TWM561178U - Control device - Google Patents

Abstract

A control device, comprising an environmental sensor, an electrical quantity sensor, a control operating unit, and a resistance output unit. The control operating unit connects to the environmental sensor, the electrical quantity sensor, and the resistance output unit. The resistance output unit additionally connects to a temperature controller to replace original resistive temperature sensor. The resistance output unit outputs a first resistance to the temperature controller so that a controlled device operates at a first power state. The resistance output unit also can output a second resistance to the temperature controller so that a controlled device operates at a second power state. When the control operating unit reads environmental information or time information, the resistance output unit outputs the first resistance or the second resistance after calculating by the control operating unit so that the controlled device operates at the first power state or the second power state.

Description

Control device

The present invention relates to a control device, in particular, a control device that can change the temperature controller to control the controlled device.

Conventional HVAC equipment, such as air conditioners, central air conditioners, heat pumps and other refrigeration or heating equipment, are manually set by the temperature controller on the equipment. The temperature controller performs the device operation control according to the resistance change of the connected temperature sensor due to the temperature change, and the resistance change of the input temperature controller. In short, the conventional air conditioner can only read and control the temperature sensor resistance value at the temperature and the temperature corresponding resistance value set by the temperature controller to determine and control the start and stop operation of the controlled device. This is shown in Figure 1A and Figure 1B.

However, the conventional temperature controller only uses temperature as a basis for regulation, regardless of other environmental conditions, such as temperature, humidity, wind speed, wind direction or time, so that the temperature controller cannot maneuver its setting according to seasonal or external environmental conditions. The controlled equipment such as HVAC or heat pump can not operate in the most economical or most comfortable state, resulting in unnecessary energy waste or uncomfortable use of personnel.

In addition, it is conventional to use a resistive temperature sensor as a device for controlling the input of the temperature controller. If the control operation setting or mode of the controller is to be changed, for example, to control the power demand, the controller cannot be known. Under the condition of controlling the protection device, to replace or integrate The temperature controller makes the controlled device according to the set power demand as the control parameter basis, and the risk and cost required to modify or replace it are quite high.

In addition, the set temperature function on the temperature controller causes the controlled device to operate and the set resistance value corresponding to the temperature sensor changes, and it is more difficult to accurately control the operation of the controlled device.

Moreover, since the temperature controller can only perform logic operation and control according to the temperature sensor on the device, if it is to integrate other environmental information for control or add additional control functions, it should be changed without affecting the existing protection function or Adding features is more costly.

In view of this, one of the purposes of the present invention is to provide a control device that inputs a resistance signal to a temperature controller to operate the controlled device at a specific output power or power usage, so that the control device can retain the existing protection device. Change the operation mode and setting of the controlled device under the conditions.

Another object of the present invention is to provide a control device that allows an existing temperature controller to indirectly control a controlled device by outputting a specific resistance value to an original temperature controller according to environmental information, so that the original controlled device extends or Change the use of other control purposes, such as power demand control, humidity control, and change temperature control settings.

Another object of the present invention is to provide a control device that allows the original temperature controller to calculate information according to time, so that the original controlled device is extended or changed to use for time control purposes, such as scheduling control. Another object of the present invention is to provide a control device that allows the original temperature controller to perform logical operations or predictions based on environmental or time information, so that the controlled device can be used for a specific output power or power usage at a specific time. Such as power saving control, metering Fee control, etc.

The control device includes an environment sensing unit or a time calculation unit, a power measurement unit, a control operation unit, and a resistance output unit. The control arithmetic unit is connected to the environment sensing unit or the time calculating unit and the power measuring unit; the resistance output unit is connected to the control computing unit. The resistor output unit is additionally connected to the temperature controller. The resistance output unit generates a first resistance value input temperature controller, and causes the controlled device to operate in a first power usage state; the resistance output unit generates a second resistance value input temperature controller, and causes the controlled device to be second The power usage status is running. After the control operation unit operates according to the environment sensing unit or the time calculation unit information, the control resistance output unit outputs the first or second resistance value to the temperature controller to operate the controlled device in the first or second power usage state.

Additional features and advantages of the present invention will become apparent from the description which follows. Other objects and advantages of the present invention will be realized and attained by the structure of the invention and the appended claims.

11‧‧‧Environmental Sensing Unit

12‧‧‧Power measurement unit

13‧‧‧Control arithmetic unit

14‧‧‧Resistor output unit

15‧‧‧Parameter input unit

16‧‧‧ Temperature Controller

1A and FIG. 1B are diagrams showing the relationship between the set temperature and the temperature sensor resistance change of the conventional temperature controller and the power usage of the controlled device.

2A is a block diagram of an embodiment of the creation of an authoring control device in an environmental information unit.

2B is a block diagram of an embodiment of the authoring control device input by a time calculation unit.

Figure 2C is a graph showing the relationship between the resistance output and the power usage of the temperature controller controlled device.

3A-3D are schematic diagrams of a series connection embodiment of the authoring resistor output unit.

4A to 4D are schematic diagrams showing a parallel embodiment of the creation of the resistance output unit.

5A to 5C are schematic views of another embodiment of the creation control device.

6A and 6B are schematic views of another embodiment of the authoring control device.

7A-7C are schematic views of another embodiment of the authoring control device.

FIG. 8 is a flow chart of an embodiment of a method for controlling an authoring control device.

Referring to FIG. 2A , the authoring control device includes an environment sensing unit 11 , a power measuring unit 12 , a control computing unit 13 , and a resistance output unit 14 . The environment sensing unit 11, the power measuring unit 12, and the resistance output unit 14 are electrically connected to the control computing unit 13. The resistor output unit 14 is further electrically connected to the temperature controller 16, in particular, to the temperature controller 16 having an internal temperature sensor (not shown) connection point. The temperature controller 16 can be a commonly used thermostat whose internal temperature sensor is replaced by the environmental sensing unit 11 for use as a temperature or other control purpose.

Referring to FIG. 2B, the authoring control device includes a time calculating unit 15, a power measuring unit 12, a control computing unit 13, and a resistance output unit 14. The time calculation unit 15, the electric quantity measuring unit 12, and the resistance output unit 14 are electrically connected to the control arithmetic unit 13. The resistor output unit 14 is further electrically connected to the temperature controller 16, in particular, to the temperature controller 16 having an internal temperature sensor (not shown) connection point. The temperature controller 16 can be a commonly used thermostat, and the internal internal temperature control function is used as a timer or other control purpose, and the above environmental information input can be added for the purpose of the composite control purpose.

The control operation unit 13 controls the resistance output unit 14 to output the first resistor R0 to the temperature controller 16, and measures the power usage of the controlled device (not shown) by the power measuring unit 12, The control unit 13 further controls the resistance output unit 14 to output the second resistor R1 to the temperature controller 16, and measures the controlled device by the power measuring unit 12 (not shown). The amount of power used, here indicated by current 1, is controlled by the control unit 13 to obtain the relationship that the output first resistance corresponds to current 1 and the second resistance corresponds to current 2, as shown in FIG. 2C. The creative resistance output unit 14 is further configured to output the output of the controlled device through the adjustment of the resistor, and the control operation unit 13 reads the power usage of the controlled device of the power measurement unit 12 to calculate/analyze/record the power of the resistance output and the controlled device. The relationship between usage. Therefore, the control arithmetic unit 13 can automatically recognize and record the correspondence relationship between the power usage amount of the controlled device and the output resistance. In short, the control device of the present embodiment has a self-learning function.

The ambient sensing unit 11 of the present embodiment is exemplified by a resistive temperature sensor, but is not limited thereto, and is mainly used for detecting the current ambient temperature. In other embodiments, it is also possible to detect temperature, humidity, pressure, flow, flow rate, wind speed, illuminance, volume, voltage, current, frequency, speed, or a combination of one or more signals. The power measuring unit 12 takes the detection current as an example, but is not limited thereto, as long as the signal related to the calculation of the power usage is applicable. The signal input mode can be analog (resistance, current, voltage), digital and pulse, or an electronic signal, without specific restrictions.

The control arithmetic unit 13 may be a central processing unit (CPU), a micro processing unit (MCU), or the like, and is preferably a processor having logical computing capabilities. The resistor output unit 14 is preferably composed of a resistor and a relay, and the relay can be used as a switch to regulate the resistance value of the output of the resistor output unit 14. The resistor may be a conventional fixed resistor or a variable resistor, which is mainly turned on or off by a relay to combine different resistance values. The resistance output unit 14 of the present embodiment may be one or more, and is not particularly limited.

Since the power consumption (such as current) measurement and the resistance value change are used to judge the running state of the device, it is not necessary to measure and compare the resistance value of the temperature sensor on the original temperature controller 16, and the output through the resistance output unit can be accurately Ground control the operating current and power output of the controlled device at various temperature values. Therefore, in other embodiments, when the controlled device is a multi-stage temperature setting, a plurality of starting devices (such as a compressor), or a frequency conversion device, the control device of the embodiment can also be used. In practical applications, it can also be changed to set the target in terms of time and power demand.

For another embodiment of the present authoring control device, please refer to FIG. 3A to FIG. 3D. The main hardware structure is substantially the same as the foregoing embodiment. However, the resistor output unit 14 of the embodiment is exemplified by a plurality of groups connected in series, for example, the first resistor VR0, the second resistor VR1, and the third resistor VR2 are connected in series. When the control operation unit 13 controls the resistance output unit 14 to output the resistance signals VR0, VR1, VR2, VR0+VR1, VR0+VR2 to the temperature controller 16, the power consumption measurement unit 12 measures the power consumption of the controlled device respectively. It is operated as current 0, current 1, current 2, current 3, and current 4, that is, the resistance and current relationship set by the original temperature controller 16, as shown by curve 17 of FIG. 3B and FIG. 3D. The control operation unit 13 reads the environment sensing unit 11 as an input signal (for example, temperature), as shown in the first state 19 (which can be regarded as being located in the first resistance value interval and represented by the first interval in the figure). The original temperature sensor of the original temperature controller 16 (not shown) has an input resistance of VR0+VR1, and causes the controlled device to generate the power usage and power output of the current 3. At this time, after the control operation unit 13 reads the temperature environment information unit 11, the control resistor output unit 14 outputs the VR1 resistance to the temperature controller 16, and at this time, the controlled device (not shown) of the temperature controller 16 is changed to the current 1 The power usage is running as shown by curve 18 of Figure 3D.

In addition to the second state 20 (which can be regarded as being located in the second resistance value interval, the second in the figure When the interval is expressed, the input temperature of the original temperature sensor (not shown) of the temperature controller 16 is VR0+VR2, and the controlled device generates the power usage of the current 4. At this time, after the control operation unit 13 reads the temperature environment information unit 11, the control resistor output unit 14 outputs the VR2 resistance to the temperature controller 16, and at this time, the controlled device (not shown) of the temperature controller 16 is changed to the current 2 The power usage is running as shown by curve 18 of Figure 3D. In this embodiment, the operating curve of the controlled device that changes the control parameters of the temperature controller is compared with the curve of the original temperature controller and the resistance signal, as shown in FIG. 3C and FIG. 3D.

It should be noted that the present embodiment describes the operation and control method in two states, but is not limited to two states and can increase the combination of the resistance signals to increase the number of states of the control.

For another embodiment of the present authoring control device, please refer to FIG. 4A to FIG. 4D. The main hardware structure is substantially the same as that of the foregoing embodiment, but the resistor output unit 14 of the embodiment is exemplified by a plurality of groups connected in parallel, as shown in FIG. 4A, for example, the first resistor VR0, the second resistor VR1, and the third resistor VR2. in parallel. When the resistance output unit 14 outputs the resistance signals R0, R1, R2, R3, and R4 to the temperature controller 16, the power consumption measurement unit 12 measures the power usage of the controlled device as current 0, current 1, and current 2, respectively. Current 3, current 4, as shown by curve 17 of Figures 4B and 4D.

When the environment sensing unit 11 is in the first state as shown in the figure, the input temperature of the original temperature sensor (not shown) of the temperature controller 16 is R3, and the controlled device generates Current usage and power output of current 3. After the control operation unit 13 reads the temperature environment information unit 11, the control resistor output unit 14 outputs the R1 resistance to the temperature controller 16, and the controlled device of the temperature controller 16 (not shown) will change the power usage of the current 1. The operation is as shown by curve 18 of Figure 4D.

In the second state, the original temperature sensor of the temperature controller 16 (not shown) loses The input resistance is R4, and the controlled device generates the power usage of the current 4. After the control arithmetic unit 13 reads the temperature environment information unit 11, the control resistor output unit 14 outputs the R2 resistor to the temperature controller 16, and the controlled device of the temperature controller 16 (not shown) will change the power usage of the current 2. The operation is as shown by curve 18 of Figure 4D. The detailed comparison of the curve and the resistance signal is as shown in FIG. 4C and FIG. 4D. The present embodiment describes the operation and control method in two states, but is not limited to two states and can increase the number of resistor signals or the combination of series and parallel resistors. Increase the state of control.

Another embodiment of the present invention is a device for controlling the operation of the heater 24 by the temperature controller 16, and is input by a plurality of environmental information units 11 such as a temperature sensor 22 and a water flow sensor 23, as shown in FIG. 5A. The system architecture diagram is shown. When the resistance output unit 14 outputs the resistance of the R0, R1, R2, R3, and R4 to the temperature controller 16, the electric quantity measuring unit 12 detects the current amount detected by the current sensor 21 to the heater 24 as current 0, respectively. Current 1, current 2, current 3, and current 4, the control arithmetic unit 13 will analyze/record this relationship as shown in FIG. 5B. After the control operation unit 13 reads the input information of the environmental information unit 11, the logic control resistor output unit 14 according to FIG. 5C outputs a corresponding resistance value to the temperature controller 16 to operate the heater according to the set power usage and power output. .

Another embodiment of the present invention is the same as the previous device, that is, the device that controls the operation of the heater 24 by the temperature controller 16. This embodiment will use the time calculation information 15 as an input, as shown in FIG. 6A. The architecture diagram is shown. When the resistance output unit 14 outputs the resistance of the R0, R1, R2, R3, and R4 to the temperature controller 16, the electric quantity measuring unit 12 detects that the current sensor 21 detects that the amount of current of the heater 24 is current 0, Current 1, current 2, current 3, current 4, as shown in FIG. 6B, when the control arithmetic unit 13 reads the time calculation unit 15, the logic control resistor output unit 14 according to FIG. 6B outputs a corresponding resistance value to heat up. The device operates according to time settings and power usage.

Another embodiment of the present invention is a device for controlling the operation of the air conditioner 26 by the temperature controller 16, and the power demand of the power demand sensor 25 is taken as the environment information unit 11 and the time calculation unit as input. The 7A system architecture diagram is shown. Specifically, when the resistance output unit 14 outputs the resistance of the R0, R1, R2, R3, and R4 to the temperature controller 16, the electric quantity measuring unit 12 will read the current sensor 21 to detect the running current of the air conditioner 26. The values are current 0, current 1, current 2, current 3, and current 4, and the control arithmetic unit 13 will analyze/record as shown in Fig. 7B. When the control arithmetic unit 13 controls the resistance output unit 14 according to the time and power demand logic of FIG. 7B, the corresponding resistance value is output, so that the air conditioner 26 operates according to the time setting and the power usage amount logic rule, as shown in FIG. 7C.

It should be noted that, in the above embodiment, if the environment sensing unit 11 takes a hygrometer as an example, the control device of the present invention will increase the function of the humidity controller used by the original controlled device, and the setting principle and the self-learning function are as described above. The embodiments are the same and will not be further described herein. In other embodiments, the pressure, flow rate, flow rate, wind speed, illuminance, volume, voltage, current, frequency, or a combination thereof may also be introduced into the control device of the present invention as an environmental sensing parameter to control the change of the output power.

It should be noted that, in the above embodiment, if the time calculation unit 15 takes the timing function as an example, the control device of the present invention will increase the timing operation control function of the original controlled device, the setting principle and the self-learning function and the foregoing embodiment. The same, will not be described here. In other embodiments, it may be combined with the environmental information unit 11 as the input calculation and judgment control of the control arithmetic unit 13.

For another embodiment of the present creation, please refer to FIG. 8. 8 is a control method applicable to the present creation control device, comprising the steps of: (S1) outputting a first resistance value to a temperature controller to operate the controlled device in a first power usage state; (S2) outputting a second resistance Value to temperature controller In order to operate the controlled device in the second power usage state; (S3) obtaining current environmental information or time information; (S4) calculating the first resistance value or the second resistance value according to the environmental information or the time information to the temperature controller (S5) Detecting the power usage of the controlled device.

The control method of the present embodiment is implemented by the hardware structure of the foregoing embodiment, and the detailed structure and principle thereof have been described in detail above, and will not be further described herein. However, it should be noted that, in actual situations, when the user inputs a certain parameter and outputs a corresponding resistance value, and the controlled device is not detected to have a matching current value, for example, after outputting the first resistance value, The detected power usage amount is close to the first power usage amount or deviated from the first power usage amount, if it is close, the process returns to the step (S3), if it is deviated, it returns to the step (S1); or after outputting the second resistance value The detected power usage amount is close to the second power usage amount or deviated from the second power usage amount, and if it is close, the process returns to the step (S3), and if it is deviated, the process returns to the step (S1).

It should be noted that the foregoing approaching and moving away from the first/second power usage amount are defined as relatively close or relatively distant. For example, in the step (S5-1), the approaching first power usage amount means that the absolute difference between the power usage amount detected by the power amount measuring unit and the first power usage amount in the step (S1) is less than the power amount. The absolute value of the difference between the amount of power usage detected by the measuring unit and the second amount of power used in step (S2).

On the other hand, the deviation from the first power usage means that the absolute difference between the detected power usage amount and the first power usage amount in the step (S1) is greater than the detected power usage amount and the step (S2). The absolute value of the difference in the second amount of power usage.

Similarly, the approaching second power usage amount means that the absolute difference between the detected power usage amount and the second power usage amount in the step (S2) is smaller than the detected power usage amount and the step (S1) The absolute value of the difference in the amount of first power usage.

Deviating from the second power usage means that the absolute difference between the detected power usage amount and the second power usage amount of the step (S2) is greater than the detected power usage amount and the first power of the step (S1) The absolute value of the difference in usage.

Compared with the prior art, the control device of the present invention controls the output of the temperature controller by a specific resistance signal, and through the power measurement and logic operation, the control device can accurately control the operation of the device by self-learning, and Accurate control of the equipment according to the required environmental sensing parameters or time calculation information to achieve power saving or specific purpose.

Claims (10)

A control device includes: an environment sensing unit; a power measuring unit; a control computing unit coupled to the environment sensing unit and the power measuring unit; and at least one resistor output unit, and the control unit and a temperature controller is connected, wherein the temperature controller has at least one of a first resistance value interval and a second resistance value interval corresponding to a state, and when the temperature controller inputs a first resistance value between the first resistance value In the interval, the output control is such that a controlled device operates with the first power usage; when the temperature controller inputs a second resistance value between the second resistance value interval, the output control is performed to enable the controlled device to The power usage operation; wherein the control operation unit calculates and determines the value obtained by the environment sensing unit, and controls the resistance output unit to output a first resistance value to the temperature controller to enable the controlled device to The first power usage amount is operated, or the second resistance value is output to the temperature controller to cause the controlled device to operate with the second power usage amount. The control device of claim 1, wherein the at least one resistor output unit comprises a resistor and a relay. The control device of claim 1, wherein the at least one resistance output unit is a series connection, a parallel arrangement, or a combination thereof. The control device of claim 1, wherein the environment sensing unit signal includes at least temperature, Humidity, concentration, pressure, flow rate, flow rate, wind speed, illuminance, volume, voltage, current, resistance, frequency, speed, count, pulse wave or a combination of one or more signals or an electronic signal. The control device of claim 1, wherein the power measuring unit is a measuring device or a communication input method capable of calculating a power usage amount, and includes at least one of an analog signal, a digital signal, and a pulse signal or an electronic signal. coding. A control device comprising: a time calculation unit; a power measurement unit; a control operation unit, connected to the time calculation unit and the power measurement unit; and at least one resistance output unit, and the control operation unit and a temperature control The temperature controller has at least one of a first resistance value interval and a second resistance interval corresponding to a state, and when the temperature controller inputs a first resistance value between a first resistance value interval, The output control causes a controlled device to operate with the first power usage; when the temperature controller inputs a second resistance value between the second resistance value interval, the output control is used to enable the controlled device to use the second power The control operation unit calculates and judges the value obtained by the time calculation unit, and controls the resistance output unit to output a first resistance value to the temperature controller to enable the controlled device to use the first power The quantity is operated, or the second resistance value is output to the temperature controller to cause the controlled device to operate with the second power usage amount. The control device of claim 6, wherein the at least one resistance output unit comprises a resistor and a relay. The control device of claim 6, wherein the at least one resistance output unit is a series connection, a parallel arrangement, or a combination thereof. The control device of claim 6, wherein the time calculation unit signal is an absolute time, or a relative time or a combination of one or more signals or an electronic signal. The control device of claim 6, wherein the power measuring unit is a measuring device or a communication input method capable of calculating a power usage amount, and includes at least one of an analog signal, a digital signal, and a pulse signal or an electronic signal. coding.