KR940010401B1 - Electronic temperature controller - Google Patents

Abstract

The electronic thermostat includes a mode setting unit for setting a cooling or a heating mode according to the temperature of a supplying path; a room temperature detector; a first controller for circulating the cooling or heating material along the supplying path; and a second controller for cutting off the supply of the cooling or heating material if a detected room temperature exceeds a reference temperature of a corresponding mode.

Description

Electronic temperature controller for local cooling and heating control that can be switched to summer and winter mode automatically

1 is a view showing an example of the configuration of a local air conditioning control device having a conventional mechanical temperature controller and mechanical summer and winter mode switching switch.

2 is a view showing an example of the configuration of the local cooling and heating control device having an electronic thermostat according to the present invention.

3 is a circuit diagram showing a specific configuration example of the electronic temperature controller according to the present invention.

The present invention relates to an electronic temperature controller in a cooling and heating control apparatus, and more particularly, to a regional temperature controller for cooling and heating in which summer and winter operation methods are automatically switched.

1 shows an example of the configuration of a conventional regional air conditioning and heating control device, the configuration and operation of which are as follows. By installing a thermostat (1) using a diaphragm indoors to detect the room temperature. In addition, the sensor 3 is attached on the pipe P to sense the temperature of the pipe P for supplying cooling and heating materials, for example, cold and hot water. The temperature controller 1 is connected to a mode switching switch 2 having a contact point so as to switch to a summer or winter mode according to the temperature of the pipe P. In addition, a fan switch 9, a fan motor 10, a valve 4, a valve driving motor M, a minimum flow rate bypass 8, and a cooling and heating coil 7 are provided.

First, a case of visiting in the summer will be described. If the temperature of the supply pipe P is below a constant temperature, the contacts E and F of the mode switching switch 2 are connected. Here, the constant temperature is a boundary temperature for distinguishing the summer mode and the winter mode, hereinafter referred to as a first reference temperature for convenience. On the other hand, when the temperature in the room rises above the second reference temperature set by the temperature controller 1, the contacts B and C of the temperature controller 1 are connected. As a result, the power is supplied to the valve driving motor (M) to open the valve (4), so that the cold water flows through the supply pipe (P) to lower the temperature of the room. On the other hand, when the temperature of the room becomes lower than the second reference temperature in this way, the contact connection state of the temperature control 1 is switched. That is, the contacts A and C are connected to shut off the power supply Vcc supplied to the valve driving motor M to close the valve 4 so that no cold water can flow.

Next, the case of heating in winter will be described. If the temperature of the supply pipe P is higher than the above-mentioned first reference temperature, the contacts D and F of the mode switching switch 2 are connected. In addition, when the indoor temperature is lower than the third reference temperature set in the temperature controller 1, the contact points A and C of the temperature controller 1 are connected to supply power to the valve driving motor M, so that the valve 4 is opened. The hot water flows through the valve 4 to enable heating. Thereafter, when the temperature of the room is increased to be higher than the third reference temperature, the contact point of the temperature controller 1 changes its connection state, that is, the contact point B and C are switched to be connected to the valve driving motor M. By shutting off the power supply Vcc, the valve 4 is closed to block hot water so that the temperature of the room is no longer increased.

However, as mentioned above, the regional cooling and heating control device has a separate configuration of the temperature controller and the mode switching switch, so it is not necessary to additionally connect the two products at the time of construction. It had the disadvantage of being impossible. In addition, when the mode change switch 2 as shown in FIG. 2 is not used, the temperature controller has to be mechanically switched to summer or winter mode. There was also the hassle of having to switch manually.

Therefore, an object of the present invention is to provide an electronic temperature controller for local cooling and heating control to solve the above problems.

Another object of the present invention is to provide an electronic temperature controller for local cooling and heating control that can reduce construction costs by implementing a mode switching part and a temperature control part for summer and winter operation in an integrated unit in the cooling and heating device.

Still another object of the present invention is to provide an electronic thermostat for convenient local cooling and heating control by automatically switching modes for summer and winter operation of the cooling and heating apparatus.

Another object of the present invention is to provide an electronic temperature controller for local cooling and heating control capable of fine indoor temperature control.

Hereinafter, an embodiment of the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 shows an example of the configuration of the local cooling and heating control apparatus having an electronic thermostat 5 according to the present invention, the mode switching portion for summer and winter operation in the configuration of the above-described FIG. The new thermostat 5 is constructed by integrating what was implemented separately. The valve 4 of the supply pipe P is driven by automatically switching the summer and winter operation in the temperature controller 5 according to the temperature detected by the supply pipe temperature detection sensor 6 to drive the valve drive motor M. Open and close appropriately to control cooling and heating temperature.

3 shows an example of the specific configuration of the temperature controller 5 during the second step. The temperature controller 5 is a supply pipe (P) for supplying cold, hot water, a sensor (6) for detecting the temperature of the supply pipe (P), cold, hot water through the supply pipe (P) In the apparatus for controlling local cooling and heating with a valve (4) for controlling the flow of the flow and a valve driving motor (M) for controlling the opening and closing of the valve (4), the supply detected by the sensor According to the temperature of the pipe (P), the mode setting unit for setting the cooling or heating mode, the room temperature detection unit for detecting the room temperature, and the valve drive motor (M) in accordance with the mode set by the mode setting unit A first controller for controlling the cold water or hot water to circulate along the supply pipe P by operating the valve 4, and the room temperature detected by the room temperature detector exceeds the reference temperature of the mode. (In summer mode, it is When the temperature is lowered, it means that the indoor temperature is higher than the reference temperature in the winter mode.) When the valve driving motor M is stopped, the valve 4 is closed to supply the cold or hot water. And a second control unit for controlling to block.

Referring to the operation of the temperature controller having the above configuration in detail as follows. Sensor 6 attached to the supply pipe P-for example, a demister can be used. The mode setting unit consisting of a plurality of resistors R9-R12 and comparators A2 and A3 is connected to the H terminal connected to the negative terminal. The mode setting unit has a form of a window comparator, and the voltage Vt input to the window comparator may be expressed by Equation (1) below. Where Rt2 is the resistance of the sensor 6, ie the thermistor.

Vt = (Vcc * Rt2) ÷ (R9 + Rt2)... … … … … … … … … … … … … … … … (One)

If the temperature of the supply pipe P is high, the output Vu of the second comparator A2 is in a "high" state to be heated (winter mode), and if the temperature of the supply pipe P is low, a third The output V _L of the comparator A3 is in a "high" state to be cooled (summer mode).

First, the case in which the summer mode is set will be described. In FIG. 3, the temperature of the room is higher than the temperature set by the variable resistor VR1 in the bridge circuit composed of the sensor for detecting the temperature of the room (region) Rt1, a plurality of resistors R1-R5, and the variable resistor VR1. When is high, the output of the first comparator A1 connected to the plurality of resistors R6-R8 (the first comparison signal for convenience) is in the " low " state. The first comparison signal in the " low " state is inverted in the inverter U3 and provided to one input terminal of the AND gate U2. However, since the output V _L of the third comparator A1 is supplied to the other input terminal of the AND gate U2 in the "high" state, the output of the AND gate U2 also becomes the "high" state and thus the diode The transistor Q1 is turned on through the D3 to turn on the relay K1, thereby driving the valve driving motor M of FIG. 2 through the terminal I, opening the valve 4, and allowing cold water to flow therethrough. Lowers. Through this process, when the indoor temperature becomes lower than the reference temperature, the first comparison signal becomes “high” and is inverted in the inverter U3, so that the output of the AND gate U2 becomes “low”. As a result, the transistor Q1 is turned off and the relay K1 is turned off to connect the contact COM of the terminal I and NC. Therefore, since the power is cut off to the valve driving motor (M) and the valve 4 is closed, the cold water can no longer flow to control the temperature.

In addition, since the temperature of the supply pipe P is released in the winter, the output V _U of the second comparator A2 becomes "high" and the output V _L of the third comparator A3 is "low". The output of the AND gate U2 remains in the " low " state. If the indoor temperature is higher than the set reference temperature, the first comparison signal is generated in the "low" state, and the transistor K1 is turned off, so that the relay K1 is turned off. As a result, the power supplied to the valve driving motor (M) is cut off to close the valve (4) to stop the supply of hot water. Thereafter, when the indoor temperature becomes lower than the reference temperature, the first comparison signal is inverted, so that the output of the AND gate U4 becomes “high”. Therefore, diode D2 is turned on, transistor Q1 is turned on, relay K1 is " on " and the connection state of terminal I is switched, that is, contact COM and NO are connected, so that power is supplied to valve drive motor M. Supplied. In this case, since the valve 4 is opened and hot water is supplied, it is possible to appropriately control the temperature of the room.

The present invention as described above can reduce the construction cost according to the wiring by implementing the summer, winter mode switching switch previously configured in the temperature controller. In addition, unlike the manual temperature controller that did not have a separate mode switch, the mode controller has a mode switch in the temperature controller so that the temperature controller automatically switches between summer and winter modes and automatically adjusts the room temperature according to the mode. And, because it is electronic, there is an advantage that fine room temperature control is possible.

Claims (3)

An apparatus for controlling local cooling and heating, comprising: a supply path for supplying cooling and heating materials; a sensor for detecting a temperature of the supply path; and an opening and closing control means for controlling opening and closing of the supply path. Mode setting means for setting the cooling or heating mode according to the detected supply path temperature, room temperature detecting means for detecting the room temperature, and driving the opening / closing control means in accordance with the mode set by the mode setting means. First control means for controlling the cooling material or heating material to circulate along the supply path by opening the supply path, and the opening / closing when the room temperature detected by the indoor temperature detection means exceeds a reference temperature of a corresponding mode. A second control means for controlling the operation of the control means to stop the supply of the cooling material or the heating material by closing the supply path; Electronic thermostats which features a. The method of claim 1, wherein the supply path is a pipe for providing a path through which the cold and hot water are circulated, and the path is controlled so that the cold and hot water are continuously supplied or no longer supplied under predetermined control. Electronic thermostat characterized in that it consists of a valve to shut off. The electronic thermostat according to claim 2, wherein the opening and closing control means is a valve driving motor which is driven under the control of the first and second control means to open or close the valve.