KR960011139B1 - Apparatus for controlling air-conditioner - Google Patents

Abstract

The apparatus optimally controls the energy efficiency of the air-conditioner by using a plurality of thermoelectric elements. The apparatus comprises: a high temperature control means in a warming room mode supplying a current for the thermoelectric elements in order to make the room temperature reache a reference warming room temperature set by a user; a low temperature control means in a cooling room mode supplying a current for the thermoelectric elements in order to make the room temperature reache a reference cooling room temperature also set by the user; a high temperature control means in the cooling room mode rotating a fan, and supplying current for thermoelectric means, installed at ducts, according to the temperature of the air of the ducts.

Description

Energy Efficiency Optimal Control Unit of Air Conditioning and Heating System

1 is a block diagram showing an energy efficiency control apparatus of a conventional heating and cooling system,

2 is an overall block diagram for explaining an energy efficiency optimum control concept in a high temperature part of cooling of the energy efficiency optimum control device according to the present invention;

Figure 3 is a block diagram showing an embodiment of the energy efficiency optimal control device of the heating and cooling system according to the present invention,

Figure 4 is a block diagram showing another embodiment of the energy efficiency optimum control device of the heating and cooling system according to the present invention.

* Explanation of symbols for the main parts of the drawings

100,130: temperature control unit 112: heating

114,152: high temperature section 132: cooling

134: low temperature part 212: optimum control device according to the differential air supply

216: Optimal control device according to the position of thermoelectric element in each duct.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling and heating system using a plurality of thermoelectrics, and more particularly, to an energy efficiency optimal control apparatus for an air conditioning and heating system for optimally controlling a cooling and heating system to increase energy efficiency.

In general, a vehicle is equipped with a heating and cooling system for indoor air conditioning. The air-conditioning system is provided with a plurality of ducts (Duct), which is a vent pipe for passing air supplied from a fan (Fan) and the like, the plurality of ducts are configured in different positions from each other.

FIG. 1 shows a conventional energy efficiency optimum control apparatus in a heating and cooling system. First, with reference to FIG. 1, in the case of heating 112, a temperature control method for the high temperature unit 114 will be described.

When the user arbitrarily sets the reference heating temperature Terf 1 in the high temperature part 114, the temperature sensor 124 detects the current temperature (Treal 1) of the high temperature part in which the thermoelectric element 122 is located, and the subtractor 116. ) Is the difference between the reference heating temperature (Terf 1) preset by the user and the current temperature (Treal 1) of the high temperature part by the thermoelectric element (122), and the corresponding temperature error value (Terror 1 = Tref 1-Treal 1). ) To the controller 118.

The controller 118 provides the driver 120 with a square wave having a pulse width modulated (PWM) corresponding to the temperature error value for each preset time interval until the input temperature error value becomes '0'. do. The driver 120 supplies a predetermined current corresponding to the duty rate of the square wave provided by the controller 118 to the thermoelectric element 122 to finally adjust the heating temperature set by the user. In this case, the control loop forms a closed loop connected to the controller 118, the driver 120, the thermoelectric element 122, and the temperature sensor 124 as shown.

On the other hand, in the case of the cooling 132, the temperature control method for the low temperature unit 134 is the same as the high temperature unit 114 temperature control method for the heating 112 described above, the only difference is that in the case of heating the temperature sensor 124 Although the thermoelectric element 122 is positioned at a high temperature portion, in the case of the cooling 132, the temperature sensor 144 is located at a low temperature portion of the thermoelectric element 122 such that the attachment position of the temperature sensor is different.

Then, in the case of the cooling 132, the temperature control method for the high temperature unit 152 may be performed by a user setting an arbitrary reference cooling temperature Terf 3. The current temperature of the high temperature unit 152 where each thermoelectric element 170 is located may be The temperature sensor 172 senses Treal 3).

Then, the temperature difference between the reference cooling temperature Terf 3 set by the user and the current temperature Trei 3 of the high temperature section in which the thermoelectric element 170 is located is obtained by the subtractor 154 and the temperature error value T error by the multiplier 156. 3 = Tref 3-Treal 3) is multiplied by a constant K having a predetermined gain to extract a revolution per minute (rpmref) representing a revolution per minute.

On the other hand, the speed sensor 168 detects the current speed of the fan 166, the subtractor 158 obtains the error (PRMerror) between the reference speed (RPMref) and the current speed (RPMreal) of the fan 166 the controller 160 To provide.

The controller 160 provides an opening time of the solenoid valve 164 by providing the drive 160 with a control signal for driving the driver 162 for a predetermined time corresponding to this speed error value at predetermined time intervals. Will be adjusted. By controlling the fan speed in the fan speed control unit 213 as described above, the amount of air blown from the fan 166 to the thermoelectric element 170 is controlled, and accordingly, the amount of heat generated in the high temperature portion in which the thermoelectric element 170 is emitted is controlled. You can do it.

However, in the conventional typical air conditioning system operating as described above, the thermoelectrics attached to each duct despite the fact that the amount of air supplied from the fan to each duct is differentially supplied due to the difference in the position of each duct in the case of temperature control of the high temperature part of cooling By flowing the same current through the device, the overheating of the high temperature part may occur, resulting in the reverse flow of heat from the high temperature part to the low temperature part, which may cause a short circuit of the wire, resulting in unnecessary energy consumption. There was a problem.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an energy efficiency optimum control device for optimally controlling the energy efficiency of a cooling and heating system.

An energy efficiency optimum control apparatus for a cooling and heating system according to the present invention includes: a high temperature part temperature control means for heating supplying a current to a thermoelectric element so as to be a predetermined reference cooling temperature set by a user; Cooling low temperature part temperature control means for supplying a current to a thermoelectric element so as to reach a predetermined cooling temperature set by said user; The fan is rotated at a predetermined reference speed so that the cooling temperature set by the user is set to a predetermined reference speed, and a current is supplied to the thermoelectric elements in the respective ducts so that the set cooling temperature is high depending on the temperature in each duct from which the air is supplied. And a high temperature part temperature control means for cooling.

The present invention also provides cooling low temperature part temperature control means for supplying a current to the thermoelectric element so as to be a predetermined reference heating temperature set by the user; The fan is rotated at a predetermined reference speed so that the cooling temperature set by the user is set to a predetermined reference speed, and a current is supplied to the thermoelectric elements in the respective ducts so that the set cooling temperature is high depending on the temperature in each duct from which the air is supplied. And a high temperature part temperature control means for cooling.

The present invention also includes a high temperature part temperature control means for heating for supplying a current to the thermoelectric element so as to be a predetermined reference heating temperature set by a user; Cooling low temperature part temperature control means for supplying a current to the thermoelectric element so as to reach a predetermined cooling temperature set by a user; The user rotates the fan at a predetermined reference speed so as to set a high temperature of cooling, and divides the duct supplied with air from the fan into a predetermined block, and according to the block temperature, And a high temperature part temperature control means for cooling, respectively, for supplying a current to cause a high temperature.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention;

2 is a schematic block diagram showing the overall configuration of the optimum energy efficiency control device of the heating and cooling system according to the present invention, Figure 3 is a block diagram according to an embodiment of the energy efficiency optimum control device according to the present invention in the heating and cooling system As an embodiment, the present invention relates to an energy efficiency optimum control device according to a differential air supply. 4 is a block diagram according to another embodiment of the energy efficiency optimum control device according to the present invention in a cooling and heating system, and relates to an energy efficiency optimum control device 216 according to the position of thermoelectric elements in each duct.

Next, a series of operating processes of the present invention will be described in detail with reference to FIGS. 2 to 4.

First, referring to FIG. 2, in the overall configuration diagram of the present invention, the control method through the temperature control unit 100 of the thermoelectric element high temperature unit 114 in the case of heating, and the temperature control unit 130 of the thermoelectric element low temperature unit 134 in the case of cooling The control method through) is the same as the prior art shown in FIG. 1, so a detailed description thereof will be omitted. Hereinafter, the control through the temperature control unit 210 of the thermoelectric element high temperature unit 152 will be omitted. The method will be described in detail.

The temperature control method of the thermoelectric element high temperature unit 152 can be divided into a control method by the optimum control device 212 according to the differential supply of air amount and a control method by the optimum control device 216 according to the position of the thermoelectric element in each duct. have.

Referring to FIG. 3, the cooling high temperature part 152 is an optimal control system for solving the problems of the prior art caused by the difference in the amount of air flowing into the plurality of ducts. The controller, driver, thermoelectric element, and temperature sensor are each provided with three.

However, it will be appreciated by those skilled in the art that the limiting of the duct and its peripherals to three is based on ease of description and is not intended to limit the present invention.

When the user sets the speed (RPMref 1) of the fan 166 in the high temperature section 152 mode of the cooling 132, the three temperature sensors (temperature sensors 1,2,3) in the temperature sensor section 214g are connected to the duct section. The temperature in 214f is detected respectively, and the difference (Terror 1,2,3) between the temperature (Treal) detected by the three temperature sensors (temperature sensors 1,2,3) and the reference temperature Terf 1 is subtracted. Detected at 214a.

The temperature error values (Terror 1, 2, 3) for each of these ducts (ducts 1, 2, 3) are applied to the controller selector 214b composed of other elements, for example, rotary switches, with a trigger level. The selector 21b sequentially applies the corresponding temperature error values Terror 1,2 and 3 to the controller 214c including the controllers (controllers 1,2 and 3).

The controllers 1, 2 and 3 have a square wave having pulse width modulation (PWM) corresponding to the temperature error values (Terror 1, 2, 3) in the driver unit 214d. 3) to provide each. The drivers 1,2 and 3 transmit a predetermined current corresponding to the duty rate of the pulses provided by the controllers 1 and 2 and 3 and the thermoelectric elements 1 and 2 in the thermoelectric element unit 214e. By supplying to each of 3 and 3, the heating temperature set by the user is finally adjusted.

That is, as described above, by applying a current corresponding to the amount of differential air in each duct to the thermoelectric elements 1,2 and 3, respectively, it is possible to achieve the optimum control to reduce the unnecessary energy to the maximum.

Here, it can be seen that the rotational speed of the fan 166 maintains a constant speed set by the speed fixing part 214h.

4 shows an optimal control system for solving the problems of the prior art caused by the position of the thermoelectric element in the cooling high temperature part by dividing each duct into three blocks as shown and the optimum current supply according to the differential emission of heat in each block. to be.

First, when the user sets the speed RPMref 2 of the fan 166 through the optimum control device 212 according to the above-described differential air supply in the cooling unit 132 and the high temperature unit 152 mode, the speed fixing unit 214h The speed is fixed, and in the temperature sensor unit 216g having three temperature sensors (temperature sensors 1,2 and 3), the temperature corresponding to the block portion 216f having three blocks (blocks 1,2 and 3) is set. Sense At this time, as described above, the duct is divided into blocks having three thermoelectric elements 1,2 and 3.

The difference (Terror 4, 5, 6) between the temperature (Treal 2) and the reference temperature (Terf 1) detected by the three temperature sensors (temperature sensors 1,2 and 3) is detected by the subtractor 216a. The temperature error values (Terror 1,2,3) for 1,2,3 are applied to the controller selector 216b composed of elements having different trigger levels, for example, rotary switches, and the control selector 216b The temperature error values Terror 4, 5, and 6 are sequentially applied to the controller 216c including the controllers (controllers 1, 2 and 3).

The controllers 1,2 and 3 in the controller 216C have a square wave having a pulse width modulated (PWM) corresponding to this temperature error value (Terror 4, 5, 6) in the driver unit 216d. Driver 1,2,3) respectively. The drivers 1,2 and 3 transmit a predetermined current corresponding to the duty rate of the pulses provided by the controllers 1 and 2 and 3 and the thermoelectric elements 1 and 2 in the thermoelectric element unit 216e. By supplying to each of 3 and 3, the heating temperature set by the user is finally adjusted.

Therefore, the optimum current amount corresponding to the differential amount of heat in each block in the duct is supplied to each thermoelectric element, thereby maximizing the emission effect and energy efficiency.

As described above, according to the energy efficiency optimum control device according to the present invention of the air conditioning and heating system, the optimum current corresponding to the amount of air differentially supplied to the duct or the optimal current corresponding to the heat differentially released according to the position of the thermoelectric element in each duct. By supplying the thermoelectric elements respectively, there is an effect that can maximize the emission effect and energy efficiency.

Claims (2)

High temperature part temperature control means of heating for supplying a current to the thermoelectric element so as to be a predetermined reference heating temperature set by a user; Cooling low temperature part temperature control means for supplying a current to a thermoelectric element so as to reach a predetermined cooling temperature set by said user; The fan is rotated at a predetermined reference speed so that the cooling temperature set by the user is set to a predetermined reference speed, and a current is set to cause the set cooling temperature to be high for the thermoelectric elements in the respective ducts according to the temperature in each duct from which the air is supplied. Energy efficiency optimum control device of a cooling and heating system including the temperature control means for supplying the hot portion of cooling. High temperature part temperature control means of heating for supplying a current to the thermoelectric element so as to be a predetermined reference heating temperature set by a user; Cooling low temperature part temperature control means for supplying a current to a thermoelectric element so as to reach a predetermined cooling temperature set by said user; The user rotates the fan at a predetermined reference speed so as to set a high temperature of cooling, and divides the duct to which air is supplied from the fan into a predetermined block, and the thermoelectric elements respectively formed in the blocks of each duct according to the block temperature. An energy efficiency optimum control device for a cooling and heating system, comprising a cooling hot portion temperature control means for supplying a current for causing the set cooling temperature to be high.