CN112628842B - Radiator intelligent control mechanism and heating radiator system - Google Patents

Abstract

The invention relates to an intelligent control mechanism of a radiator and a heating radiator system, wherein the intelligent control mechanism of the radiator comprises a controller, a first sensor for detecting the gap temperature of a heating radiator, a plurality of second sensors for detecting the room temperature and the humidity, a water temperature sensor for detecting the water temperature of an inlet pipe of the heating radiator, a circulating pump arranged on a pipeline of the heating radiator, a regulating valve arranged on the inlet pipe of the heating radiator and a wind power radiating mechanism arranged on the heating radiator; the controller is connected with the first sensor, the second sensor, the water temperature sensor, the circulating pump, the regulating valve and the wind power heat dissipation mechanism through a wire harness. The heating radiator system comprises a radiator body and the intelligent control mechanism of the radiator. The invention has the advantages of high intelligent degree, more adjustable parameters, high heat dissipation efficiency, high space utilization rate, low noise, high safety factor and the like.

Description

Radiator intelligent control mechanism and heating radiator system

Technical Field

The invention relates to a heating radiator, in particular to an intelligent control mechanism of a radiator and a heating radiator system, and belongs to the field of household heating.

Background

With the popularization of the 5G technology, the era of the Internet of things is coming formally, the smart home serves as the most direct carrier of the Internet of things, and the intellectualization of the traditional home becomes a trend in time. At present, common smart homes are as follows: air conditioner, TV, refrigerator, air purifier etc. the user can directly purchase the replacement, and the radiator equipment of common family heating usefulness is difficult to carry out simple replacement, and it is big to adopt electric heater and air conditioner to keep warm the energy consumption, and to the family of having installed the radiator, space utilization is not high, so the intellectuality of radiator equipment is relatively lagged behind.

The existing heating equipment of the heating radiator adopts the steps that a furnace is firstly utilized to heat water, and then hot water or steam is conveyed into the heating radiator through a water inlet pipeline of the heating radiator, the heating radiator realizes heat exchange with air in a radiation or convection mode, so that the indoor air temperature is raised, the heating purpose is achieved, because the heating radiator is close to the wall and is fixed and cannot move, the heat on one side close to the wall is difficult to be transferred to the indoor, and the heat dissipation efficiency is low; in addition, because the indoor air has poor mobility, the air around the heating radiator is gradually conducted into the room after being heated to a certain temperature, so that the indoor heating time is prolonged.

In order to solve the problems, in the prior art, a water pump is additionally arranged at a water inlet or outlet pipeline, a sensor is additionally arranged in a heating radiator and a room, and a heat radiating device is additionally arranged outside the heating radiator. The sensor transmits the acquired signal to the controller, and the controller controls the water pump and the heat dissipation device, so that the intellectualization of the heating radiator equipment and the improvement of the heat dissipation efficiency are realized. This type of technique, it is low to have intelligent degree, and adjustable and controllable parameter is few, installs heat abstractor additional and adopts the fan more, and space utilization is not high and the noise is big, considers that heating installation position is low, and ordinary additional fan has potential danger to children.

Disclosure of Invention

The invention aims to solve the technical problem of providing an intelligent control mechanism of a radiator and a heating radiating system, which have the advantages of high intelligent degree, more adjustable and controllable parameters, high radiating efficiency, high space utilization rate, low noise and high safety coefficient.

In order to solve the problems, the technical scheme adopted by the invention is as follows:

an intelligent control mechanism of a radiator comprises a controller, a first sensor for detecting the gap temperature of a radiator, a plurality of second sensors for detecting the room temperature, a water temperature sensor for detecting the water temperature of a water inlet pipe of the radiator, a circulating pump arranged on a pipeline of the radiator, a regulating valve arranged on the water inlet pipe of the radiator and a wind power radiating mechanism arranged on the radiator; the controller is connected with the first sensor, the second sensor, the water temperature sensor, the circulating pump, the regulating valve and the wind power heat dissipation mechanism through a wire harness.

As a further improvement of the present invention, the wind power heat dissipation mechanism comprises: a wind power generation device (4), an air volume amplification device (3), a driving device (2) of the air volume amplification device (3), and a fog-free humidifying device (5).

As a further improvement of the invention, the controller is internally provided with a wireless transmission device, and the wireless transmission device comprises a signal transmitter and a signal receiver and can be wirelessly connected with an APP of a remote controller or user intelligent equipment.

A heating radiator cooling system comprises a radiator body (1) and the intelligent radiator control mechanism of claim 1, wherein the wind power cooling mechanism comprises a wind power generation device (4), an air volume amplification device (3) and a driving device (2) of the air volume amplification device (3), an air duct (7) and a slotted hole for arranging the air volume amplification device (3) are reserved on the side surface of the radiator body (1), air flow is guided into the air volume amplification device (3) through the air duct (7), an air inlet pipe (3-1) is arranged on one side of the air volume amplification device (3), a transmission shaft (9) is arranged on the other side of the radiator body (1), the driving device (2) is fixed on the other side of the radiator body (1) and corresponds to the wind power generation device (4), and the driving device (2) is connected with the air volume amplification device (3) through the transmission shaft (9), the air volume amplification device (3) can rotate for 360 degrees by taking the central line of the air duct (7) as an axis.

As a further improvement of the invention, the radiator body (1) comprises a front piece and a rear piece, wherein one piece is in a grid shape, the other piece is reserved with the air duct (7) and the ventilation opening, and a gap is reserved between the two pieces; both radiators can be injected with heat source.

As a further improvement of the present invention, the whole air volume amplification device (3) is a closed ring shape, and may be rectangular, oval, circular or square; one end of the air volume amplification device (3) is provided with an air inlet pipe (3-1) connected with the air duct (7), and the opening of the air inlet pipe (3-1) is horn-shaped.

As a further improvement of the invention, the section of the air volume amplification device (3) is a J-shaped cavity (3-2), the straight end of the J-shaped cavity (3-2) is narrow, the end of the arc is wide, and the tail part of the end of the arc is provided with an air outlet (3-3).

As a further improvement of the invention, the humidifier also comprises a fog-free humidifying device (5), and the fog-free humidifying device (5) is communicated with the air duct (7).

As a further improvement of the invention, two groups of wind power heat dissipation mechanisms are arranged on the heating radiator body (1), the two groups of wind power heat dissipation mechanisms are arranged in parallel, a motor (2-1) is arranged in the driving device (2), a driving gear (2-2) is installed at the output end of the motor (2-1), the gear (2-2) is meshed with a rack sliding block (2-3), the rack sliding block (2-3) is slidably installed on a guide rail in the driving device (2), and the rack (2-3) is meshed with a driven gear (2-4) at one end of a transmission shaft (9).

As a further improvement of the invention, the radiator body (1) is provided with a radiating fin (6) on one side of the air volume amplification device (3), and the radiating fin (6) is provided with an air channel radiating fin (6-1) embedded with the air channel and a transmission shaft radiating fin (6-2) embedded with a transmission shaft (9) of the driving device (2).

Adopt the produced beneficial effect of above-mentioned technical scheme to lie in:

1. the intelligent temperature and humidity controller has high intelligent degree, the controller can automatically adjust the indoor temperature and humidity by automatically controlling various modes of the intelligent heat dissipation mechanism through data acquired by a plurality of sensors arranged at different positions, the overall energy utilization rate is high, and the household improvement is facilitated. The heat dissipation efficiency of a radiator is affected by many factors, such as the water flow speed in the radiator, the surface area of the radiator, the temperature difference between the water temperature and the room temperature, etc., the room temperature at this place is usually mainly the temperature around the radiator, and when the indoor air flowability is poor, the situation that the radiator temperature is high and the indoor temperature is not ideal occurs, which is the reason for this, usually caused by the low heat dissipation efficiency of the radiator. And detect the inside temperature of radiator, its near temperature and the temperature in other indoor regions comprehensively through a plurality of sensors, can acquire the whole condition of environment, and the controller is judged through predetermined procedure, makes corresponding actuating mechanism operation to the pertinence improves the unfavorable condition, makes the radiating efficiency of radiator improve greatly, improves the comprehensive utilization ratio of energy, and concrete operation is scientific and reasonable more, and intelligent degree is higher.

2. After installing wind-force heat dissipation mechanism additional, the heat of gathering up in the radiator body clearance is effectively discharged, can make indoor temperature tend to the equilibrium, and the contrast is with the traditional radiator of volume, and radiating efficiency is showing and is promoting. Compared with a heat dissipation mechanism with a blade fan, the air volume amplification device provided by the invention has the advantages of small noise, high safety coefficient and natural and stable blown air.

3. The wind power heat dissipation mechanism is fixed with the radiator body through the embedded radiating fins or the screws, so that the radiator is convenient to disassemble and replace and has high modularization degree.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a block diagram of the intelligent control mechanism of the radiator of the invention.

Fig. 2 is a schematic structural diagram of a heating heat dissipation system of the present invention.

Fig. 3 is a schematic view of the radiator with the heat sink removed and partially in section.

Fig. 4 is a schematic structural view of the duct fins.

Fig. 5 is a schematic structural view of a propeller shaft fin.

Fig. 6 is a schematic configuration diagram of the air volume amplification device.

FIG. 7 is a schematic cross-sectional view of the airflow amplification apparatus.

FIG. 8 is a schematic view of the structure of the driving device

Wherein: 1. a radiator body; 2. a drive device; 3. an air volume amplification device; 3-1, an air inlet; 3-2, J-shaped cavity; 3-3, an air outlet; 4. a wind power generation device; 5. a humidifying device; 6. a heat sink; 6-1, air duct radiating fins; 6-2, transmission shaft cooling fins; 7. an air duct; 8. a T-shaped cavity; 9. a drive shaft.

Detailed Description

For purposes of clarity and a complete description of the present invention, and the like, in conjunction with the detailed description, it is to be understood that the terms "central," "vertical," "lateral," "up," "down," "front," "back," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing and simplifying the present invention, but do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present invention.

As shown in fig. 1, the intelligent control mechanism of the radiator comprises a controller, a first sensor, a plurality of second sensors (one sensor is shown), a water temperature sensor, a circulating pump arranged on the pipeline of the radiator, a regulating valve arranged on the water inlet pipeline of the radiator, and a wind power heat dissipation mechanism arranged on the radiator. The opening degree of the regulating valve is regulated to control the flow of water, and the starting and stopping of the circulating pump can control the flow speed of the water in the pipeline. The temperature in the gap of the heating radiator body 1 is acquired by a first sensor in the intelligent control mechanism of the radiator, a plurality of second sensors are distributed in an independent space (indoor) where the heating radiator system is located and used for acquiring the temperature and the humidity of different indoor positions, and a water temperature sensor at the position of an inlet water pipeline acquires the heat source temperature of the pipeline, namely the water temperature in the heating radiator.

The controller receives signals of the first sensor, the second sensor and the water temperature sensor, and then sends signals to the regulating valve and/or the circulating pump and/or the wind power heat dissipation mechanism according to a preset program or a user instruction so as to control the action of the regulating valve and/or the circulating pump and/or the wind power heat dissipation mechanism.

The controller can process data collected by the sensor and upload results to a control panel and a remote controller or transmit the results to a mobile phone end of a user through the Internet.

The controller can automatically select the corresponding heat dissipation mode according to the processed collected data, and can also perform self-defined adjustment on each mode through the instruction of a user.

The air volume amplification principle of the air volume amplification device 3 in the heating heat radiation system is as follows: wind generated by the wind power generation device 4 enters the J-shaped cavity 3-2 through the air inlet 3-1 of the air volume amplification device 3, the wind changes the wind direction in the J-shaped cavity 3-2, the wind is ejected from the air outlet 3-3, annular high-speed airflow is formed along the ejection direction, negative pressure is formed at the center of the ring due to the fact that the air pressure of the annular high-speed airflow is lower than that at the center of the ring, and therefore static air in an area opposite to the ejection direction can be sucked to the center of the ring and blown out along the ejection direction, and the air volume amplification function is achieved.

By utilizing the air quantity amplification principle, the air outlets 3-3 face the outer side of the radiator body 1, and hot air in gaps of the radiator body 1 can be blown out through the air quantity amplification device 3, so that the convection of the hot air and the cold air is accelerated, the heat of one side of the radiator close to a wall body is reasonably utilized, and the heat dissipation efficiency is improved; the driving device 2 can drive the transmission shaft 9 to change the direction of the air outlet 3-3 of the air volume amplification device 3, thereby realizing the air sweeping function; the air outlets 3-3 can also face the inside of the heater body, so that the heat preservation and self-cleaning functions inside the heater piece body 1 are realized.

The invention is different from the common bladeless fan for refrigeration, and aims to heat, the heating effect can be weakened due to the fact that the flow speed of air flow ejected by the air outlets 3-3 is too high, so that the requirement on the air speed is not high, the power of a fan used is lower, and the noise and the energy consumption are lower. But the air duct 7 of reserving on radiator body 1 and the air capacity amplification device 3 embedded air current that produces at radiator body 1's structural design heating wind-force production device 4 make the air current that erupts not for cold wind, and the heat of taking away radiator body 1 simultaneously accelerates radiator body 1's heat exchange efficiency, and is preferred, and the workable disk that becomes in air duct 7 middle section heats the effect better.

The design of the grid-shaped radiator is beneficial to heating air, when the air volume amplification device 3 pumps high-temperature air out or feeds low-temperature air in, the newly-entered low-temperature air is ensured to be quickly heated, and the heat dissipation efficiency is improved; and the grid-shaped structure is beneficial to the circulation supplement of air, so that the hot air delivered to the room by the air volume amplification device 3 is uniform and comfortable.

Embodiment 1:

as shown in fig. 2 to 3 and 6 to 7, two sets of oval air amplification devices 3 are embedded in two oval slots of the radiator body 1, a gap is left between the slot air amplification devices 3, the air amplification devices 3 are made of PPR material, and the heat insulation effect and the creep resistance are good. The air duct 7 is a cylindrical cavity in the radiator body and is parallel to the central line of the air inlet pipe 3-1 of the air volume amplification device 3, the inner diameter of one end, close to the air volume amplification device 3, of the air duct 7 is reduced, a 1mm gap is reserved between the inner diameter of the air duct 7 and the outer diameter of the air inlet pipe 3-1, and the air duct 7 is outwards connected with a pipeline fan through an L-shaped bent pipe. The radiator body 1 is provided with a T-shaped cavity 8 between two air channels 7 for communicating the fog-free humidifying device 5 and the air channels 7.

As shown in fig. 2 to 3, the wind power generator 4 and the fog-free humidifier 5 are fixed on the left side of the radiator body 1, and the driving device 2 is fixed on the right side of the radiator body 1.

According to the experimental data of the embodiment, the 60w pipeline fan is arranged in the wind generating device 4, so that the requirement of the air volume of high, low, medium and third gears can be met, and meanwhile, the air blown out from the high gear is not cold air. A filter screen is additionally arranged at the air suction opening of the wind power generation device, so that dust is prevented from entering and damaging electric components.

According to the experimental data of the embodiment, 650ml of water is stored in the fog-free humidifying device 5, which can satisfy 4-hour continuous indoor humidifying mode, and the water storage amount of 650ml can satisfy 8h of working time at the longest considering that the system intelligent adjusting mode is not in a continuous humidifying state.

As shown in fig. 8, the air volume amplification device 3 is connected with the driving device 2 through the transmission shaft 9, a key groove with a threaded hole is arranged at one end of the transmission shaft 9 connected with the air volume amplification device 3, a cylindrical boss inserted into the key groove is reserved on the air volume amplification device 3, and after the transmission shaft 9 is inserted in place, the transmission shaft 9 and the air volume amplification device 3 are fixed through a positioning screw. The middle of the transmission shaft is provided with a bearing which plays a role in supporting and lubricating, so that the air volume amplification device 3 can rotate more smoothly. The other end of the transmission shaft 9 is provided with a driven gear 2-4. When the device works, the driven gear 2-4 is meshed with the rack sliding block 2-3 which is arranged in the driving device 2 in a sliding mode.

As shown in fig. 8, the driving device 2 of the present embodiment adopts a scheme that one motor 2-1 simultaneously drives two sets of wind power heat dissipation mechanisms, that is, a driving gear 2-2 is installed at an output end of the motor 2-1 in the driving device 2, the driving gear 2-2 is engaged with a rack slider 2-3 slidably installed in the driving device 2, and when the driving gear 2-2 rotates, the rack slider 2-3 is driven to slide up and down in the driving device 2, so as to drive a driven gear 2-4 engaged with the rack slider 2-3, and rotate the air volume amplification device 3.

As shown in fig. 2 to 3 and 4 to 5, in the present embodiment, the air inlet duct 3-1 and the transmission shaft 9 of the air volume amplification device 3 are respectively fixed by the air duct heat sink 6-1 and the transmission shaft heat sink 6-2. The structure leads the air volume amplification device 3 to be arranged in the slotted hole of the radiator body 1 from the front, and when the air volume amplification device 3 needs to be replaced and cleaned, the disassembly and the assembly are convenient.

When the temperature of the heat source reaches a preset value (such as 60 ℃), the system enters a heating radiator heating mode, the controller controls the circulating pump to be started, the regulating valve is completely opened, the heat source is introduced into the heating radiator body 1 to heat the heating radiator, and meanwhile, air in the gap of the heating radiator is heated to be heated.

When the temperature of the air collected by the first sensor reaches a preset value (such as 40 ℃) and the average value of the room temperature collected by the second sensor is lower than the preset value (such as 28 ℃), the system enters a heating mode, the controller controls the wind power generation device 4 and the driving device 2 in the wind power heat dissipation mechanism to be started, the air outlet 3-3 faces the outer side of the heating radiator body 1, the wind power generation device 4 adjusts the power of the fan to be high-grade, air flow with high temperature in the heating radiator body is extracted, and indoor heating is accelerated.

When the average value of the room temperature collected by the second sensor reaches a preset value (such as 28 ℃), the system enters a heat preservation mode, the controller controls the air outlet 3-3 to face the inner side of the radiator body 1, and the wind power generation device 4 adjusts the power of the fan to be in a middle gear for heat preservation and self-cleaning.

When the indoor humidity collected by the second sensor is lower than a preset value (such as 30%), the system enters a humidifying mode, the controller controls the fog-free humidifying device 5 to be started, the wind power generation device 4 is controlled to adjust the power of the fan to be in a low level, the fog-free humidifying device 5 wets the built-in humidifying net through the water storage device, dry air in the T-shaped cavity 8 penetrates through the humidifying net to become humid air, the humid air enters the air channel 7 and is blown out of the air volume amplification device 3, and therefore the humidifying function is achieved. Under the control of the controller, the fog-free humidifying device 5 can be started only after the wind power generation device 4 is started and stopped before the wind power generation device 4 is stopped, thereby avoiding damage to electric devices.

When the user adjusts the temperature reduction (such as 24 ℃), the system enters an indoor temperature reduction mode, the controller controls the outdoor circulating pump to reduce the output power, the adjusting valve reduces the entering amount of the heat source, the temperature of the heating radiator body 1 is reduced, meanwhile, the air outlet 3-3 is controlled to face the outer side of the heating radiator body 1, the wind power generation device 4 adjusts the power of the fan to be high-grade, the reduction of the indoor temperature is accelerated, when the average room temperature is reduced to the preset value, the controller controls the power of the wind power generation device 4 to be reduced to a medium-grade, and the air outlet 3-3 faces the inner side of the heating radiator body 1 for heat preservation.

In each mode, the user can visually see the change of the indoor temperature and humidity through the display screen, the mobile phone client or the remote controller.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (6)

1. A heating system cooling system is characterized in that: the heating radiator comprises a heating radiator body (1), a controller, a first sensor for detecting the gap temperature of the heating radiator, a plurality of second sensors for detecting the room temperature and the humidity, a water temperature sensor for detecting the water temperature of a water inlet pipe of the heating radiator, a circulating pump arranged on a pipeline of the heating radiator, a regulating valve arranged on the water inlet pipe of the heating radiator and a wind power heat dissipation mechanism arranged on the heating radiator; the controller is connected with the first sensor, the second sensor, the water temperature sensor, the circulating pump, the regulating valve and the wind power heat dissipation mechanism through a wire harness;

wind-force heat dissipation mechanism includes: a wind power generation device (4), an air volume amplification device (3), a driving device (2) of the air volume amplification device (3) and a fog-free humidifying device (5);

the controller is internally provided with a wireless transmission device, the wireless transmission device comprises a signal transmitter and a signal receiver and can be wirelessly connected with an APP (application) of a remote controller or user intelligent equipment;

an air duct (7) and a slotted hole for arranging an air quantity amplification device (3) are reserved on the side surface of the heating radiator body (1), the airflow is guided into the air volume amplification device (3) through the air duct (7), the section of the air volume amplification device (3) is a J-shaped cavity (3-2), the straight end of the J-shaped cavity (3-2) is narrow, the circular arc end is wide, an air outlet (3-3) is arranged at the tail part of one end of the circular arc, an air inlet pipe (3-1) is arranged at one side of the air volume amplification device (3), a transmission shaft (9) is arranged at the other side, the driving device (2) is fixed on the other side of the radiator body (1), the driving device (2) is connected with the air volume amplification device (3) through a transmission shaft (9) corresponding to the wind power generation device (4), the air volume amplification device (3) can rotate for 360 degrees by taking the central line of the air duct (7) as an axis.

2. The heating heat dissipation system according to claim 1, wherein: the radiator body (1) comprises a front piece and a rear piece, wherein one piece is in a grid shape, the other piece is reserved with the air duct (7) and the ventilation opening, and a gap is reserved between the two pieces; both radiators can be injected with heat source.

3. The heating heat dissipation system according to claim 1, wherein: the whole air volume amplification device (3) is in a closed ring shape and can be rectangular, oval, circular or square; one end of the air volume amplification device (3) is provided with an air inlet pipe (3-1) connected with the air duct (7), and the opening of the air inlet pipe (3-1) is horn-shaped.

4. The heating heat dissipation system according to claim 1, wherein: the device is characterized by further comprising a fog-free humidifying device (5), wherein the fog-free humidifying device (5) is communicated with the air duct (7).

5. The heating heat dissipation system according to claim 1, wherein: the heating radiator is characterized in that two groups of wind power heat dissipation mechanisms are arranged on the heating radiator body (1) in parallel, a motor (2-1) is arranged in the driving device (2), a driving gear (2-2) is installed at the output end of the motor (2-1), the gear (2-2) is meshed with a rack sliding block (2-3), the rack sliding block (2-3) is slidably installed on a guide rail in the driving device (2), and the rack sliding block (2-3) is meshed with a driven gear (2-4) at one end of a transmission shaft (9).

6. The heating heat dissipation system according to claim 1, wherein: the radiator body (1) is provided with a radiating fin (6) on one side of the air volume amplification device (3), and the radiating fin (6) is internally provided with an air channel radiating fin (6-1) embedded with the air channel and a transmission shaft radiating fin (6-2) embedded with a transmission shaft (9) of the driving device (2).

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