controller, controller control electric draining valve open, the bath water of internal layer cylinder is discharged to downcomer through electric draining valve; Meanwhile, controller exits Based Intelligent Control state.

After controller exits Based Intelligent Control state, user utilizes mobile phone or network to be contacted by blue-tooth device and controller, and controller is issued in the instruction preparing bath hot water, and controller is converted into Based Intelligent Control state after receiving instruction; Controller controls water supply electromagnetic valve and opens, running water enters sealing die cavity by running water pipe through water supply electromagnetic valve, when sealing the water level in die cavity and arriving the position of the 4th liquid level sensor, 4th liquid level sensor by its Signal transmissions to controller, controller controls water supply electromagnetic valve and cuts out, and running water stops entering sealing die cavity; After water supply electromagnetic valve is closed, controller controls the work of air energy device, by radiator, conduction oil and inner bag by the water heating in sealing die cavity, for user gets out bath hot water in advance, implement the long-distance intelligent control of intelligent air energy bathtub radiator work; When the temperature sealing the water in die cavity reaches the temperature upper limit of setting, the first temperature sensor is by its Signal transmissions to controller, and controller controls air energy device and quits work; So constantly circulation, by the water management in sealing die cavity in the temperature range of setting.

The invention has the beneficial effects as follows: intelligent air energy bathtub radiator does not dispel the heat bathtub, air energy device and controller, when intelligent air energy bathtub radiator uses as heating radiator, controller is utilized to control air energy device by the water heating in the sealing die cavity of heat radiation bathtub, utilize heat radiation bathtub to distribute in the interior space by heat, make intelligent air energy bathtub radiator have the function of radiator; When intelligent air energy bathtub radiator uses as bathing or bathing, utilize heat-exchanger pump that the water in sealing die cavity is extracted into the internal layer cylinder of heat radiation bathtub, meanwhile, utilize air energy device to be incubated the bath water heating of internal layer cylinder, make intelligent air energy bathtub radiator have the function of bathtub; Utilize the first temperature sensor and the Based Intelligent Control of the first liquid level sensor enforcement to intelligent air energy bathtub radiator, mobile phone and internet is utilized to implement to control intelligent air energy bathtub radiator long-distance, control the work of intelligent air energy bathtub radiator outside in advance, get hot water ready in advance, make intelligent air energy bathtub radiator have the function of Non-follow control, Based Intelligent Control and Long-distance Control.

Accompanying drawing explanation

Fig. 1 is the structural representation of intelligent air energy bathtub radiator.

Detailed description of the invention

Below in conjunction with accompanying drawing, the present invention is further detailed:

The structural representation of the intelligent air energy bathtub radiator shown in Fig. 1, intelligent air energy bathtub radiator includes heat radiation bathtub 1, air energy device 2 and controller 3, heat radiation bathtub 1 includes double-layer bathtub 4, inner bag 5 and inner disc 6, double-layer bathtub 4 is tightly connected by outer cylinder 7 and internal layer cylinder 8 and forms, be provided with between outer cylinder 7 and internal layer cylinder 8 and seal die cavity 9, inner bag 5 is located in sealing die cavity 9, utilizes the water in inner bag 5 heated sealant die cavity 9, inner disc 6 is enclosed within internal layer cylinder 8, avoids bather directly to step down on the casing wall of internal layer cylinder 8, is scalded by internal layer cylinder 8, internal layer cylinder 8 is provided with Manual water drain valve 10 and electric draining valve 11, and the water inlet of Manual water drain valve 10 and electric draining valve 11 is located at the cylinder bottom 12 of internal layer cylinder 8, and the delivery port of Manual water drain valve 10 and electric draining valve 11 is connected with downcomer 13, when internal layer cylinder 8 needs to drain bath water, open Manual water drain valve 10, bath water is discharged to downcomer 13, air energy device 2 includes compressor 14, radiator 15, expansion valve 16 and evaporimeter 17, the cold-producing medium out splice going splice of compressor 14 is connected with radiator 15, radiator 15 is connected with expansion valve 16, expansion valve 16 is connected with evaporimeter 17, and evaporimeter 17 is connected with the cold-producing medium input adapter of compressor 14, radiator 15 is located in inner bag 5, is provided with conduction oil 18 in inner bag 5, heat radiation bathtub 1 is provided with heat-exchanger pump 19, and the joint 20 that draws water of heat-exchanger pump 19 is communicated with sealing die cavity 9, and the water out adapter 21 of heat-exchanger pump 19 is positioned on internal layer cylinder 8, for being extracted in internal layer cylinder 7 by double-layer bathtub 4 hot water sealed in die cavity 9, outer cylinder 7 is provided with water supply electromagnetic valve 22, and water supply electromagnetic valve 22 out splice going splice is communicated with sealing die cavity 9, and water supply electromagnetic valve 22 input adapter is connected with running water pipe 23, for being injected by running water in sealing die cavity 9, controller 3 is provided with start button 24, stop button 25, water supply button 26, drain button 27, hot water button 28, first temperature sensor 29, second temperature sensor 30, temperature indicator 31, first liquid level sensor 32, 4th liquid level sensor 50, inductive switch 33, blue-tooth device 34, temperature controller 35 and Based Intelligent Control button 36, first temperature sensor 29 and the first liquid level sensor 32 are positioned at internal layer cylinder 7, 4th liquid level sensor 50 is positioned at the top of sealing die cavity 9, second temperature sensor 30 is positioned at inner bag 5, inductive switch 33 is positioned at the cylinder bottom 12 of internal layer cylinder 7, temperature controller 33 is located on controller 3, controller 3 is connected with air energy device 2, electric draining valve 11, heat-exchanger pump 19 and water supply electromagnetic valve 22 by control line.

In order to implement the various control function of intelligent air energy bathtub radiator, the state of a control of the controller 3 of intelligent air energy bathtub radiator includes Non-follow control state and Based Intelligent Control state; Non-follow control state includes heat radiation Non-follow control state and bathing Non-follow control state; During heat radiation Non-follow control state, the power supply of heat-exchanger pump 19 is cut off by controller 3, and heat-exchanger pump 19 is in off-position; Based Intelligent Control state includes heat radiation Based Intelligent Control state and bathing Based Intelligent Control state; During heat radiation Based Intelligent Control state, the power supply of heat-exchanger pump 19 is cut off by controller 3, and heat-exchanger pump 19 is in off-position.In order to ensure the normal use of intelligent air energy bathtub radiator, Manual water drain valve 10, electric draining valve 11 and water supply electromagnetic valve 22 original state are: Manual water drain valve 10, electric draining valve 11 and water supply electromagnetic valve 22 are in closed condition.

When intelligent air energy bathtub radiator uses as heat radiation Non-follow control, press water supply button 26, water supply button 26 by its Signal transmissions to controller 3, controller 3 enters heat radiation Non-follow control state, controller 3 controls water supply electromagnetic valve 22 and opens, running water enters sealing die cavity 9 between outer cylinder 6 and internal layer cylinder 7 by running water pipe 23 through water supply electromagnetic valve 22, when sealing the water level in die cavity 9 and arriving the position of the 4th liquid level sensor 50, controller 3 controls water supply electromagnetic valve 22 and cuts out, and supplies water and stops; Simultaneously, press start button 24, start button 24 by its Signal transmissions to controller 3, controller 3 controls air energy device 2 and runs, compressor 14 compressed refrigerant runs, evaporimeter 17 is utilized to absorb air energy, radiator 15 is utilized heat to be delivered to conduction oil 18 in inner bag 5, utilize conduction oil 18 and inner bag 5 that the water in sealing die cavity 9 is heated as hot water, hot water in sealing die cavity 9 transfers heat to the internal layer cylinder 8 of double-layer bathtub 4, utilize internal layer cylinder 8 to distribute heat to the interior space, intelligent air energy bathtub radiator is used as radiator; When intelligent air energy bathtub radiator uses as bathing Non-follow control, click hot water button 28, hot water button 28 by its Signal transmissions to controller 3, controller 3 enters bathing Non-follow control state, controller 3 controls heat-exchanger pump 19 and runs, hot water in sealing die cavity 9 is extracted into internal layer cylinder 8 by heat-exchanger pump 19, uses as bath water; When the water level arrival of internal layer cylinder 8 requires, then click hot water button 28, hot water button 28 is by its Signal transmissions to controller 3, and it is out of service that controller 3 controls heat-exchanger pump 19, and supplying hot water stops; Simultaneously, along with constantly distributing of internal layer cylinder 8 bath water heat, heat is constantly delivered to internal layer cylinder 8 by the hot water in sealing die cavity 9, and internal layer cylinder 8 constantly transfers heat to the bath water in internal layer cylinder 8, reduce the amplitude that bath water temperature reduces, avoid bather to suffer from cold.

In order to the temperature implementing bath water controls, the bath water of internal layer cylinder 8 is by after internal layer cylinder 8 constantly heating, and the first temperature sensor 28 being located at internal layer cylinder 8 is by its Signal transmissions to controller 3, and the warm temperature indicator 30 that controller 3 controls shows the temperature of bath water; When the temperature of bath water reaches the temperature upper limit of setting, utilize the stop button 25 of controller 3 to control compressor 14 and stop, radiator 15 stops heat radiation, avoids bath water temperature to continue to rise.

When intelligent air energy bathtub radiator uses, after internal layer cylinder 8 bath water temperature reaches the temperature upper limit of setting, bather enters internal layer cylinder 8, is sitting in or lies on inner disc 6, carry out bathing or bathing, avoids human body to contact with internal layer cylinder 8, along with the continuous decline of bath water temperature, when needing heating bath water, again start button 24 is clicked, start button 24 by its Signal transmissions to controller 3, controller 3 air energy device 2 works, compressor 14 runs, evaporimeter 17 is utilized to absorb the low temperature heat energy of air, low temperature heat energy is converted into the heat energy of high temperature after compressor, radiator 15 is utilized heat to be delivered to conduction oil 18 in inner bag 5 and inner bag 5, utilize inner bag 5 by the water heating in sealing die cavity 9, water in sealing die cavity 9 transfers heat to the internal layer cylinder 8 of double-layer bathtub 4, utilize internal layer cylinder 8 by the bath water heating in internal layer cylinder 8, when the temperature of bath water reaches the temperature upper limit of setting, the stop button 25 of controller 3 is utilized to control air energy device 2 out of service, so constantly circulation.

When intelligent air energy bathtub radiator uses as bathing Non-follow control, along with the hot water in sealing die cavity 9 is extracted into internal layer cylinder 8 by heat-exchanger pump 19, the water level in sealing die cavity 9 is along with reduction; When sealing the position of the liquid level in die cavity 9 lower than the 4th liquid level sensor 50,4th liquid level sensor 50 by its Signal transmissions to controller 3, controller 3 controls water supply electromagnetic valve 22 and opens, and running water enters sealing die cavity 9 between outer cylinder 6 and internal layer cylinder 7 by running water pipe 23 through water supply electromagnetic valve 22; When sealing the water level in die cavity 9 and arriving the position of the 4th liquid level sensor 50, the 4th liquid level sensor 50 is by its Signal transmissions to controller 3, and controller 3 controls water supply electromagnetic valve 22 and cuts out; So constantly circulation, makes water level in sealing die cavity 9 in the scope controlled.

In order to implement to provide hot water to heat radiation bathtub 1 and other places, heat radiation bathtub 1 is provided with split flow pump 37, and the tap 38 of split flow pump 37 is connected with the joint 20 that draws water of heat-exchanger pump 19, utilizes split flow pump 37 that delivery is local to other; Outer cylinder 6 wall is provided with suction eye 39, and the joint 20 that draws water of heat-exchanger pump 19 is installed on suction eye 39, and the joint 20 that draws water is tightly connected with suction eye 39; Internal layer cylinder 8 is provided with apopore 40, and the water out adapter 21 of heat-exchanger pump 19 is installed on apopore 40, and water out adapter 21 and apopore 40 are tightly connected.

In order to implement the heat sinking function of heat radiation bathtub 1, the high temperature heat of the radiator 15 of air energy device 2 is delivered on the internal layer cylinder 8 of inner bag 5 and heat radiation bathtub 1, and reducing the loss of heat, inner bag 5 and internal layer cylinder 8 are made up of Heat Conduction Material, and Heat Conduction Material includes aluminium alloy or stainless steel; Outer cylinder 6 is made up of non-thermally conductive material, and non-thermally conductive material includes pottery, resin and plastics, is provided with hollow molded cavity in pottery, resin and plastics; Outer cylinder 6 outer layer covers has one layer of heat preservation cotton 41; For improving its heat-proof quality.

In order to avoid the bath water of the bathtub 1 that dispels the heat overflows, the wall of outer cylinder 6 upper end is provided with spilling water joint 42, and spilling water joint 42 is connected with downcomer 13; (12 walls are provided with first row water hole 43 and the second row mouth of a river 44 to the cylinder bottom of internal layer cylinder 8, Manual water drain valve 10 is installed on first row water hole 43, Manual water drain valve 10 and first row water hole 43 are tightly connected, electric draining valve 11 is installed on the second row mouth of a river 44, and electric draining valve 11 and the second row mouth of a river 44 are tightly connected; When the water level of the bath water of internal layer cylinder 8 exceedes the position of spilling water joint 42, spilling water joint 42 is discharged to downcomer 13 by bath water.

In order to avoid direct body contact's internal layer cylinder 8, be provided with heat conduction space 45 between inner disc 6 and internal layer cylinder 8, inner disc 6 is provided with thermal hole 46, and heat conduction space 45 is communicated with thermal hole 46; When intelligent air energy bathtub radiator uses as radiator, the thermal current in heat conduction space 45 to be flowed the interior space by thermal hole 46, implements the heating function of intelligent air energy bathtub radiator; When intelligent air energy bathtub radiator uses as bathtub, the bath hot water in heat conduction space 45 flow to the position, non-conductive space 45 of internal layer cylinder 8 by thermal hole 46, heat is delivered to the bath water of internal layer cylinder 8.

When intelligent air energy bathtub radiator uses as heating radiator, utilize controller 3 to control air energy device 2 by the water heating in the sealing die cavity 9 of heat radiation bathtub 1, utilize heat radiation bathtub 1 to distribute in the interior space by heat; When intelligent air energy bathtub radiator uses as bathing or bathing, utilize heat-exchanger pump 19 that the water in sealing die cavity is extracted into the internal layer cylinder 8 of heat radiation bathtub 1, meanwhile, utilize the bath water heating of air energy device 2 pairs of internal layer cylinders 8 to be incubated; Utilize the Based Intelligent Control that the first temperature sensor 29 and the first liquid level sensor 32 are implemented intelligent air energy bathtub radiator; Utilize mobile phone and internet to implement to control intelligent air energy bathtub radiator long-distance, control the work of intelligent air energy bathtub radiator outside in advance, get hot water ready in advance.

When intelligent air energy bathtub radiator uses as radiator Based Intelligent Control, press a Based Intelligent Control button 36, Based Intelligent Control button 36 is by its Signal transmissions to controller 3, and controller 3 enters heat radiation Based Intelligent Control state; After controller 3 enters heat radiation Based Intelligent Control state, controller 3 controls water supply electromagnetic valve 22 and opens, running water enters sealing die cavity 9 by running water pipe 23 through water supply electromagnetic valve 22, when sealing the water level in die cavity 9 and arriving the position of the 4th liquid level sensor 50,4th liquid level sensor 50 by its Signal transmissions to controller 3, controller 3 controls water supply electromagnetic valve 22 and cuts out, and running water stops entering sealing die cavity 9; Meanwhile, controller 3 controls air energy device 2 and works, and compressor 14 runs, and utilizes the high temperature heat that the low temperature heat energy of air is converted into by evaporimeter 17 and radiator 15, by radiator 15, conduction oil 18 and inner bag 5 by the water heating in sealing die cavity 9; Heat is delivered to the internal layer cylinder 8 of double-layer bathtub 4 by the hot water in sealing die cavity 9, internal layer cylinder 8 by heat radiation to the heat conduction space 45 between inner disc 6 and internal layer cylinder 8, by heat conduction space 45 air heat, the thermal current in heat conduction space 45 to be flowed the interior space by thermal hole 46, implements the heating function of intelligent air energy bathtub radiator; Temperature when indoor is prescribed a time limit higher than in the room temperature of setting, and temperature controller 33 is by its Signal transmissions to controller 3, and controller 3 controls compressor 14 to be stopped, and radiator 15 stops heat radiation; Along with the continuous reduction of indoor temperature, under the temperature of indoor is lower than the room temperature of setting in limited time, temperature controller 33 is by its Signal transmissions to controller 3, and controller 3 controls compressor 14 and runs, and radiator 15 dispels the heat again; So constantly circulation, controls in the scope of setting by indoor temperature; When intelligent air energy bathtub radiator uses as bathtub, press hot water button 28, hot water button 28 by its Signal transmissions to controller 3, controller 3 enters bathing Based Intelligent Control state, controller 3 controls heat-exchanger pump 19 and runs, hot water in sealing die cavity 9 is extracted in internal layer cylinder 8 by heat-exchanger pump 19, uses as bath water; When the bath water water level of internal layer cylinder 8 arrives the water level of setting, the first liquid level sensor 32 is by its Signal transmissions to controller 3, and it is out of service that controller 3 controls heat-exchanger pump 19, and supplying hot water stops, for user provides the bath water of applicable bathing temperature; Meanwhile, heat is constantly delivered to internal layer cylinder 8 by conduction oil 18 and inner bag 5 by radiator 15, and heat is constantly transmitted the bath water of internal layer cylinder 8 by internal layer cylinder 8, avoids bath water temperature to reduce; Bath water along with internal layer cylinder 8 constantly absorbs the heat that internal layer cylinder 8 transmits, when the temperature of bath water rises to the temperature upper limit of setting, first temperature sensor 28 is by its Signal transmissions to controller 3, and controller 3 controls compressor 14 and runs out of service, and radiator 15 stops heat radiation; Bathing or bathing complete, press drain button 27, drain button 27 is by its Signal transmissions to controller 3, and controller 3 controls electric draining valve 11 and opens, and the bath water of internal layer cylinder 8 is discharged to downcomer 13 through electric draining valve 11; Meanwhile, controller 3 exits Based Intelligent Control state.

In order to implement the long-distance intelligent control of intelligent air energy bathtub radiator, after controller 3 exits Based Intelligent Control state, user utilizes mobile phone or network to be contacted by blue-tooth device 34 and controller 3, controller 3 is issued in the instruction preparing bath hot water, and controller 3 is converted into Based Intelligent Control state after receiving instruction; Controller 3 controls water supply electromagnetic valve 22 and opens, running water enters sealing die cavity 9 by running water pipe 23 through water supply electromagnetic valve 22, when sealing the water level in die cavity 9 and arriving the position of the 4th liquid level sensor 50,4th liquid level sensor 50 by its Signal transmissions to controller 3, controller 3 controls water supply electromagnetic valve 22 and cuts out, and running water stops entering sealing die cavity 9; After water supply electromagnetic valve 22 is closed, controller 3 controls air energy device 2 and works, by radiator, conduction oil 18 and inner bag 5 by the water heating in sealing die cavity 9, for user gets out bath hot water in advance, implement the long-distance intelligent control of intelligent air energy bathtub radiator work; When the temperature sealing the water in die cavity 9 reaches the temperature upper limit of setting, the first temperature sensor 28 is by its Signal transmissions to controller 3, and controller 3 controls air energy device 2 and quits work; So constantly circulation, by the water management in sealing die cavity 9 in the temperature range of setting.

In order to avoid the first temperature sensor 29 is malfunctioning, cause the temperature control of bath water, the first temperature sensor 29 is arranged in the bath water of internal layer cylinder 7, and the second temperature sensor 30 is arranged in the conduction oil 18 of inner bag 5; First temperature sensor 29 is different from the temperature that the second temperature sensor 30 controls, and the temperature that the second temperature sensor 30 controls is greater than the temperature that the first temperature sensor 29 controls; The temperature controlling range of the first temperature sensor 29 is 35 ° of C to 40 ° of C; The temperature controlling range of the second temperature sensor 30 is 41 ° of C to 45 ° of C.When first temperature sensor 29 is malfunctioning, bath water the temperature upper limit that controls more than the first temperature sensor 29 of temperature; Along with radiator 15 constantly transfers heat to conduction oil 18, when the temperature of conduction oil 18 exceedes the temperature upper limit of setting, the second temperature sensor 30 is by its Signal transmissions to controller 3, and controller 3 controls compressor 14 and quits work, and radiator 15 dispels the heat and stops.

In order to control the liquid level of heat radiation bathtub 1, first liquid level sensor 32 includes the first liquid level sensor 47 and the second liquid level sensor 48, first liquid level sensor 47 is positioned at above the second liquid level sensor 48, first liquid level sensor 47 is positioned at the top of internal layer cylinder 7, the position of the first liquid level sensor 47 is lower than the position of spilling water joint 42, second liquid level sensor 48 is positioned at the middle part of internal layer cylinder 7, for controlling the water level of heat radiation bathtub 1.Controller 3 is provided with liquid level selector switch 49, and liquid level selector switch 49 is provided with the first gear and the second gear; First gear of liquid level selector switch 49 is connected with the first liquid level sensor 47, and when liquid level selector switch 49 pushes the position of the first gear, the first liquid level sensor 47 is connected with the control circuit of controller 3 by liquid level selector switch 49; Second gear of liquid level selector switch 49 is connected with the second liquid level sensor 48, and when liquid level selector switch 49 pushes the position of the second gear, the second liquid level sensor 48 is connected with the control circuit of controller 3 by liquid level selector switch 49.

When intelligent air energy bathtub radiator is as bathing Based Intelligent Control, bather selects water level according to demand; When needs high water level, liquid level selector switch 49 is pushed the position of the first gear; Controller 3 controls heat-exchanger pump 19 and runs, hot water in sealing die cavity 9 is extracted in internal layer cylinder 8 by heat-exchanger pump 19, when the water level in internal layer cylinder 8 arrives the position of the first liquid level sensor 47, the first liquid level sensor 47 is by its Signal transmissions to controller 3, and controller 3 controls heat-exchanger pump 19 and stops pumping; When needs low water level, liquid level selector switch 49 is pushed the position of the second gear; Controller 3 controls heat-exchanger pump 19 and runs, hot water in sealing die cavity 9 is extracted in internal layer cylinder 8 by heat-exchanger pump 19, when the water level in internal layer cylinder 8 arrives the position of the secondth liquid level sensor 48, second liquid level sensor 48 is by its Signal transmissions to controller 3, and controller 3 controls heat-exchanger pump 19 and stops pumping.

In order to detect bathtub mat 4, whether someone enters bathing, and inner disc 6 is provided with foot pad 51, avoids inner disc 6 and internal layer cylinder 8 to stick together; Be provided with Compress Spring 53 between inner disc 6 and internal layer cylinder 8, the upper end of Compress Spring 53 contacts with inner disc 6, and the lower end of Compress Spring 53 contacts with internal layer cylinder 8; The height of Compress Spring 53 is greater than the thickness of foot pad 51.Bath inner disc 6, under the effect of Compress Spring 53 elastic force, makes to form a heat conduction space 45 between the cylinder bottom 12 of inner disc 6 and internal layer cylinder 8.

In order to avoid people are in the process of bathing or bathing, water temperature rises, and remind bather, inner disc 6 is provided with induction pieces 55, and induction pieces 55 is positioned at the top of inductive switch 33, and controller 3 is provided with temperature alarm 56; When intelligent air energy bathtub radiator uses, bather lies in inner disc 6 bathing, the gravity of human body overcomes the elastic force of Compress Spring 53, inner disc 6 is declined, make induction pieces 55 close to inductive switch 33, bather to controller 3, is passed to controller 3 in the information of heat radiation bathtub 1 bathing by its Signal transmissions by inductive switch 33; When the temperature of conduction oil 18 exceedes the temperature of setting, the second temperature sensor 30 by its Signal transmissions to controller 3 time, controller 3 control temperature alarm 56, reminds user to stop bathing.When bather lies in inner disc 6 bathing, inner disc 6 overcomes Compress Spring 53 and declines, and when the foot pad 51 of inner disc 6 contacts with internal layer cylinder 8, inner disc 6 stops declining, and makes inner disc 6 and internal layer cylinder 8 maintain a heat conduction space 45, avoids human body to contact with internal layer cylinder 8.

In order to avoid double-layer bathtub 4 is split up by the hot water in sealing die cavity 9, double-layer bathtub 4 is provided with safety valve 57, and safety valve 57 is installed on the casing wall of outer cylinder 7, and the water inlet of safety valve 57 is communicated with sealing die cavity 9, and the delivery port of safety valve 57 is communicated with downcomer 13; Along with in sealing die cavity 9, the temperature of hot water constantly rises, and sealing die cavity 9 hydraulic pressure constantly increases, and sealing die cavity 9 hydraulic pressure to exceed on safe pressure that safety valve 57 sets in limited time, and safety valve 57 is opened automatically, and the hot water of sealing die cavity 9 is let out downcomer 13; When the hydraulic pressure sealing die cavity 9 drops to below the safe pressure of setting, safety valve 57 cuts out automatically, and so constantly circulation, makes the hydraulic pressure control of sealing die cavity 9 in safe range.

In order to improve internal layer cylinder 8 with the bonding strength of outer cylinder 7, internal layer cylinder 8 is provided with rabbet along 52, and rabbet is embedded into inside outer cylinder 7 along 52, makes internal layer cylinder 8 and outer cylinder 7 be tightly connected integral.In order to ensure the intensity of heat radiation bathtub 1, internal layer cylinder 8 is provided with reinforcement 54, reinforcement 54 is fixedly connected with internal layer cylinder 8 and outer cylinder 7, reinforcement 54 is made up of aluminium alloy or stainless steel, reinforcement 54 welds with internal layer cylinder 8, reinforcement 54 embeds 7 li, outer cylinder, and reinforcement 54 is linked together by adhesive and outer cylinder 7; Reinforcement 54 is provided with many, and reinforcement 54 is distributed in sealing die cavity 9.

Claims (9)

1. the using method of intelligent air energy bathtub radiator, intelligent air energy bathtub radiator, include heat radiation bathtub (1), air energy device (2) and controller (3), heat radiation bathtub (1) includes double-layer bathtub (4), inner bag (5) and inner disc (6), double-layer bathtub (4) is tightly connected by outer cylinder (7) and internal layer cylinder (8) and forms, be provided with between outer cylinder (7) and internal layer cylinder (8) and seal die cavity (9), inner bag (5) is located in sealing die cavity (9), internal layer cylinder (8) is provided with Manual water drain valve (10) and electric draining valve (11), air energy device (2) includes compressor (14), radiator (15), expansion valve (16) and evaporimeter (17), and radiator (15) is located in inner bag (5), is provided with conduction oil (18) in inner bag (5), heat radiation bathtub (1) is provided with heat-exchanger pump (19), and outer cylinder (7) is provided with water supply electromagnetic valve (22), controller (3) is provided with start button (24), stop button (25), water supply button (26), drain button (27), hot water button (28), the first temperature sensor (29), the second temperature sensor (30), temperature indicator (31), the first liquid level sensor (32), the 4th liquid level sensor (50), inductive switch (33), blue-tooth device (34), temperature controller (35) and Based Intelligent Control button (36), it is characterized in that: when described intelligent air energy bathtub radiator Based Intelligent Control uses, the water heating utilizing controller (3) control air energy device (2) will dispel the heat in the sealing die cavity (9) of bathtub (1), utilizes heat radiation bathtub (1) to distribute in the interior space by heat, when intelligent air energy bathtub radiator uses as bathing or bathing, utilize heat-exchanger pump (19) that the water in sealing die cavity is extracted into the internal layer cylinder (8) of heat radiation bathtub (1), meanwhile, air energy device (2) is utilized to be incubated the bath water heating of internal layer cylinder (8), utilize the first temperature sensor (29) and the Based Intelligent Control of the first liquid level sensor (32) enforcement to intelligent air energy bathtub radiator, utilize mobile phone and internet to implement to control intelligent air energy bathtub radiator long-distance, control the work of intelligent air energy bathtub radiator outside in advance, get hot water ready in advance.

2. the using method of intelligent air energy bathtub radiator according to claim 1, it is characterized in that: when described intelligent air energy bathtub radiator uses as radiator, press a Based Intelligent Control button (36), Based Intelligent Control button (36) is by its Signal transmissions to controller (3), and controller (3) enters heat radiation Based Intelligent Control state; After controller (3) enters heat radiation Based Intelligent Control state, controller (3) controls water supply electromagnetic valve (22) and opens, running water enters sealing die cavity (9) by running water pipe (23) through water supply electromagnetic valve (22), when sealing the water level in die cavity (9) and arriving the position of the 4th liquid level sensor (50), 4th liquid level sensor (50) by its Signal transmissions to controller (3), controller (3) controls water supply electromagnetic valve (22) and cuts out, and running water stops entering sealing die cavity (9); Simultaneously, controller (3) controls air energy device (2) work, compressor (14) runs, utilize the high temperature heat that the low temperature heat energy of air is converted into by evaporimeter (17) and radiator (15), the water heating in die cavity (9) will be sealed by radiator (15), conduction oil (18) and inner bag (5); Heat is delivered to the internal layer cylinder (8) of double-layer bathtub (4) by the hot water in sealing die cavity (9), internal layer cylinder (8) by heat radiation to the heat conduction space (45) between inner disc (6) and internal layer cylinder (8), by heat conduction space (45) air heat, the thermal current in heat conduction space (45), by thermal hole (46) the flowing interior space, implements the heating function of intelligent air energy bathtub radiator; Temperature when indoor is prescribed a time limit higher than in the room temperature of setting, and temperature controller (33) is by its Signal transmissions to controller (3), and controller (3) controls compressor (14) to be stopped, and radiator (15) stops heat radiation; Along with the continuous reduction of indoor temperature, under the temperature of indoor is lower than the room temperature of setting in limited time, temperature controller (33) is by its Signal transmissions to controller (3), and controller (3) controls compressor (14) and runs, and radiator (15) dispels the heat again; So constantly circulation, controls in the scope of setting by indoor temperature; When intelligent air energy bathtub radiator uses as bathtub, press hot water button (28), hot water button (28) by its Signal transmissions to controller (3), controller (3) enters bathing Based Intelligent Control state, controller (3) controls heat-exchanger pump (19) and runs, the hot water sealed in die cavity (9) is extracted in internal layer cylinder (8) by heat-exchanger pump (19), uses as bath water; When the bath water water level of internal layer cylinder (8) arrives the water level of setting, first liquid level sensor (32) by its Signal transmissions to controller (3), it is out of service that controller (3) controls heat-exchanger pump (19), and supplying hot water stops, for user provides the bath water of applicable bathing temperature; Meanwhile, heat is constantly delivered to internal layer cylinder (8) by conduction oil (18) and inner bag (5) by radiator (15), and heat is constantly transmitted the bath water of internal layer cylinder (8) by internal layer cylinder (8), avoids bath water temperature to reduce; Bath water along with internal layer cylinder (8) constantly absorbs the heat that internal layer cylinder (8) transmits, when the temperature of bath water rises to the temperature upper limit of setting, first temperature sensor (28) by its Signal transmissions to controller (3), controller (3) controls compressor (14) and runs out of service, and radiator (15) stops heat radiation; Bathing or bathing complete, press drain button (27), drain button (27) is by its Signal transmissions to controller (3), and controller (3) controls electric draining valve (11) and opens, and the bath water of internal layer cylinder (8) is discharged to downcomer (13) through electric draining valve (11); Meanwhile, controller (3) exits Based Intelligent Control state.

3. intelligent air energy bathtub radiator using method according to claim 2, it is characterized in that: after described controller (3) exits Based Intelligent Control state, user utilizes mobile phone or network to be contacted by blue-tooth device (34) and controller (3), controller (3) is issued in the instruction preparing bath hot water, after controller (3) receives instruction, is converted into Based Intelligent Control state; Controller (3) controls water supply electromagnetic valve (22) and opens, running water enters sealing die cavity (9) by running water pipe (23) through water supply electromagnetic valve (22), when sealing the water level in die cavity (9) and arriving the position of the 4th liquid level sensor (50), 4th liquid level sensor (50) by its Signal transmissions to controller (3), controller (3) controls water supply electromagnetic valve (22) and cuts out, and running water stops entering sealing die cavity (9); After water supply electromagnetic valve (22) is closed, controller (3) controls air energy device (2) work, the water heating in die cavity (9) will be sealed by radiator, conduction oil (18) and inner bag (5), for user gets out bath hot water in advance, implement the long-distance intelligent control of intelligent air energy bathtub radiator work; When the temperature sealing the water in die cavity (9) reaches the temperature upper limit of setting, the first temperature sensor (28) is by its Signal transmissions to controller (3), and controller (3) controls air energy device (2) and quits work; So constantly circulation, will seal water management in die cavity (9) in the temperature range set.

4. the using method of intelligent air energy bathtub radiator according to claim 2, is characterized in that: when described the first temperature sensor (29) is malfunctioning, bath water the temperature upper limit that controls more than the first temperature sensor (29) of temperature; Along with radiator (15) constantly transfers heat to conduction oil (18), when the temperature of conduction oil (18) exceedes the temperature upper limit of setting, second temperature sensor (30) by its Signal transmissions to controller (3), controller (3) controls compressor (14) and quits work, and radiator (15) heat radiation stops.

5. the using method of intelligent air energy bathtub radiator according to claim 2, is characterized in that: when described intelligent air energy bathtub radiator is as bathing Based Intelligent Control, bather selects water level according to demand; When needs high water level, liquid level selector switch (49) is pushed the position of the first gear; Controller (3) controls heat-exchanger pump (19) and runs, the hot water sealed in die cavity (9) is extracted in internal layer cylinder (8) by heat-exchanger pump (19), when the water level in internal layer cylinder (8) arrives the position of the first liquid level sensor (47), first liquid level sensor (47) is by its Signal transmissions to controller (3), and controller (3) controls heat-exchanger pump (19) and stops pumping; When needs low water level, liquid level selector switch (49) is pushed the position of the second gear; Controller (3) controls heat-exchanger pump (19) and runs, the hot water sealed in die cavity (9) is extracted in internal layer cylinder (8) by heat-exchanger pump (19), when the water level in internal layer cylinder (8) arrives the position of the secondth liquid level sensor (48), second liquid level sensor (48) is by its Signal transmissions to controller (3), and controller (3) controls heat-exchanger pump (19) and stops pumping.

6. the using method of intelligent air energy bathtub radiator according to claim 1, it is characterized in that: described bath inner disc (6), under the effect of Compress Spring (53) elastic force, makes to form a heat conduction space (45) between the cylinder bottom (12) of inner disc (6) and internal layer cylinder (8).

7. the using method of intelligent air energy bathtub radiator according to claim 2, it is characterized in that: when described intelligent air energy bathtub radiator uses, bather lies in inner disc (6) bathing, the gravity of human body overcomes the elastic force of Compress Spring (53), inner disc (6) is declined, (33, bather to controller (3), is passed to controller (3) in the information of heat radiation bathtub (1) bathing by its Signal transmissions by inductive switch (33) close to inductive switch to make induction pieces (55); When the temperature of conduction oil (18) exceedes the temperature of setting, the second temperature sensor (30) by its Signal transmissions to controller (3) time, controller (3) control temperature alarm (56), reminds user to stop bathing.

8. the using method of intelligent air energy bathtub radiator according to claim 7, it is characterized in that: when described bather lies in inner disc (6) bathing, inner disc (6) overcomes Compress Spring (53) and declines, when the foot pad (51) of inner disc (6) contacts with internal layer cylinder (8), inner disc (6) stops declining, make inner disc (6) and internal layer cylinder (8) maintain a heat conduction space (45), avoid human body to contact with internal layer cylinder (8).

9. the using method of intelligent air energy bathtub radiator according to claim 2, it is characterized in that: described sealing die cavity (9) hydraulic pressure to exceed on safe pressure that safety valve (57) sets in limited time, safety valve (57) is opened automatically, and the hot water sealing die cavity (9) is let out downcomer (13); When the hydraulic pressure sealing die cavity (9) drops to below the safe pressure of setting, safety valve (57) cuts out automatically, and so constantly circulation, makes the hydraulic pressure control of sealing die cavity (9) in safe range.