KR100918622B1 - Energy saving type air conditioner using turbulence and control method thereof - Google Patents

Abstract

PURPOSE: An energy-saving type air-conditioner using the turbulence and a control method thereof are provided to prevent the stratification of temperature by supplying the layered air after mixing by controlling a jet fan. CONSTITUTION: An energy-saving type air-conditioner using the turbulence comprises a suction part(1), an air mixture part(2), a heat exchanger(3), and an exhausting part(4). The suction part has a suction blower(12). A suction sending part inhales the indoor air. The part of indoor air inhaled by the suction part is ejected to out. The rest of the indoor air is mixed with the newly inhaled air by the air mixture part. The heat exchanger exchanges the heat of the air supplied from the air mixture part at a heat exchanger(31). The exhausting part has a discharging blower(42).

Description

Energy saving type air conditioner using turbulence and its control method {Energy saving type air conditioner using turbulence and control method

The present invention relates to an energy-saving air conditioner using turbulent flow, and a control method thereof. Specifically, the present invention relates to a recycled indoor air flowing from a bypass damper that supplies indoor air to a heat exchanger by generating turbulence by blowing a jet fan. The present invention relates to an air conditioner and a control method of improving heat exchange efficiency of a heat exchanger by mixing newly introduced outdoor air to prevent temperature stratification.

An air conditioner controls the temperature, humidity, airflow, and cleanliness of the air sent to the room to create a pleasant indoor environment.It is divided into small or large capacity according to the installation location and cooling / heating capacity. Large capacity is used for large buildings such as buildings or factories.

Such a large-capacity air conditioner performs cooling or heating by repeated cycles of forced suction of indoor air, heat exchange to high or low temperature, and reduction back to the room.

7 is a block diagram showing an embodiment of a conventional air conditioner, as shown, the conventional large-capacity air conditioner is a suction unit (1), air mixing unit (2), heat exchange along the fluid (air) flow direction The part 3 and the discharge part 4 are comprised in the case 5, and arranged in order. At this time, the space portion into which air is introduced or discharged is divided by the isolation frame.

The suction part 1 is formed at one side of the upper part of the case 5 and is connected to the room by an indoor air suction port 11 through which the return air (RA) is sucked. The suction blower 12 which sucks indoor air into the apparatus is provided. The suction blower sucks the indoor air to one side and discharges the indoor air to the air mixing unit on the other side by the rotation of the centrifugal fan. There may be various driving methods of the suction blower 12. For example, the suction fan 12 includes a centrifugal fan and a fan motor for driving the centrifugal fan. The centrifugal fan and the fan motor are connected by belts and belt cars. It is not an important part, but because it is a general known technique, reference numerals and detailed description thereof will be omitted.

In addition, the suction part 1 is configured such that the space part is separated from the air mixing part 2 by the isolation frame 61 so that only the outlet of the suction blower 12 communicates with the air mixing part.

The air mixing part 2 is divided into a part in which the suction part 1 is in contact with a heat exchange part 3 in contact with the isolation frame 62 in which the bypass damper 21 is installed. The upper part of the case (5) in contact with the part (1) is provided with an indoor air outlet 21 through which a part of the indoor air introduced from the suction part 1 is discharged, and the case of the part in contact with the heat exchange part 3 ( 5) On the upper side, an outdoor air inlet 23 through which fresh air is introduced is formed. Typically, about 30% of indoor air goes out through the indoor air outlet 21, and the remaining 70% of indoor air is mixed with 30% of outdoor air in the space part in contact with the heat exchanger through the bypass damper 21, thereby exchanging heat exchanger. It is supplied to (3).

The heat exchange part (3) is a coil-shaped heat exchanger (31) for exchanging mixed air mixed with a predetermined amount of indoor air and a predetermined amount of outdoor air introduced from the air mixing unit and the mixed air installed in front of the heat exchanger. It consists of an air filter 32 to remove contaminants.

In the heat exchange, the indoor air is cooled or heated by being connected to a heat pump installed outdoors to cool or heat up the introduced mixed air. Specifically, it includes a means for supplying a refrigerant or a cold or hot water that is a heat medium flowing through the internal flow path of such a heat exchanger, which has a variety of ways depending on the type of air conditioner. Since the specific method is a known technique, a detailed description thereof will be omitted.

One example is the heat pump method. The heat pump type may use either a heat pump such as EHP using electricity or GHP using gas. Since the EHP or GHP method is a well-known technique, a detailed description thereof will be omitted.

Finally, the discharge part 4 has an air outlet 41 for supplying heat-exchanged air in communication with the interior of the building on the case 5, the discharge blower 42 for forcibly discharging the heat-exchanged air 42 It consists of). At this time, the discharge blower 42 is composed of a centrifugal fan and a fan motor for driving the centrifugal fan as described in the suction blower, the centrifugal fan and the fan motor are connected by a belt and a belt car. Similarly, since it is a known technique, reference numerals and descriptions thereof will be omitted.

Referring to the cooling (heating process is also the same) of the large-capacity air conditioner having the above configuration is as follows.

First, when the suction blower 12 is driven, air in the building interior is introduced into the suction unit 1, and the introduced air passes through the air mixing unit 2 while about 30% of the air is indoor air outlet 22. It is discharged to the outside through the outside, on the contrary, the outdoor air inlet 23 flows toward the heat exchange unit 3 in a state mixed with about 70% of the in-flight air remaining in the air.

After the impurities are filtered through the air filter 32, the air introduced into the heat exchange part 3 is heat-exchanged at low temperature while passing through the heat exchanger 31 installed at the rear of the air filter 32.

The cold air heat-exchanged as described above is repeatedly reduced into the building through the heat exchange air outlet 41 installed on the case 5 by the rotational force of the discharge blower 42 installed inside the discharge unit 4. Cooling is achieved

However, the conventional air conditioner has a structural disadvantage that the heat exchange efficiency of the heat exchanger 31 is deteriorated by forming a stratification without mixing the mixed air supplied from the air mixing unit 2 to the heat exchange unit 4 well. have. When such temperature stratification occurs, the air conditioner increases the output of the heat pump circulating the heat medium in the heat exchanger to adjust the temperature of the air flowing into the room to the set temperature, thereby leading to an overload condition. There is a problem of lowering and lowering energy efficiency.

The problem caused by the temperature stratification as described above will be described in more detail with reference to FIG. 8. As shown, the airflow of cold air and hot air passing through the bypass damper of the conventional air conditioner is the bypass damper 21 formed at the center of the isolation frame 62 by the indoor air introduced into the air mixing part 2. Is introduced through the fresh air supplied from the upper outdoor air inlet 23 by the blowing force of the suction blower 12 or the suction blower 42 of the discharge blower 42 formed in the discharge portion 4 before rising to the upper portion Before the air is sufficiently mixed with the outdoor air, it reaches the heat exchanger 31 via the air filter 32 of the central heat exchanger 3,

In addition, the outdoor air flowing into the upper outdoor air inlet 23 reaches the heat exchanger 31 through the air filter 32 of the heat exchanger 3 through the upper side before descending to the lower side.

When indoor air and outdoor air, which maintains most of the unmixed temperatures, are separated and reach the heat exchanger, the heat exchanger performs high efficiency heat exchange in some sections, but low efficiency heat exchange in some sections. do.

In addition, if this situation persists, the heat exchanger will lose mechanical durability due to the difference in temperature up and down, and the heat medium supply means (for example, the heat pump) will have to increase the power to supply the heat medium more quickly, resulting in greater energy loss. The same applies to the case where cold / hot water is used as the heat medium without using the refrigerant as the heat medium.

It will be described below on the basis of the winter heating time of the air conditioner having a structural problem by the temperature stratification as described above.

After heating the room in winter, the hot air returned through the indoor air inlet 11 is introduced through the bypass damper 21 of the air mixing unit 2, and immediately reaches the heat exchanger 31, and the air mixing The outdoor cold air introduced into the outdoor air inlet 23 of the unit 2 reaches the heat exchanger 31 via the air filter 32 of the heat exchanger 3 through the upper side without descending to the lower side. In this case, the reason why the cold upper outdoor air and the lower indoor air are not mixed is due to the blowing force of the suction blower 12 or the suction force of the discharge blower 42 formed in the discharge unit 4 as described above. This is because the air heat exchanger 31 reaches the heat exchanger 31 via the air filter 32 of the central heat exchanger 3 before being sufficiently mixed with the fresh air supplied from (23). This causes the problem described above.

In addition, after cooling the room in the summer, the cool air returned through the indoor air inlet 11 is introduced through the bypass damper 21 of the air mixing unit 2, and immediately reaches the heat exchanger 31. The outdoor hot air introduced into the outdoor air inlet 23 of the mixing unit 2 reaches the heat exchanger 31 through the air filter 32 of the heat exchange unit 3 through the upper side without descending downward. . In this case, the reason why the hot air is not mixed with the outdoor air in the upper part is the same as the reason for the winter.

An object of the present invention for solving the above problems is to measure the temperature of the hot air and cold air supplied to the heat exchanger side of the air conditioner and then control the jet fan to supply a mixture of laminarized air flow An air conditioner for preventing stratification and a control method thereof are provided.

Another object of the present invention is to measure the temperature of hot air and cold air supplied to the heat exchanger side of the air conditioner, and then control the jet fan to mix the flow of laminarized air, when the jet fan is positioned up and down and measured The present invention provides an air conditioner and a control method for preventing stratification of temperature by adjusting and supplying a blowing amount of upper and lower jet fans according to the temperature.

Another object of the present invention is to measure the temperature of hot air and cold air supplied to the heat exchanger side of the air conditioner and then control the jet fan to supply a mixture of laminarized air flow, turbulence generator at the front end of the jet fan It is to provide an air conditioner and a control method for preventing the stratification of temperature by maximizing the occurrence of turbulence by installing a.

  Another object of the present invention is to control the jet fan after measuring the temperature of the hot air and cold air supplied to the heat exchanger side of the air conditioner to mix the flow of laminarized air, the jet fan is placed up and down The present invention provides an air conditioner and a control method for preventing stratification of temperature by maximizing the generation of turbulence by intermittently blowing the air volume of the upper and lower jet fans according to the measured temperature.

The present invention to achieve the object as described above and to perform the problem for eliminating the drawbacks of the prior art comprises: a suction unit having a suction blower for sucking the indoor air; An air mixing part for discharging some of the indoor air sucked through the suction part and mixing the remaining air with the newly introduced outdoor air; A heat exchange part for heat-exchanging the air supplied from the air mixture part at a low or high temperature in the heat exchanger; In the air conditioner comprising a discharge unit having a discharge blower for reducing the heat-exchanged air to the room;

A jet fan installed at upper and lower sides of the air mixing part to generate turbulence by suction and blowing; A temperature sensor installed to measure a temperature of air flowing into the heat exchanger; A controller for controlling the operation, blowing angle and blowing intensity of the jet fan according to the temperature input from the temperature sensor and a power supply for supplying power to the jet fan; achieved by providing an energy-saving air conditioner using turbulence configured further do.

The jet fan is characterized in that configured to generate turbulence by the load difference by installing a turbulence generator on the discharge side.

The turbulence generator is an energy-saving air conditioner using turbulence, characterized in that a plurality of turbulent pieces having different areas or sizes are formed on the frame formed to be arranged up and down or left and right.

The jet fan installed above and below the air mixing unit is characterized in that the jet fan is installed below the outdoor air inlet through which the outdoor air flows and the jet fan installed below the bypass damper through which the indoor air flows.

The angle adjustment of the jet fan is configured to rotate at a predetermined angle by a stepper motor formed with a circular gear formed on one side of each jet fan installed on the hinge bracket and the shaft gear meshing with the circular gear, the cylinder type on the other side of the jet fan It is characterized in that it is configured to support by installing the ABS.

The temperature sensor is installed at the front or rear end of the air filter to measure the temperature of the air flowing into the heat exchanger, one or more installed in the vertical direction to one or more support frames, characterized in that configured to measure the upper and lower temperatures or the temperature of the upper and lower left and right It is done.

The controller receives the real-time temperature information from one or more temperature sensors to the step motor for rotating the angle of the jet fan to the blowing target point when out of or within the preset temperature range of the fan motor and the fan motor for rotating the blowing fan. It is characterized in that the operation is configured to control each.

In another aspect, the present invention is a control method of the energy-saving air conditioner using the turbulence,

Measuring a temperature of air introduced by a plurality of temperature sensors in real time;

Receiving, by the controller, temperature information from the plurality of temperature sensors;

Controlling the jet fan to operate when the controller deviates from the preset temperature range after analyzing the received temperature information;

 The controller may be configured to control the jet fan to stop when the temperature is within a preset temperature range after analyzing the received temperature information. The method may be achieved by providing a control method of an energy-saving air conditioner using turbulence.

The step of controlling the jet fan to be operated or stopped is a step of controlling the angle and blowing by operating or stopping the step motor for rotating the angle of the jet fan to the blowing target point and the fan motor for rotating the blowing fan. It features.

The present invention detects the laminar flow of air by measuring the temperature between the hot air and cold air supplied to the heat exchanger side of the air conditioner, and then mixed by the blowing of the jet fan to prevent the stratification of the temperature to the heat medium The advantage of increasing the energy efficiency of the heat exchanger of the air conditioner using the refrigerant or cold and hot water,

In addition, when hot air and cold air supplied to the heat exchanger side of the air conditioner are supplied in laminar flow, a controller that senses the temperature from a plurality of temperature sensors installed in real time detects this and operates a jet fan when the temperature difference is large. By controlling the temperature of the air supply, the laminar flow of the air that is not mixed with each other is destroyed, causing turbulent flow. The evenly mixed air is supplied to the heat exchanger to prevent temperature stratification, thereby increasing the energy efficiency of the heat exchanger constituting the air conditioner and The advantage of increased durability by preventing the durability of the heat exchanger due to the difference,

In addition, by placing a turbulence generator at the front end of the jet fan to blow another laminar flow that can be generated by the jet fan to increase the turbulence generation efficiency,

In addition, the jet fan is positioned up and down, and the airflow of the upper and lower jet fan is adjusted according to the temperature measured from the temperature sensor arranged up, down, up, down, left and right to increase the turbulence generation efficiency,

In addition, it is a useful invention having the advantage of maximizing the generation of turbulence by intermittently blowing when adjusting the blowing amount of the upper and lower jet fan in accordance with the measured temperature by placing the jet fan up and down is an invention that is expected to be used in industry.

Hereinafter, the configuration and the operation of the embodiment of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a block diagram showing an embodiment of an air conditioner according to the present invention, Figure 2 is a block diagram showing a control structure according to the present invention, Figure 3 is a jet fan having a turbulent piece according to the present invention Is a cross-sectional configuration diagram.

As shown in the present invention, the basic configuration of a general air conditioner includes a suction part 1, an air mixing part 2, a heat exchange part 3, and a discharge part 4 along a fluid (air) flow direction. (5) A structure is arranged and arranged inside. At this time, the space portion into which air is introduced or discharged is divided by the isolation frame.

Specifically, the suction part 1 is formed at one side of the upper part of the case 5 and is connected to the room by an indoor air inlet 11 through which the returned air (RA) is sucked, The suction blower 12 which sucks indoor air into an apparatus is provided inside. The suction blower sucks the indoor air to one side and discharges the indoor air to the air mixing unit on the other side by the rotation of the centrifugal fan. In addition, the suction part 1 is configured such that the space part is separated from the air mixing part 2 by the isolation frame 61 so that only the outlet of the suction blower 12 communicates with the air mixing part.

The air mixing part 2 is divided into a part in which the suction part 1 is in contact with a heat exchange part 3 in contact with the isolation frame 62 in which the bypass damper 21 is installed. On the upper side of the case (5) in contact with the part (1), an indoor air outlet 21 through which some air (EA) is discharged from the indoor air introduced from the suction part 1 is installed, and the heat exchange part 3 On the upper side of the case (5) of the contact portion) is formed an outdoor air inlet (23) through which fresh outdoor air (OA) is introduced. In addition, the bypass damper 21 of the present invention is configured to facilitate the mixing action by using a longer one up and down than the conventional one so as to improve the flow of air more introduced.

The heat exchange part (3) is a coil-shaped heat exchanger (31) for exchanging mixed air mixed with a predetermined amount of indoor air and a predetermined amount of outdoor air introduced from the air mixing unit and the mixed air installed in front of the heat exchanger. It consists of an air filter 32 to remove contaminants.

Finally, the discharge part 4 has an air outlet 41 for supplying heat-exchanged air communicating with the interior of the building on the case 5, forcibly discharging the heat-exchanged air (SA) The discharge blower 42 which consists of these is comprised.

The present invention has a basic configuration of the air conditioner as described above, in order to prevent the temperature stratification of the heat exchanger 31, the bypass damper 21 and the outdoor air inlet (2) into which the indoor air of the air mixing unit 2 is introduced. Jet fans 7a and 7b were provided below the outdoor air inlet 23 and below the bypass damper 21 so as to blow air to the air supplied from 23 to generate turbulent flow. As such, by installing and blowing the air so as to cover only outdoor and indoor air, it was most effective in preventing laminar flow of the introduced air.

Jet fan (7a, 7b) installed on the top or bottom was configured to rotate by forming a hinge bracket (71a, 71b) on the bottom of the isolation frame 62 or the case (5), respectively. At this time, the hinge bracket (71a) installed on the upper side was protruded first from the isolation frame (62) and then protruded to the bottom to configure the 'T' shaped hinge bracket (71a), the hinge bracket (71b) installed on the bottom The hinge bracket protrudes upward.

The angle conversion of the jet fans 7a and 7b installed in the hinge brackets 71a and 71b is performed by circular gears 72a and 72b formed on one side of each jet fan and shaft gears 73a and 73b meshing with the circular gears. It was configured to rotate at a predetermined angle by the step motor (74a, 74b) is formed.

In addition, in order to stably support the rotational movement of the jet fan according to the angle conversion, the cylinder type Absorba (75a, 75b) formed on the other side of the jet fan was installed to support. When the piston moves in a cylinder, the piston linearly moving in the cylinder is increased or decreased by the rotation of the jet fan, and one side of the piston inserted into the groove (79a, 79b; see FIGS. 4 and 5) on the other side of the jet fan is grooved ( 79a, 79b) to linearly move while sliding in the intermittent state to cope with the angle change of the jet fan.

The reason why the jet fan 7 is used in the present invention is that the suction force inside the air through the inlet port located at the rear is discharged through the outlet port, so that the conveying power of the air passing through the outlet port in the tubular structure can be maximized. Because it can enhance the action. If a general blower is used, the suction force is weak compared to the blowing force, and thus it is not very efficient in terms of air circulation. That is, when the fan 76a, 76b installed inside the jet fan rotates by the rotation of the fan motors 77a, 77b, the flow rate is increased, so that the inner flow rate is faster than the air flow around the jet fan, like a kind of bernoulli tube. As the suction force is increased, the degree of mixing of air is increased by mixing air by suction and mixing by discharge.

In addition, in the jet fan of the present invention, turbulence generators 78a and 78b are installed at the discharge port, and the air is discharged to be turbulent to mix the flow of air supplied to the laminar flow more efficiently.

Another laminar flow may be achieved if it is composed only of a general jet fan, but the present invention is configured to have a turbulence generator on the outlet side, so that the discharged air is turbulent to mix the flow of air having different temperatures more quickly.

The turbulence generators 78a and 78b have a structure in which a plurality of turbulent pieces 782a and 782b having different areas or sizes are arranged on the frames 781a and 781b which are arranged vertically or horizontally. Turbulence caused by That is, the load difference occurs between the side and the side where the turbulent piece is not formed and the high and low side of the turbulent piece depending on the load, resulting in irregular air flow.

In addition, the temperature sensor 8 is installed at the front or rear of the air filter 32 to measure the temperature of the air flowing into the heat exchanger 31 to control the driving time of the jet fan. At this time, a plurality of temperature sensors 8 are installed in a vertical arrangement by one or more support frames 81 installed vertically up and down as shown. In addition, in order to increase the reliability of the temperature measurement, it is possible to configure not only the vertical arrangement but also the supporting frame 81 in the horizontal direction to measure the area including the horizontal arrangement.

The temperature sensor installed as described above measures the temperature of the indoor air supplied through the bypass damper 21 and the temperature of the outdoor air supplied through the outdoor air inlet 23 and then measured by the controller 9 shown in FIG. 2. Output temperature information. At this time, the information may be a temperature sensor that directly sends a digital signal, but if it is a temperature sensor that detects an analog signal, the information may be converted into a digital signal through an AD converter and transmitted.

If the temperature difference between the two air flowing from the indoor side and the outdoor side is large, and also by the suction power of the blower of the suction blower 12 or the discharge blower 42 formed in the discharge portion 4 in the upper outdoor air inlet (23) If the temperature reaches the heat exchanger 31 through the air filter 32 of the central heat exchanger 3 before sufficiently mixing with the supplied fresh outdoor air, the temperature measured by the temperature sensor 8 installed at different heights is arranged up and down. Will have different temperatures.

In other words, the difference in temperature of the temperature sensor means that the incoming air is supplied with a certain laminar flow. In this case, the heat exchanger performs high efficiency heat exchange in some sections, but performs low heat exchange in some sections. It tells you that you will be in a falling state.

The controller 9 receives the information of the temperature sensor 8 installed and arranged in plural according to the internally set procedure in real time, and if the upper and lower temperature difference is out of the set temperature range, the controller 9 operates the jet fan to protect the efficiency and durability of the heat exchanger. Will be adjusted.

The set temperature range can be set properly according to the working environment. For example, after collecting the temperature of a plurality of temperature sensors, the temperature difference between the temperature sensor in a certain area and the adjacent temperature sensors can be operated if it is 10 degrees or more, or if it is 5 degrees or more, it can be operated. If it is higher than it can work. Likewise, when the jet fan is in operation, the temperature difference between the temperature sensor in a certain area and the adjacent temperature sensors can be stopped when the temperature is less than 10 degrees, and when it is below 5 degrees, the operation can be stopped. If it is less than 15 degrees, it may stop working. That is, according to the temperature information from the temperature sensor, the operation and shutdown are actively and appropriately actively controlled.

2, the angle control method of the jet fan of the present invention according to the controller 9 will be described in more detail.

The controller 9 receives the temperature information in real time from a plurality of temperature sensors, and if a temperature outside the set temperature range is detected, the step motor 74a for adjusting the angle of the jet fan toward the area where the temperature sensor with a large temperature is located, Rotate 74b). That is, between the power supply 10 and the stem motor which apply power to the step motor 74a, 74b, it is energized.

At the same time, power is supplied through the power supply 10 connected to the fan motors 77a and 77b installed in the jet fan to rotate the fan motor to rotate the fans 76a and 76b connected thereto.

As such, when the angle of the jet fan is adjusted and the fan rotates, the air of the jet fan is supplied near the set temperature sensor to destroy the laminar flow between the air supplied to the laminar flow.

Of course, the air supplied at this time further accelerates the mixing of the laminar air by supplying turbulence by the turbulence generator.

In another aspect, the present invention can be configured to control the rotation of the fan motor with different angles to the jet fan that is adjusted up and down by the controller.

In other words, when the air flows in the horizontal direction through the central part and the outside air discharged from the upper part are mixed, the temperature difference between the upper part and the lower part may occur due to the mixing of the upper part and the lower part. As a result, the fan motor of the upper part is rotated more strongly to blow the fan toward the lower side, or vice versa, the fan motor of the lower part can be rotated more strongly to enhance the mixing of the temperature, thereby achieving leveling of the temperature.

In addition, the controller 9 of the present invention may be wired or wirelessly connected to the step motors 74a and 74b or the fan motors 77a and 77b as necessary, such as an installation place. In the case of wireless, there is provided a wireless transmission and reception device, such a configuration is a conventional technology and a detailed description thereof will be omitted. In addition, shifting or transformer related device configurations for increasing or decreasing the rotational speed of the step motors 74a and 74b or the fan motors 77a and 77b in which the controller 9 of the present invention is connected to a power supply are also conventional techniques. Description is omitted. The essence of the present invention is that the step motors 74a and 74b or the fan motors 77a and 77b are controlled by the controller 9.

Figure 4 is an exemplary view showing the operation of the lower jet fan according to the present invention, Figure 5 is an exemplary view showing the operation of the upper jet fan according to the present invention, when the shaft gear is rotated by the rotation of the step motor as shown As the circular gears 72a and 72b formed on one side of the interlocking jet fan rotate, the angles of the jet fans 7a and 7b hinged to the hinge brackets 71a and 71b are adjusted. At the same time, the angle of the absorber is changed to keep the angles of the jet fans 7a and 7b stable. At this time, the piston of the Absorba stably supports the rotation of the jet fan while linearly moving in the grooves 79a and 79b formed on the other side of the jet fan.

6 is an exemplary view showing the air flow of cold air and hot air of the air conditioner according to the present invention. As shown, the indoor air introduced into the air mixing unit 2 is introduced through the bypass damper 21 formed long in the center of the isolation frame 62. As described above, the temperature difference is caused by the air laminarly flowed. When generated, the temperature by the temperature sensor 8 is output to the controller 9, and the controller rotates the step motors 74a and 74b for adjusting the angle of the control fan and the fan motor 77a for rotating the fans 76a and 76b. , 77b) to control the control fan.

Accordingly, the upper part of the introduced air, that is, the portion where fresh outdoor air supplied from the upper outdoor air inlet 23 is introduced, is discharged from the jet fan 7a or the jet fan 7a to which the turbulence generator 78a is attached. After the air becomes turbulent by breaking the laminar flow, the turbulent indoor air meets the outdoor air, and the indoor air is turbulent and mixed again to prevent the stratification of the temperature as the temperature between the two air changes to an intermediate temperature.

In addition, the turbulent mixed air or the turbulent indoor air is further turbulent by the air discharged from the jet fan 7b supplied from the lower side or from the jet fan 7b having the turbulence generator 78b attached thereto. The effect of the mixing is shown to be mixed while reducing the temperature difference between each other.

Then, the mixed air reaches the heat exchanger 31 via the air filter 32 of the heat exchanger 3 by the blowing force of the suction blower 12 or the suction force of the discharge blower 42 formed in the discharge part 4. do.

In this way, when the mixed air forcibly mixed due to the turbulence generation and stratification due to the temperature difference does not occur, the heat exchanger reaches the heat exchanger, it is contacted at a uniform temperature over the entire area of the heat exchanger to exchange heat with high efficiency.

Accordingly, the mechanical durability of the heat exchanger is maintained, and the means for supplying a heat medium such as cold / hot water or a refrigerant into the heat exchanger, for example, a heat pump and a heat medium supply means, supplies a heat medium at a normal speed, thereby increasing energy efficiency. .

The operation of the air conditioner having a structure that prevents temperature stratification by installing the turbulence generator as described above will be described below with reference to winter heating.

After heating the room in winter, the hot air returned through the indoor air inlet 11 of the suction unit 1 passes through the indoor air outlet 22 formed at the upper portion of the hot air before passing through the bypass damper of the mixing unit 2. After discharging the indoor air, the fresh air is supplied through the bypass damper 21 extending to the upper portion into which the fresh cold outdoor air supplied from the upper outdoor air inlet 23 is introduced. The introduced indoor air is turbulent due to irregular mixing due to the discharged air by operating the jet fans 7a and 7b by controlling the controller which receives the temperature information from the temperature sensor. The turbulent indoor air collides with the cold outdoor air supplied from the outdoor air inlet 23, and the two air streams are mixed by the turbulent action so that there is no temperature difference, and also mixed with the indoor air in the downward direction by the jet fan again. After passing through the air filter 32 in a state of preventing the stratification of the temperature, the heat exchanger 31 of the heat exchanger 3 reaches the heat exchanger 31 evenly and uniformly at a uniform temperature to exchange heat with high efficiency.

In addition, in the summer, after cooling the room, the cold air returned through the indoor air intake port 11 discharges a predetermined amount of indoor air through the indoor air outlet 22 formed in the upper portion before passing through the bypass damper of the mixing section 2. After that, the hot outdoor air supplied from the upper outdoor air inlet 23 is introduced through the bypass damper 21 extending to the upper portion into which the fresh air is introduced. The introduced indoor air is turbulent by the jet fans 7a and 7b. The turbulent indoor air collides with the hot outdoor air supplied from the outdoor air inlet (23), and the two air streams are mixed by the turbulent action so that there is no temperature difference. After passing through the air filter 32 to prevent temperature stratification, the mixture reaches the heat exchanger 31 of the heat exchanger 3, and evenly contacts the entire surface of the heat exchanger at a uniform temperature to exchange heat with high efficiency.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a block diagram showing an embodiment of an air conditioner according to the present invention,

2 is a block diagram showing a control structure according to the present invention;

3 is a cross-sectional configuration of a jet fan having a turbulence piece according to the present invention,

Figure 4 is an exemplary view showing the operation of the lower jet fan according to the present invention,

5 is an exemplary view showing the operation of the upper jet fan according to the present invention,

Figure 6 is an exemplary view showing the air flow of cold air and hot air of the air conditioner according to the present invention,

7 is a block diagram showing an embodiment of a conventional air conditioner,

8 is an exemplary view showing the air flow of cold air and hot air passing the bypass damper of the conventional air conditioner.

<Description of the symbols for the main parts of the drawings>

(1): suction part (2): air mixing part

(3): heat exchange part (4): discharge part

(5): Case (7a, 7b): Jet Fan

(8): Temperature sensor (9): Controller

(10): power supply (12): suction blower

21: bypass damper 31: heat exchanger

42: discharge blower 62: isolation frame

(71a, 71b): Hinge bracket (72a, 72b): round gear

(73a, 73b): shaft gear (74a, 74b): step motor

(75a, 75b): Absorber (76a, 76b): Fan

(77a, 77b): fan motor (78a, 78b): turbulence generator

(79a, 79b): Groove (81): support frame

(781a, 781b): frame (782a, 782b): turbulent flight

Claims (9)

A suction part 1 having a suction blower 12 for suctioning indoor air; An air mixing part 2 for discharging some of the indoor air sucked through the suction part 1 and mixing the remaining air with the newly introduced outdoor air; A heat exchanger 3 for heat-exchanging the air supplied from the air mixing unit to a low temperature or a high temperature in the heat exchanger 31; In the air conditioner, the discharge unit having a discharge blower 42 for reducing the heat-exchanged air into the room; Jet fans 7a and 7b installed at upper and lower sides of the air mixing unit 2 to generate turbulence by suction and blowing; A temperature sensor 8 installed to measure the temperature of the air flowing into the heat exchanger 31; A power supply for supplying power to the controller 9 and the jet fans 7a and 7b for controlling the operation, the blowing angle and the blowing intensity of the jet fans 7a and 7b according to the temperature input from the temperature sensor 8 ( 10); energy-saving air conditioner using turbulence, characterized in that further comprises. The method according to claim 1, The jet fan (7a, 7b) is an energy-saving air conditioner using turbulence, characterized in that the turbulence generator (78a, 78b) on the outlet side is configured to generate turbulence by the load difference. The method according to claim 2, The turbulence generators 78a and 78b have turbulent flows characterized in that a plurality of turbulent pieces 782a and 782b having different areas or sizes are formed on the frames 781a and 781b which are arranged vertically or horizontally. Energy-saving air conditioner using. The method according to claim 1, The jet fans 7a and 7b provided at the upper and lower portions of the air mixing unit are disposed below the bypass damper 21 into which the jet fan 7a and the indoor air are installed, which are installed below the outdoor air inlet 23 through which the outdoor air is introduced. Energy saving type air conditioner using turbulent flow, characterized in that consisting of a jet fan (7b) installed. The method according to claim 1, The angle adjustment of the jet fan (7a, 7b) is a circular gear (72a, 72b) formed on one side of each jet fan installed on the hinge bracket (71a, 71b) and the shaft gear (73a, 73b) meshing with the circular gear Energy formed using turbulence, which is configured to rotate at a predetermined angle by the formed stepper motors 74a and 74b, and is configured to support the cylinder type Absorbers 75a and 75b on the other side of the jet fans 7a and 7b. Economy air conditioner. The method according to claim 1, The temperature sensor 8 is installed at the front end or the rear end of the air filter 32 to measure the temperature of the air flowing into the heat exchanger 31, at least one is installed in the vertical direction to at least one support frame 81 Energy saving type air conditioner using turbulence, characterized in that configured to measure the temperature of the upper and lower or upper and lower left and right. The method according to claim 1, The controller 9 receives the temperature information in real time from one or more temperature sensors 8 to rotate the angles of the jet fans 7a and 7b to the blowing target point when the temperature is out of the preset temperature range or within the temperature range. An energy-saving air conditioner using turbulent flow, characterized in that the operation of the fan motors (77a, 77b) for rotating the motor (74a 74b) and the blowing fan (76a, 76b) is configured to control. In the control method of the air conditioner according to any one of claims 1 to 7, Measuring a temperature of air introduced by a plurality of temperature sensors in real time; Receiving, by the controller, temperature information from the plurality of temperature sensors; Controlling the jet fans 7a and 7b to be operated when the controller deviates from the preset temperature range after analyzing the received temperature information; The controller controls the jet fan (7a, 7b) is stopped when the temperature is within the preset temperature range after the received analysis of the received temperature information; control method of energy-saving air conditioner using turbulence, characterized in that it further comprises . The method according to claim 8, The controller may control the jet fans 7a and 7b to be operated or stopped. The step motor 74a 74b rotates the angle of the jet fan to the blowing target point and the fan motor rotates the blowing fans 76a and 76b. Control method of energy-saving air conditioner using turbulence, characterized in that the step of operating or stopping (77a, 77b) to control the angle and blowing.

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