Patent Description:
Compression apparatus (including a compressor and a pressure vessel, where pressure in the pressure vessel is changed when the compressor is operating) are important components of an air conditioning system and a heat pump system for working. In a system containing a compression apparatus, if no measure is taken to turn off the compression apparatus when the system pressure is high, the system pressure will continue to rise, thereby generating danger.

An existing method of turning off the compression apparatus is collecting by a main control board a switch signal of the compression apparatus, outputting the signal by the main control board to a module board according to the switch signal, and controlling by the module board the compression device to be turned off. This method of turning off the compression apparatus involves a lot of elements, has low response speed, and as long as any one element is damaged, a situation that the compression device cannot be turned off will occur, thereby leading to a serious consequence.

Thus, it still needs to be solved how to improve efficiency and success rate of turning off the compression apparatus, and to improve safety factors of an air conditioning system and a heat pump system. <CIT> relates to a circuit for blocking operation of a compressor.

This document does not disclose two interconnected control apparatuses which are connected to a drive apparatus and to a pressure switch.

<CIT> relates to an air conditioner having a function of protecting a compressor.

In the following, each of the described methods, apparatuses, embodiments, examples, and aspects, which do not fully correspond to the invention as defined in the claims is thus not according to the invention and is, as well as the whole following description, present for illustration purposes only or to highlight specific aspects or features of the claims. Embodiments not falling under the scope of the claims should be interpreted as examples useful for understanding the invention.

The present application provides turn-off protection, driving, and overpressure turn-off systems, a heat pump apparatus, and an electrical device, to improve a success rate of turning off a compression apparatus and improve safety factors of an air conditioning system and a heat pump system.

In one aspect, the present application provides a turn-off protection system, including:.

In an optional embodiment, the turn-off protection system further includes:
a third control apparatus, configured to be connected to the first control apparatus and the pressure switch apparatus to output a third drive signal and further configured to stop outputting the third drive signal according to the pressure switch action signal, where the third drive signal is used for driving the first control apparatus to output the first drive signal.

In an optional embodiment, the turn-off protection system further includes:
a signal output circuit, where an end of the signal output circuit is connected to the second control apparatus and the other end of the signal output circuit is connected to the drive apparatus.

In an optional embodiment, the signal output circuit includes:.

In an optional embodiment, the signal output circuit further includes:
a diode, where a positive electrode of the diode is connected to the collector of the second triode and a negative electrode of the diode is connected to the first pin.

In an optional embodiment, the drive apparatus further includes a second pin connecting to a first feedback pin of the second control apparatus; and
a pulse signal is transmitted to the first feedback pin through the second pin when the drive apparatus stops outputting the second drive signal.

In an optional embodiment, the turn-off protection system further includes a pressure switch apparatus, the pressure switch apparatus includes:.

In an optional embodiment, the second control apparatus is further connected to the third control apparatus;
the second control apparatus is configured to transmit a reset signal to the third control apparatus upon obtaining the pressure switch action signal and the first drive signal from the first control apparatus, and the reset signal is used to control the third control apparatus to stop outputting the third drive signal.

In an optional embodiment, the first control apparatus includes N bridge arm pulse width modulation, PWM, circuits, and each bridge arm PWM circuit has a different on time; where N is an integer greater than <NUM>.

In an optional embodiment, each bridge arm PWM circuit includes a triode.

In an optional embodiment, the first control apparatus includes an <NUM>-channel buffer.

In an optional embodiment, the turn-off protection system further includes a first protection apparatus and a second protection apparatus;
one ends of the first protection apparatus and the second protection apparatus are both connected to the drive apparatus, and the other ends of the first protection apparatus and the second protection apparatus are both connected to the first control apparatus to buffer an output of the control apparatus.

In an optional embodiment, the first protection apparatus includes:.

In an optional embodiment, the second protection apparatus includes:.

In an optional embodiment, the turn-off protection system further includes:
a drive apparatus, configured to be connected to a compression apparatus when in use to output the second drive signal to the compression apparatus after receiving the first drive signal, where the second drive signal is used to drive the compression apparatus to operate.

In another aspect, the present application provides a heat pump apparatus, including the turn-off protection system provided in the first aspect, and further including:.

In another aspect, the present application provides an electrical device, including the heat pump apparatus provided in the second aspect.

In another aspect, the present application provides a driving system, including the turn-off protection system as described in the first aspect, and further including:
a drive apparatus, configured to be connected to the compression apparatus when in use to output the second drive signal to the compression apparatus after receiving the first drive signal outputted by the first control apparatus, so as to drive the compression apparatus to operate.

In another aspect, the present application provides an overpressure turn-off system, including the turn-off protection system as described in the first aspect, and further including:
a pressure switch apparatus, configured to be turned off when a pressure of the system is detected to be overpressure, and output a pressure switch action signal.

The present embodiment provides a turn-off protection system including a first control apparatus and a second control apparatus. The first control apparatus is configured to be in signal connection with the pressure switch apparatus to output a first drive signal and further configured to stop outputting the first drive signal according to a pressure switch action signal. The pressure switch apparatus is configured to be turned off when a pressure of the system is detected to be overpressure and output the pressure switch action signal. The second control apparatus is connected to the first control apparatus, and further connected to the drive apparatus of the compression apparatus when in use. The second control apparatus is used to output a fault protection signal to the drive apparatus upon obtaining the pressure switch action signal and the first drive signal from the first control apparatus. The fault protection signal is used to control the drive apparatus to stop outputting the second drive signal to the compression apparatus.

Thus, when the system is in overpressure, the control apparatus controls the drive apparatus of the compression apparatus to stop outputting a drive signal, so as to control the compression apparatus to be turned off. The second control apparatus is further configured to control the drive apparatus to stop outputting a drive signal when the system is in overpressure. The first control apparatus and the second control apparatus not only provide dual turn-off protection but also improve efficiency and success rate of turning off the compression apparatus, as well as improve safety factors of an air conditioning system and a heat pump system.

In addition, there is no need to make a software logic judgement in overpressure protection. It can use a signal to directly drive hardware to perform turn-off. Thus, fewer elements are needed, and the response is more quick and safer, the efficiency and success rate of turning off the compression apparatus is improved, and safety factors of the air conditioning system and heat pump system are improved.

The drawings herein are incorporated into the specification and constitute a part of this specification, showing embodiments that comply with the present disclosure, and are used together with the specification to explain the principles of the present disclosure.

Description of reference numerals:
turn-off protection system <NUM>; pressure switch apparatus <NUM>; pressure detection switch <NUM>; first control apparatus <NUM>; PWM circuit <NUM>; second control apparatus <NUM>; drive apparatus <NUM>; third control apparatus <NUM>; signal output circuit <NUM>; first protection apparatus <NUM>; second protection apparatus <NUM>; compression apparatus <NUM>; first power supply <NUM>; second power supply <NUM>; heat pump apparatus <NUM>; heat-exchange apparatus <NUM>; electrical device <NUM>; driving system <NUM>; overpressure turn-off system <NUM>.

Through the above drawings, specific embodiments of the present disclosure have been shown, and will be described in detail below. These drawings and descriptions are not intended to limit the scope of the concept of the present disclosure in any way, but rather to illustrate the concepts of the present disclosure with referring to specific embodiments to those technical personnel in the field.

Herein, exemplary embodiments will be described herein in detail, and examples of the exemplary embodiments are represented in the drawings. When the following description refers to the drawings, unless otherwise indicated, the same numbers in different drawings represent the same or similar elements. The implementation modes described in the following exemplary embodiments do not represent all implementation modes that are consistent with the present disclosure. Rather, they are only examples of apparatus and methods that are consistent with some aspects of the present disclosure as detailed in the appended claims.

In the description of the present application, it should be understood that the terms "first" and "second" are only used for descriptive purposes and cannot be understood as indicating or implying relative importance or implicitly indicating the quantity of indicated technical features. Therefore, features defined by "first" and "second" can explicitly or implicitly include one or more such features. In the description of the present application, "more" refers to two or more than two, unless otherwise specified.

An existing method of turning off the compression apparatus is collecting by a main control board a switch signal of the compression apparatus, outputting the signal by the main control board to a module board according to a switch signal, and controlling by the module board the compression device to be turned off. This method of turning off the compression apparatus involves a lot of elements, has slow response speed, and as long as any one element is damaged, a situation that the compression device cannot be turned off will occur, thereby leading to a serious consequence.

There are also some methods of turning off the compression apparatus: directly connecting a pressure switch to and controlling a power supply of a compressor, thereby stopping the compressor by disconnecting the power supply. However, if the power supply is a unidirectional power supply, an effect of controlling the compressor to stop cannot be achieved.

Thus, it still needs to be solved how to improve efficiency and the success rate of turning off the compression apparatus, and to improve safety factors of an air conditioning system and a heat pump system.

In view of this, the present application provides a turn-off protection system, a driving system, an overpressure turn-off system, a heat pump apparatus, and an electrical device. The turn-off protection system includes a pressure switch apparatus, a first control apparatus, a drive apparatus, and a second control apparatus. This pressure switch apparatus is turned off when a pressure of the system is detected to be overpressure and outputs a pressure switch action signal. The first control apparatus is in signal connection with the pressure switch apparatus to output a first drive signal and is used for stopping outputting the first drive signal according to the pressure switch action signal. The drive apparatus is connected to a compression apparatus to output a second drive signal to the compression apparatus after receiving the first drive signal, the second drive signal is used to drive the compression apparatus to operate. The second control apparatus is connected to the first control apparatus and the drive apparatus so as to output a fault protection signal to the drive apparatus when the pressure switch action signal and the first drive signal are obtained from the first control apparatus, where the fault protection signal is used for controlling the drive apparatus to stop outputting the second drive signal. When the system is in overpressure, the control apparatus controls the drive apparatus of the compression apparatus to stop outputting the drive signal, thereby controlling the compression apparatus to be turned off. The second control apparatus is further used for controlling the drive apparatus to stop outputting the drive signal when the system is in overpressure. The first control apparatus and the second control apparatus not only provide dual turn-off protection, but also improve efficiency and success rate of turning off the compression apparatus, as well as improve the safety factors of an air conditioning system and heat pump system.

Referring to <FIG>, some embodiments of the present application provide a turn-off protection system <NUM>, where the turn-off protection system <NUM> is in signal connection with a pressure switch apparatus <NUM> when in use. The pressure switch apparatus <NUM> is configured to be turned off when the system is detected to be overpressure and output a pressure switch action signal. The pressure of the system is, for example, a pressure of an air conditioning system, or a pressure of part of the air conditioning system (for example, a pressure of air-conditioner indoor unit).

When the system is operating normally (the system is not in overpressure), the pressure switch apparatus <NUM> may be in a normal closed state, and the pressure switch apparatus <NUM> is disconnected when the system is in overpressure. The pressure switch apparatus <NUM> may be in a normal open state when the system is operating normally, and the pressure switch apparatus <NUM> is closed when the system is in overpressure. When the pressure of the system is overpressure, the state of the pressure switch apparatus <NUM> is needed to be changed to a state opposite to a normal state.

The pressure switch apparatus <NUM> can be a switch of an external device to detect whether the system is in overpressure.

The turn-off protection system <NUM> includes a first control apparatus <NUM> and a second control apparatus <NUM>.

The first control apparatus <NUM> is in signal connection with the pressure switch apparatus <NUM> when in use to output a first drive signal and is used for stopping outputting the first drive signal according to a pressure switch action signal, where the first drive signal is used for instructing a drive apparatus <NUM> of a compression apparatus <NUM> to drive the compression apparatus <NUM> to operate. The drive apparatus <NUM> is connected to the compression apparatus <NUM>, the drive apparatus <NUM> can be understood as a drive module of a compression apparatus. The drive apparatus <NUM> is used for outputting a second drive signal to the compression apparatus <NUM> after receiving the first drive signal, the second drive signal is used for driving the compression apparatus <NUM> to operate. If there is no first drive signal, the drive apparatus <NUM> will not output the second drive signal and will not drive the compression apparatus <NUM> to operate. The first control apparatus <NUM> is, for example, a logic chip, and mechanically triggered to stop outputting the first drive signal after receiving the pressure switch action signal.

The second control apparatus <NUM> is connected to the first control apparatus <NUM>, and further connected to the drive apparatus <NUM> when in use, the second control apparatus <NUM> outputs a fault protection signal to the drive apparatus <NUM> upon obtaining the pressure switch action signal and the first drive signal from the first control apparatus <NUM>. This fault protection signal is used for controlling the drive apparatus <NUM> to stop outputting the second drive signal to the compression apparatus <NUM>. A purpose that the second control apparatus <NUM> outputs the fault protection signal to the drive apparatus <NUM> is to prevent a situation where the first control apparatus <NUM> does not stop outputting the first drive signal when the first control apparatus <NUM> have received the pressure switch action signal. The drive apparatus <NUM> can be further controlled to stop outputting the second drive signal by inputting the fault protection signal to the drive apparatus <NUM>.

In summary, the embodiments provide a turn-off protection system <NUM>, including a first control apparatus <NUM> and a second control apparatus <NUM>. The first control apparatus <NUM> is in signal connection with the pressure switch apparatus <NUM> to output the first drive signal and is used for stopping outputting the first drive signal according to the pressure switch action signal. The pressure switch apparatus <NUM> is to be turned off when the pressure of the system is detected to be overpressure and outputs the pressure switch action signal. The second control apparatus <NUM> is connected to the first control apparatus <NUM>, and further connected to the drive apparatus <NUM> of the compression apparatus <NUM> when in use, the second control apparatus <NUM> outputs a fault protection signal to the drive apparatus <NUM> upon obtaining the pressure switch action signal and the first drive signal from the first control apparatus <NUM>. The fault protection signal is used to control the drive apparatus <NUM> to stop outputting the second drive signal to the compression apparatus <NUM>.

So, when the system is in overpressure, the control apparatus controls the drive apparatus <NUM> of the compression apparatus <NUM> to stop outputting a drive signal, thereby controlling the compression apparatus <NUM> to be turned off. The second control apparatus <NUM> is further used for controlling the drive apparatus <NUM> to stop outputting drive signal when system is in overpressure. The first control apparatus <NUM> and the second control apparatus <NUM> not only provide dual turn-off protection, but also improve efficiency and success rate of turning off the compression apparatus <NUM>, and improve safety factors of an air conditioning system and a heat pump system.

In addition, in overpressure protection, there is no need to make a software logic judgment. It is to use a signal to directly drive hardware to perform turn-off. Thus, fewer elements are needed, response is faster and safer, the efficiency and success rate of the turning off the compression apparatus <NUM> are improved, and the safety factors of the air conditioning system and heat pump system are improved.

Referring to <FIG>, a turn-off protection system <NUM> provided by some embodiments of the present application further includes a third control apparatus <NUM>, where the third control apparatus <NUM> is connected to the first control apparatus <NUM> and the pressure switch apparatus <NUM> to output a third drive signal, the third drive signal is used to drive the first control apparatus <NUM> to output the first drive signal. The third control apparatus <NUM> is further used to stop outputting the third drive signal according to the pressure switch action signal.

In some optional embodiments, the second control apparatus <NUM> is connected to the pressure switch apparatus <NUM>. The second control apparatus <NUM> outputs a reset signal to the third control apparatus <NUM> according to the pressure switch action signal, the third control apparatus <NUM> is in signal connection with the first control apparatus <NUM>, the third control apparatus <NUM> controls the first control apparatus <NUM> to stop outputting the first drive signal according to the pressure switch action signal.

A purpose that the second control apparatus <NUM> outputs the reset signal to the third control apparatus <NUM> is to prevent a situation where the first control apparatus <NUM> does not stop outputting the first drive signal when the first control apparatus <NUM> has received the pressure switch action signal; and to control the first control apparatus <NUM> to stop outputting the first drive signal through the third control apparatus <NUM>.

Specifically, the third control apparatus <NUM> is used to obtain the signal outputted by the first control apparatus <NUM> while obtaining the pressure switch action signal. When the obtained signal that is outputted by the first control apparatus <NUM> is the first drive signal, the reset signal is outputted to the third control apparatus <NUM>. Upon receiving the reset signal, the third control apparatus <NUM> stops outputting the third drive signal to the first control apparatus <NUM>. More specifically, when the signal outputted by the first control apparatus <NUM> is determined as the first drive signal, the second control apparatus <NUM> outputs by a pin a fault signal of the first control apparatus <NUM> to the third control apparatus <NUM>. The third control apparatus <NUM> stops outputting the third drive signal to the first control apparatus <NUM> upon receiving the fault signal of the first control apparatus <NUM>. Therefore, controlling the first control apparatus <NUM> to stop outputting the first drive signal by the third control apparatus <NUM> can be further ensured to turn off the compression apparatus <NUM>.

In summary, the turn-off protection system <NUM> provided by the embodiments further includes a third control apparatus <NUM>. The second control apparatus <NUM> is used to output a reset signal to the third control apparatus <NUM> according to the pressure switch action signal, and the third control apparatus <NUM> is used to control the first control apparatus <NUM> to stop outputting the first drive signal according to the reset signal. In this way, if the first control apparatus <NUM> does not stop outputting the first drive signal after receiving the pressure switch action signal, the third control apparatus <NUM> can be used to further control the first control apparatus <NUM> to stop outputting the first drive signal, thereby improving the success rate of turning off the compression apparatus <NUM>.

Referring to <FIG>, a turn-off protection system <NUM> provided by some embodiments of the present application further includes a signal output circuit <NUM>. One end of the signal output circuit <NUM> is connected to the second control apparatus <NUM>, and the other end thereof is connected to the drive apparatus <NUM>. The second control apparatus <NUM> outputs the fault protection signal to the drive apparatus <NUM> through the signal output circuit <NUM>. Optionally, the drive apparatus <NUM> also outputs a low-pulse feedback signal to the second control apparatus <NUM> through the signal output circuit <NUM>. The low-pulse feedback signal is used to indicate that the drive apparatus <NUM> has stopped outputting the second drive signal.

Specifically, the fault protection signal is used to excite the signal output circuit <NUM> to transmit a high-level signal to the drive apparatus <NUM>, so that the drive apparatus <NUM> stops outputting the second drive signal under an action of the high-level signal. The high-level signal comes from a high-level power supply connected to the signal output circuit <NUM>, the high-level power supply can be a built-in power supply in a module where the compression device <NUM> is located, and may be such as a 15V power supply.

The signal output circuit <NUM> shown in <FIG> is a schematic representation of the signal output circuit <NUM>. The signal output circuit <NUM> includes a first triode Q1 and a second triode Q2.

A base electrode of the first triode Q1 is connected to an output of the second control apparatus <NUM>, and an emitter electrode of the first triode Q1 is grounded. An emitter electrode of the second triode Q2 is connected to the first power supply <NUM>, a base electrode of the second triode Q2 is connected to a collector of the first triode, and a collector of the second triode Q2 is connected to a first pin of the drive apparatus <NUM>. The first triode Q1 can be an NPN-type triode, and the second triode Q2 can be a PNP-type triode. The second control apparatus <NUM> firstly outputs the fault protection signal to turn on the first triode Q1, and the emitter electrode of the second triode Q2 is connected to the first power supply <NUM>. After the first triode Q1 is turned on, the second triode Q2 is turned on. Then, the first power supply <NUM> outputs a high-level signal to the drive apparatus <NUM>, and the drive apparatus <NUM> stops outputting the second drive signal upon receiving the high-level signal.

That is, the fault protection signal is used to turn on the first triode Q1 and the second triode Q2, so that the drive apparatus <NUM> stops outputting the second drive signal after receiving by the first pin a voltage signal (i.e., the high-level signal described above) outputted by the first power supply <NUM>.

In some optional embodiments, the signal output circuit <NUM> further includes a diode D1, a positive electrode of the diode D1 is connected to the collector of the second triode, and a negative electrode of the diode D1 is connected to the first pin of the drive apparatus <NUM>. The diode D1 can filter out an impurity signal in the voltage signal (i.e., the high-level signal described above) outputted by the first power supply <NUM>.

In some optional embodiments, the signal output circuit <NUM> further includes a resistor R1, resistor R2, resistor R3, and resistor R4.

One end of the resistor R1 is connected to an output of the second control apparatus <NUM>, and the other end of the resistor R1 is connected to the base electrode of the first triode Q1. One end of the resistor R2 is connected to the collector of the first triode Q1, and the other end of the resistor R2 is connected to the base electrode of the second triode Q2. One end of the resistor R3 is connected to the other end of the resistor R2; and the base electrode of the second triode Q2, and the other end of the resistor R3 is connected to an output of the first power supply <NUM>. One end of the resistor R4 is connected to the negative electrode of the diode D1, and the other end of the resistor R4 is connected to the first pin of the drive apparatus <NUM>.

The function of the resistors R1, R2, R3, and R4 is to stabilize the transmission of signals, to improve a probability that the drive apparatus <NUM> successfully receives the voltage signal (i.e., the high-level signal as described above) outputted by the first power supply <NUM>, thereby improving the probability of turning off the compression apparatus <NUM>.

In some optional embodiments, the drive apparatus <NUM> further includes a second pin, the second pin is connected to a first feedback pin of the second control apparatus <NUM>, and a power supply (<NUM>. 3V power supply as shown in <FIG>) is further provided on a connection link. When the drive apparatus <NUM> stops outputting the second drive signal, a pulse signal is transmitted to the first feedback pin through the second pin. If the second control apparatus <NUM> does not receive the pulse signal, the fault protection signal can be transmitted to the drive apparatus <NUM> again so as to trigger the drive apparatus <NUM> again to stop outputting the second drive signal. In this way, the success rate of controlling the drive apparatus <NUM> to stop outputting the second drive signal is improved through pulse signal feedback, thereby improving the success rate of turning off the compression apparatus <NUM> when the system is in overpressure.

Multiple resistors (two resistors are exemplarily shown in <FIG>) can be further provided on a line connecting the second pin of the drive apparatus <NUM> to the first feedback pin of the second control apparatus <NUM>, the multiple resistors are used to stabilize the signal outputted by the drive apparatus <NUM> and filter out some of impurity signals.

In summary, the turn-off protection system <NUM> provided by these embodiments further includes a signal output circuit <NUM>. The signal output circuit <NUM> is provided with a first triode Q1 and a second triode Q2 that can be sequentially turned on. The base electrode of the first triode Q1 is connected to the output of the second control apparatus <NUM>, and the emitter electrode of the first triode Q1 is grounded. The emitter electrode of the second triode Q2 is connected to the first power supply <NUM>, the base electrode of the second triode Q2 is connected to the collector of the first triode, and the collector of the second triode Q2 is connected to the first pin of the drive apparatus <NUM>. The fault protection signal turning on the first triode Q1 causes the second triode Q2 to be turned on, so that the drive apparatus <NUM> stops outputting the second drive signal after receiving by the first pin the voltage signal outputted by the first power supply <NUM>. By the signal output circuit <NUM>, the success rate of controlling the drive apparatus <NUM> to stop outputting the second drive signal can be improved, thereby improving the success rate of turning off the compression apparatus <NUM> when the system is in overpressure.

Referring to <FIG>, a turn-off protection system <NUM> provided by some embodiments of the present application further includes the pressure switch apparatus <NUM> described above. The pressure switch apparatus <NUM> includes a pressure detection switch <NUM>.

As shown in <FIG>, one end of the pressure detection switch <NUM> is connected to an enable pin of the first control apparatus <NUM>, and further connected to a pin of the third control apparatus <NUM>, as well as connected to a second power supply <NUM>. The second power supply <NUM> may be a built-in power supply in a module board where the compression apparatus <NUM> is located, and may be, for example, a <NUM>. 3V power supply. The other end of the pressure detection switch <NUM> is grounded.

When the pressure detection switch <NUM> is closed, the enable pin of the first control apparatus <NUM> is grounded, and the pin of the second control apparatus <NUM> and the pin of the third control apparatus <NUM> cannot receive a voltage signal, that is, the pin of the second control apparatus <NUM> and the pin of the third control apparatus <NUM> cannot receive the pressure switch action signal.

When the pressure detection switch <NUM> is turned off, the voltage signal that is outputted by the second power supply <NUM> and received by the enable pin of the first control apparatus <NUM> is the pressure switch action signal. Similarly, the voltage signal that is outputted by the second power supply <NUM> and received by the second control apparatus <NUM> and the third control apparatus <NUM> is the pressure switch action signal.

In some optional embodiments, the pressure switch apparatus <NUM> further includes a resistor R5, resistor R6, resistor R7, and resistor R8.

One end of the resistor R5 is connected to the second power supply <NUM>, and the other end of the resistor R5 is connected to one end of the pressure detection switch <NUM>, and further connected to the enable pin of the first control apparatus <NUM>. One end of the resistor R6 is connected to the second power supply <NUM>, and the other end of the resistor R6 is connected to the other end of the resistor R5, and further connected to the enable pin of the first control apparatus <NUM>. The resistor R5 and the resistor R6 are in a parallel state. A function of the resistors R5 and R6 is to stabilize a voltage signal outputted by the second power supply <NUM> when the pressure detection switch <NUM> is turned off due to overpressure of the system, and filter out some of impurity signals in the voltage signal.

One end of the resistor R7 is connected to one end of the pressure detection switch <NUM>, and further connected to the enable pin of the first control apparatus <NUM>, and the other end of the resistor R7 is connected to the pin of the second control apparatus <NUM>. One end of the resistor R8 is connected to one end of the resistor R7, and further connected to the enable pin of the first control apparatus <NUM>, and the other end of the resistor R8 is connected to another pin of the second control apparatus <NUM>. A function of the resistors R7 and R8 is to stabilize the voltage signal outputted by the second power supply <NUM> and filter out some of impurity signals in the voltage signal when the pressure detection switch <NUM> is turned off due to overpressure of the system.

In summary, the pressure switch apparatus <NUM> in the turn-off protection system <NUM> provided by these embodiments include a pressure detection switch <NUM>, the pressure detection switch <NUM> is connected to a second power supply <NUM>, and is further connected to the first control apparatus <NUM>, the second control apparatus <NUM>, and the third control apparatus <NUM>, respectively. When the system is not in overpressure, the pressure detection switch <NUM> is in a normally closed state, and the enable pin of the first control apparatus <NUM> does not receive the pressure switch action signal. Similarly, neither the second control apparatus <NUM> nor the third control apparatus <NUM> receives the pressure switch action signal. When the system is in overpressure, the pressure detection switch <NUM> is turned off, the voltage signal that is outputted by the second power supply <NUM> and received by first control apparatus <NUM>, the second control apparatus <NUM> and the third control apparatus <NUM> is the pressure switch action signal.

Referring to <FIG>, in a turn-off protection system <NUM> provided by some embodiments of the present application, the first control apparatus <NUM> includes N bridge arm pulse width modulation, PWM, circuits <NUM>, and the number of N is determined by the requirements of the drive apparatus <NUM>. <FIG> shows that the first control apparatus <NUM> includes two bridge arm PWM circuits <NUM>, namely an upper bridge arm <NUM>-channel PWM circuit <NUM> and a lower bridge arm <NUM>-channel PWM circuit <NUM>. Each bridge arm PWM circuit <NUM> includes a triode, and the first control apparatus <NUM> includes a triode array.

The N bridge arm PWM circuits <NUM> are all driven to be turned on by the third drive signal outputted by the third control apparatus <NUM>. In order to prevent mutual influence between the bridge arm PWM circuits <NUM>, conduction time of each bridge arm PWM circuit <NUM> in the N bridge arm PWM circuits <NUM> can be different. The third drive signal outputted by the third control apparatus <NUM> is a pulse signal, and the first drive signal outputted by the first control apparatus <NUM> is also a pulse signal. Optionally, the first control apparatus <NUM> can be an <NUM>-channel buffer.

In some optional embodiments, the turn-off protection system further includes a first protection apparatus <NUM> and a second protection apparatus <NUM>. One ends of the first protection apparatus <NUM> and the second protection apparatus <NUM> are both connected to the drive apparatus <NUM>, and the other ends of the first protection apparatus <NUM> and the second protection apparatus <NUM> are both connected to the first control apparatus <NUM>. The first protection apparatus <NUM> and the second protection apparatus <NUM> are both used to buffer the output of the first control apparatus <NUM>.

Optionally, the first protection apparatus <NUM> includes a first resistor R9 and a first capacitor C1. One end of the first resistor R9 is connected to a bridge arm PWM circuit <NUM> (the upper bridge arm <NUM>-channel PWM circuit <NUM> shown in <FIG>), and the other end of the first resistor R9 is connected to the drive apparatus <NUM>. One end of the first capacitor C1 is connected to the other end of the first resistor R9, and the other end of the first capacitor C1 is grounded. The first resistor R9 and the first capacitor C1 can stabilize and buffer the first drive signal outputted by the upper bridge arm <NUM>-channel PWM circuit <NUM>.

Optionally, the second protection apparatus <NUM> includes a second resistor R10, a third resistor R11, and a second capacitor C2. One end of the second resistor R10 is connected to a bridge arm PWM circuit <NUM> (the lower bridge arm <NUM>-channel PWM circuit <NUM> shown in <FIG>), and the other end of the second resistor R10 is connected to the drive apparatus <NUM>. One end of the third resistor R11 is connected to one end of the second resistor R10, and the other end of the third resistor R11 is grounded. One end of the second capacitor C2 is connected to the other end of the second resistor R10, and the other end of the second capacitor C2 is grounded.

The second resistor R10, the third resistor R11, and the second capacitor C2 can stabilize and buffer the first drive signal outputted by the lower bridge arm <NUM>-channel PWM circuit <NUM>.

The resistance values of the first resistor R9, the second resistor R10, and the third resistor R11 can be selected according to actual needs, and these embodiments have no limitation on this.

The specifications of the first capacitor C1 and the second capacitor C2 can be selected according to actual needs, and these embodiments have no limitation on this.

In some optional embodiments, a circuit, which is used for transmitting the output signal of the first control apparatus <NUM> and is between the first control apparatus <NUM> and the second control apparatus <NUM>, includes a resistor R12 and a capacitor C3.

One end of the resistor R12 is connected to the output of the first control apparatus <NUM> (for example, connected to the lower bridge arm PWM circuit <NUM> shown in <FIG>), and the other end of the resistor R12 is connected to the pin of the second control apparatus <NUM>. One end of the capacitor C3 is connected to one end of the resistor R12, and the other end of the capacitor C3 is grounded. The resistor R12 and the capacitor C3 can stabilize the signal outputted by the first control apparatus <NUM>, and can filter out an impurity signal in the signal outputted by the first control apparatus <NUM>.

In summary, in the turn-off protection system provided by the above embodiments of the present application, the first control apparatus <NUM> controls the drive apparatus <NUM> of the compression apparatus <NUM> to stop outputting a drive signal when the system is in overpressure, thereby controlling the compression apparatus <NUM> to be turned off. During overpressure protection, there is no need to make software logic judgments. It is to use a signal to directly drive hardware to perform turn-off, fewer elements are needed, the response is faster and safer, the efficiency and success rates of turning off the compression apparatus <NUM> are improved, and the safety factors of the air conditioning system and heat pump system are improved.

It should also be noted that the type of power supply in the turn-off protection system provided in the above embodiments of the present application is not limited, and the power supply can be a unidirectional power supply.

Referring to <FIG>, a turn-off protection system <NUM> provided by some embodiments of the present application further includes the drive apparatus <NUM>. The model and specification of the drive apparatus <NUM> can be selected according to actual needs, and these embodiments have no limitation on this. The drive apparatus <NUM> determines the number of PWM circuits <NUM> in the first control apparatus <NUM>.

Referring to <FIG>, some embodiments of the present application further provide a heat pump apparatus <NUM>, where the heat pump apparatus includes the turn-off protection system <NUM> provided by any one of the above embodiments, as well as a compression apparatus <NUM> and a heat-exchange apparatus <NUM> for heating liquid water. The heat pump apparatus <NUM>, such as a heat pump swimming pool machine, is generally installed at an edge of a swimming pool to heat the water in the swimming pool. The compression apparatus <NUM> can be provided inside or outside of the heat-exchange apparatus <NUM>.

Referring to <FIG>, some embodiments of the present application further provide an electrical device <NUM>, where the electrical device <NUM> includes the heat pump apparatus <NUM> as provided in any one of the above embodiments, and may further include other apparatus, which is not limited in these embodiments.

Referring to <FIG>, some embodiments of the present application provide a driving system <NUM>, where the driving system <NUM> includes the turn-off protection system <NUM> as provided in any one of the above embodiments, and further includes a drive apparatus <NUM>. The drive apparatus <NUM> is connected to the compression apparatus <NUM> when in use, so as to output the second drive signal to the compression apparatus <NUM> after receiving the first drive signal outputted by the first control apparatus <NUM>, and then drive the compression apparatus <NUM> to operate. The model and specification of the drive apparatus <NUM> can be selected according to actual needs, and these embodiments have no limitation on this. The number of the PWM circuits <NUM> in the first control apparatus <NUM> is determined by the drive apparatus <NUM>. The driving system <NUM> may further include the pressure switch apparatus <NUM> as described above.

Referring to <FIG>, some embodiments of the present application provide an overpressure turn-off system <NUM>, where the overpressure turn-off system <NUM> includes the turn-off protection system <NUM> provided in any one of the above embodiments, and further includes a pressure switch apparatus <NUM>, where the pressure switch apparatus <NUM> is turned off when the system is detected to be overpressure, and outputs a pressure switch action signal. For the description of the pressure switch apparatus <NUM>, please refer to the description of the pressure switch apparatus <NUM> when describing the turn-off protection system <NUM> in the above embodiments, and it will not be repeated here. The overpressure turn-off system <NUM> can further include the drive apparatus <NUM> as described above.

It should be noted that in this description, the terms "includes", "comprises", or any other variation thereof are intended to cover non-exclusive inclusion, so that a process, method, article, or apparatus that includes a series of elements not only includes those elements, but further include other elements that are not explicitly listed, or include elements inherent in such process, method, article, or apparatus. Without limitations, the element limited by the statement "including a. " does not exclude the existence of another identical element in the process, method, article, or apparatus that includes this element.

Claim 1:
An overpressure turn-off system (<NUM>) for a system, the overpressure turn-off system (<NUM>) comprising:
a turn-off protection system (<NUM>); a drive apparatus (<NUM>) for a compression apparatus (<NUM>); and a pressure switch apparatus (<NUM>);
wherein the pressure switch apparatus (<NUM>) is configured to be turned off when the pressure of the system is detected to be overpressure and to output a pressure switch action signal;
wherein the turn-off protection system (<NUM>), comprises:
a first control apparatus (<NUM>), in signal connection with the pressure switch apparatus (<NUM>) and configured to output a first drive signal and further configured to stop outputting the first drive signal according to a pressure switch action signal, wherein the pressure switch apparatus (<NUM>) is configured to be turned off when a pressure of the system is detected to be overpressure and to output the pressure switch action signal, wherein the first drive signal for instructing the drive apparatus (<NUM>) to drive the compression apparatus (<NUM>) to operate; and
a second control apparatus (<NUM>), connected to the first control apparatus (<NUM>), and further connected to the drive apparatus (<NUM>) , wherein the second control apparatus (<NUM>) is for outputting a fault protection signal to the drive apparatus (<NUM>) upon obtaining the pressure switch action signal and the first drive signal from the first control apparatus (<NUM>), and the fault protection signal is used for controlling the drive apparatus (<NUM>) to stop outputting a second drive signal to the compression apparatus (<NUM>); and
wherein the drive apparatus (<NUM>) is configured to output the second drive signal to the compression apparatus (<NUM>) after receiving the first drive signal, wherein the second drive signal is used for driving the compression apparatus (<NUM>) to operate.