阅读说明：本技术 压缩机的控制装置、压缩机及空调系统 (Compressor control device, compressor and air conditioning system ) 是由 S.谢尔纳 P.K.扎瓦德兹基 D.多姆克 郭正命 金镕熙 于 2020-04-24 设计创作，主要内容包括：一种压缩机控制模块CCM,适于控制可变排量斜盘压缩机的输出,包括：直接计算或从如HVAC控制单元的外部源接收信号,其指示来自可变排量斜盘压缩机的期望或要求输出,即控制目标或设定值；接收值的当前/实际值；接收或计算可变排量斜盘压缩机的斜盘相对于旋转轴线的当前旋转速度和角度或当前活塞冲程长度及其往复频率；可选地接收或计算压缩机、空调系统或来自车辆的额外当前值；确定来自可变排量斜盘压缩机的期望或要求输出与可变排量斜盘压缩机的当前输出之间的差；和向阀驱动单元输出一信号,其将调整斜盘(48)的角度,以使可变排量斜盘压缩机的实际输出更接近或等于在步骤a)中获得的期望或要求输出,还考虑在c)和d)中接收或计算的额外值。(A compressor control module CCM adapted to control the output of a variable displacement swash plate compressor comprising: calculating directly or receiving a signal from an external source, such as an HVAC control unit, indicative of a desired or required output, i.e., a control target or set point, from the variable displacement swash plate compressor; receiving a current/actual value of a value; receiving or calculating a current rotation speed and angle of a swash plate of the variable displacement swash plate compressor relative to a rotation axis or a current piston stroke length and a reciprocating frequency thereof; optionally receiving or calculating additional current values of the compressor, the air conditioning system, or from the vehicle; determining a difference between a desired or requested output from the variable displacement swash plate compressor and a current output of the variable displacement swash plate compressor; and outputting a signal to the valve drive unit that will adjust the angle of the swash plate (48) such that the actual output of the variable displacement swash plate compressor is closer to or equal to the desired or required output obtained in step a), taking into account the additional values received or calculated in c) and d).)

1. A compressor control module, CCM, adapted to control the output of a variable displacement swash plate compressor, wherein the CCM is adapted to:

a) calculating directly or receiving from an external source, such as an HVAC control unit, a signal indicative of a desired or required output from a variable displacement swash-plate compressor (30), such as, but not limited to, suction pressure, piston stroke length, evaporator outlet air temperature, refrigerant mass flow, and/or work done on fluid;

b) Receiving a current/actual value of the value described in a);

c) receiving or calculating, respectively, a current rotational speed and angle of a swash plate (48) of the variable displacement swash plate compressor relative to a rotational axis or a current piston stroke length and a reciprocating frequency thereof;

d) optionally receiving or calculating additional current values of the compressor, air conditioning system or from the vehicle, such as discharge pressure, crankcase pressure, pressure difference between suction pressure and crankcase pressure, evaporator outlet air temperature and/or engine speed;

e) determining a difference between a desired or requested output from the variable displacement swash plate compressor and a current output of the variable displacement swash plate compressor; and

f) outputting a signal to the valve drive unit that will adjust the angle of the swash plate (48) to bring the actual output of the variable displacement swash plate compressor closer to or equal to the desired or required output obtained in step a), taking into account the additional values received or calculated in c) and d).

2. The CCM of claim 1 further adapted to repeat steps a) through f) until the current output of the variable displacement swash plate compressor is closer to or equal to the desired or required output from a); and is

Wherein said CCM is preferably adapted to perform steps a) to f) in a given order.

3. The CCM of claim 1 or claim 2 wherein the CCM is further adapted to manipulate a desired or required output of the variable displacement swash plate compressor received in step a) based on one or more values received in c) and/or d).

4. Compressor control module CCM according to any of the preceding claims, wherein upper and/or lower threshold differences between crank chamber pressure and suction pressure difference (Pc-Ps) are stored while the derivative of the piston stroke length is not zero or differs from a certain tolerance band around zero, wherein exceeding the upper threshold will result in an increase of the Swashplate (SWP) angle, and wherein falling below the lower threshold will result in a decrease of the SWP angle; and

wherein the upper and/or lower threshold difference or a function of the upper and/or lower threshold difference is used for accurate SWP angle control.

5. The compressor control module CCM of any one of the preceding claims, wherein compressor rotational speed and/or a derivative thereof is fed forward to the CCM in order to adjust inputs and/or outputs of one and/or more controller circuits to improve dynamic performance under varying compressor RPM.

6. Compressor control module CCM according to any of the preceding claims,

Wherein the signal to the valve drive unit is generated at least in part by an output of a Model Predictive Control (MPC), an IMC, an online predictive controller such as a neural network, and/or a multiple-input-single-output (MISO) controller.

7. Compressor control module CCM according to any of the preceding claims,

wherein the signal to the valve drive unit is at least partly generated by an output of the PID controller, wherein the determined difference in step e) is preferably an input signal to the PID controller.

8. The compressor control module CCM of claim 7,

wherein at least one gain parameter of the PID controller is adjusted at least partially based on one or more measured or calculated values of the compressor, such as suction chamber pressure and/or discharge chamber pressure and/or piston stroke length and/or piston reciprocation frequency and/or opening of the control valve.

9. The compressor control module CCM of claim 8,

wherein the P parameter and/or the I parameter and/or the D parameter are lower when the suction chamber pressure is low compared to when the suction chamber pressure is high; and/or

When the discharge chamber pressure is high, the P parameter and/or the I parameter and/or the D parameter are lower than when the discharge chamber pressure is lower; and/or

The P-parameter and/or the I-parameter and/or the D-parameter are higher when the piston stroke length is small compared to when the piston stroke length is larger.

10. A variable displacement swash plate compressor, wherein the CCM of any one of the preceding claims is an integral part of the variable displacement swash plate compressor.

11. The variable displacement swash plate compressor according to claim 10, wherein the variable displacement swash plate compressor does not include a bleed port or a bleed valve, or a bleed port having a reduced diameter, between any suction chamber (31) and the crank chamber (21).

12. The variable displacement swash plate compressor of claim 10 or 11, wherein the variable displacement swash plate compressor comprises at least one speed-stroke sensor, wherein the speed-stroke sensor may be adapted to monitor the amount of reciprocation speed and piston stroke length of one or more pistons of the variable displacement swash plate compressor and send this measurement to the CCM, wherein the CCM is adapted to calculate the current angle of the swash plate and/or the piston stroke length of the variable displacement swash plate compressor based on the amount of stroke of the one or more pistons and calculate the swash plate and compressor rotation speed (RPM) based on the reciprocation speed of the pistons.

13. The variable displacement swash plate compressor of any one of claims 10 to 12, wherein the variable displacement swash plate compressor comprises an electronically controlled valve (100) connected to the CCM and adapted to direct pressure from the crank chamber (21) to the one or more suction chambers (31) or from the discharge chamber (33) to the crank chamber (21) of the variable displacement swash plate compressor in response to receiving an output signal from the CCM at step f) to thereby change the angle of the swash plate (48).

14. An air conditioning system comprising a variable displacement swash plate compressor according to any one of claims 10 to 13.

15. The air conditioning system of claim 14, wherein the air conditioning system is used in an automobile, further wherein,

the CCM or air conditioning system is adapted to be operated to ensure that the temperature in the cabin of the vehicle is maintained at a desired or set temperature by a user of the vehicle by controlling the suction pressure or coolant output of the variable displacement swash plate compressor.

16. The air conditioning system of claim 14 or 15,

the desired output of the variable displacement swash plate compressor is the amount of work done on the coolant and it remains constant regardless of the driving force and rotational speed of the variable displacement swash plate compressor.

Technical Field

The present application relates to a compressor control module for controlling operation of a variable displacement swash plate compressor, a variable displacement swash plate compressor including the same, and an air conditioning system.

Background

Generally, an air conditioning system for a vehicle is equipped with a refrigerant compression cycle system for cooling and/or heating. The core of the refrigerant compression cycle is a compressor that compresses and circulates a refrigerant in the refrigerant cycle. The compressor is typically configured to maintain the pressure in the evaporator at a low level. The pressure in the evaporator is directly related to the temperature of the saturated refrigerant throttled into the evaporator, so by keeping the pressure low, the compressor keeps the temperature in the evaporator low.

Variable displacement swash plate compressors are popular in vehicle air conditioning systems. Variable displacement swash plate compressors are typically driven by a belt driven vehicle engine. The compressor output (such as compressor load or work done by the compressor on the fluid) can be adjusted by changing the angle of the swash plate.

The variable displacement swash plate compressor is configured such that the inclination angle of the swash plate affects the reciprocating length of the compression pistons. The angle of inclination of the swash plate is in turn typically adjusted by varying the pressure difference between the crank chamber and its suction chamber of the variable displacement swash plate compressor. That is, when the pressure in the crank chamber is increased by introducing the high-pressure working fluid from the discharge chamber to the crank chamber, the pressure difference (Pc-Ps) between the crank chamber and the suction chamber is increased, and the swash plate angle is decreased (i.e., moved perpendicular to the main shaft), so that the stroke of the piston is decreased. Thus, when the pressure in the crank chamber decreases, the swash plate angle increases and the stroke of the piston increases, resulting in an increase in compressor mass flow.

Disclosure of Invention

The present application is a continuation of the invention disclosed in korean patent application KR10-2018-0010891 and discloses a Compressor Control Module (CCM) to further improve the regulation of the compressor, wherein the suction pressure can be regulated according to the required cooling effect.

The present disclosure includes a first communication passage (referred to as "P1" in KR10-2018 and 0010891) connecting a suction chamber and a crank chamber of a variable displacement swash plate compressor and a second communication passage (referred to as "P2" in KR10-2018 and 0010891) connecting a discharge chamber and the crank chamber of the variable displacement swash plate compressor. It also discloses a four-way control valve for selectively opening and closing the first communication passage and the second communication passage so that a bleed port may be closed or substantially closed.

By allowing the pressure to be adjusted in both directions, the bleed port can be reduced or closed, thereby greatly increasing efficiency. However, closing the bleed port makes the system less stable and small changes in the opening of the control valve may result in large changes in the swash plate angle. Closing or substantially closing the bleed port increases efficiency but complicates system control. The present invention describes a solution how to control the compressor precisely in case the bleed port is closed or substantially reduced.

This object is solved by a Compressor Control Module (CCM) according to claim 1, a variable displacement swash plate compressor according to claim 10 and an air conditioning system according to claim 14.

In particular, this object is solved by a compressor control module CCM adapted to control the output of a variable displacement swash plate compressor, wherein the CCM is adapted to:

a) Calculating a signal directly or receiving a signal from an external source, such as an HVAC control unit, that is indicative of a desired or required output from the variable displacement swash plate compressor, also referred to as a control target or set point, such as, but not limited to, suction pressure, piston stroke length, evaporator outlet air temperature, refrigerant mass flow, and/or work done on fluid;

b) receiving a current/actual value of the value described in a);

c) receiving or calculating a current rotation speed and angle of a swash plate of the variable displacement swash plate compressor with respect to a rotation axis or a current piston stroke length and a reciprocating frequency thereof, respectively;

d) optionally receiving or calculating additional current values of the compressor, air conditioning system or from the vehicle, such as discharge pressure, crankcase pressure, pressure difference between suction pressure and crankcase pressure, evaporator outlet air temperature and engine speed;

e) determining a difference between a desired or requested output from the variable displacement swash plate compressor and a current output of the variable displacement swash plate compressor; and

f) outputting a signal to the valve drive unit that will adjust the angle of the swash plate to bring the actual output of the variable displacement swash plate compressor closer to or equal to the desired or required output obtained in step a), taking into account the additional values received or calculated in c) and d).

Advantages include precise control of the compressor with the bleed port closed or significantly reduced.

Controller parameters of one or more controllers may be advantageously adjusted during operation. This may depend on certain system variables (such as Ps, piston stroke length, RPM, Pd, evaporator air outlet temperature, humidity, etc.).

In an embodiment, the compressor control module CCM is adapted to repeat steps a) to f) until the current output of the variable displacement swash plate compressor is closer to or equal to the desired or required output from a); and is

Wherein the CCM is preferably adapted to perform steps a) to f) in a given order.

In an embodiment, the CCM is further adapted to manipulate the desired or required output of the variable displacement swash plate compressor received in step a) based on one or more values received in c) and/or d).

For step a), the CCM may be adapted to receive a desired or required output (control target value) of the variable displacement swash plate compressor and to manipulate that value based on one or more values received in c) and/or d).

In one embodiment, upper and/or lower threshold differences between crank chamber pressure and suction pressure difference (Pc-Ps) are stored while the derivative of piston stroke length is not zero or differs from some tolerance band around zero, wherein exceeding the upper threshold will result in an increase in Swashplate (SWP) angle, and wherein falling below the lower threshold will result in a decrease in SWP angle; and is

Wherein the upper and/or lower threshold difference or a function of the upper and/or lower threshold difference is used for accurate SWP angle control.

In one embodiment, the compressor rotational speed and/or derivative thereof is fed forward to the CCM to adjust the inputs and/or outputs of one and/or more controller loops to improve dynamic performance under varying compressor RPM.

In an embodiment, the signal to the valve drive unit is generated at least in part by the output of a Model Predictive Control (MPC), an IMC, an online predictive controller such as a neural network, and/or a multiple-input-single-output (MISO) controller.

In an embodiment, the signal to the valve drive unit is at least partly generated by an output of a PID controller, wherein the determined difference in step e) is preferably an input signal to the PID controller.

In an embodiment, at least one gain parameter of the PID controller is adjusted at least partially based on one or more measured or calculated values of the compressor, such as suction chamber pressure and/or discharge chamber pressure and/or piston stroke length and/or piston reciprocation frequency and/or opening of the control valve

In one embodiment, the P-parameter and/or I-parameter and/or D-parameter is lower when the suction chamber pressure is low compared to when the suction chamber pressure is higher; and/or

When the discharge chamber pressure is high, the P parameter and/or the I parameter and/or the D parameter are lower than when the discharge chamber pressure is lower; and/or

The P-parameter and/or the I-parameter and/or the D-parameter are higher when the piston stroke length is low compared to when the piston stroke length is higher.

In one embodiment, the CCM is an integral part of a variable displacement swash plate compressor.

In one embodiment, the variable displacement swash plate compressor does not include a bleed port or valve, or a bleed port with a reduced diameter, between any of the suction chamber and the crank chamber.

In an embodiment, the variable displacement swash plate compressor comprises at least one speed-stroke sensor, wherein the speed-stroke sensor may be adapted to monitor the amount of reciprocation speed and piston stroke length of one or more pistons of the variable displacement swash plate compressor and send this measurement to the CCM, wherein the CCM is adapted to calculate the current angle of the swash plate and/or the piston stroke length of the variable displacement swash plate compressor based on the amount of stroke of the one or more pistons and to calculate the swash plate and compressor rotation speed (RPM) based on the reciprocation speed of the pistons.

In an embodiment, the variable displacement swash plate compressor comprises an electronically controlled valve (100) connected to said CCM and adapted to direct pressure from the crank chamber (21) to the suction chamber(s) (31) or from the discharge chamber (33) to the crank chamber (21) of the variable displacement swash plate compressor in response to receiving an output signal from the CCM at step f), thereby changing the angle of the swash plate (48).

In one embodiment, a variable displacement swash plate compressor is part of an air conditioning system.

In one embodiment, the air conditioning system is used in an automobile, and further wherein,

the CCM or air conditioning system is adapted to operate to ensure that the temperature in the cabin of the vehicle is maintained at a desired or set temperature by a user of the vehicle by controlling the suction pressure or coolant output of the variable displacement swash plate compressor.

In one embodiment, the desired output of the variable displacement swash plate compressor is the amount of work done on the coolant and it remains constant regardless of the driving force and rotational speed of the variable displacement swash plate compressor.

For calculating the target value, other external signals may be considered, such as the target and actual values of the external air conditions (such as temperature and humidity), the sun load (sun load) of the vehicle, and the evaporator air outlet temperature.

The variable displacement swash plate compressor may not include a bleed port or valve, or at least a reduced diameter bleed port or valve, between any of the suction and crank chambers.

By removing the bleed port or valve or reducing its diameter, the efficiency of the compressor is increased due to reduced internal pressure losses, thus saving fuel.

The signal output from the CCM at step f) may cause the variable displacement swash plate compressor to vary the pressure in the crank chamber to vary the angle of the swash plate to increase or decrease the output of fluid (such as compressor mass flow output) from the variable displacement swash plate compressor.

The signal output from the CCM at step f) may affect a valve driving unit that drives an actuator that drives the valve body to open one of the communication passages. The first passage opens PcPs and increases the angle. The second passage is opened PdCc to reduce the swash plate angle.

The variable displacement swash plate compressor may include at least one speed-stroke sensor, wherein the speed-stroke sensor may be adapted to monitor an amount of piston stroke length and reciprocating speed of one or more pistons of the variable displacement swash plate compressor and send this measurement to the CCM, wherein the CCM is adapted to calculate a current angle of the swash plate and/or the piston stroke length of the variable displacement swash plate compressor based on the amount of stroke of the one or more pistons and calculate a swash plate and compressor rotation speed (RPM) based on the reciprocating speed of the pistons.

The variable displacement swash plate compressor may comprise at least one crank chamber pressure sensor, wherein the CCM is (optionally) adapted to use this information in step d).

The variable displacement swash plate compressor may comprise at least one suction pressure sensor measuring the suction pressure, wherein the CCM may be adapted to use this information for step b).

The variable displacement swash plate compressor may comprise at least one incremental pressure sensor measuring the pressure difference between the crankcase pressure and the suction pressure, wherein the CCM is (optionally) adapted to use this information for step d).

The CCM (or a portion of the CCM control algorithm) may be integrated into an AC system controller (AC ECU). This can reduce costs.

The TXV can control the evaporator superheat temperature by adjusting the mass flow. The compressor controls the suction pressure which may be closely related to the evaporator temperature.

The control algorithm of the CCM may be located on a PCBA that includes a microcontroller, a valve drive unit, a power supply, an input unit to read sensors, and a communication unit for transmitting information to and/or receiving information from the AC ECU and/or the engine ECU.

Drawings

The above and other aspects, features and advantages of the present disclosure will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings in which:

fig. 1 is a sectional view showing an internal structure of a variable displacement swash plate compressor including a first communication passage P1, a second communication passage P2, and a control valve 100;

Fig. 2 is a graph showing the change in the opening degrees of the first and second communication passages with the movement of the valve body;

FIG. 3 shows a schematic diagram of closed loop control according to an embodiment of the invention;

FIG. 4 is a graph showing changes in suction pressure and valve opening during an increase in the inclination angle of the swash plate in the embodiment shown in FIG. 1;

FIG. 5 is a graph showing changes in suction pressure and valve opening during a process of decreasing the inclination angle of the swash plate in the embodiment shown in FIG. 1;

FIG. 6 shows a flow chart of a method that may be used in a CCM to control the current output of a variable displacement swash plate compressor;

FIG. 7 illustrates a control according to an embodiment of the invention;

FIG. 8 illustrates a control according to an embodiment of the invention;

FIG. 9 illustrates a control according to an embodiment of the invention;

fig. 10 shows a control according to an embodiment of the invention.

Detailed Description

To improve controllability, a feed forward function may be required, meaning that the compressor RPM value is used as an input to the controller to improve the dynamic performance as the compressor RPM changes.

In one embodiment, compressor RPM and/or a derivative thereof is used as an input for a feed forward function to adjust the target piston stroke length value, such as by increasing or decreasing certain values.

In an embodiment, the adjustment may also occur at a different location of the control circuit, for example at the controller output value.

A feed forward function may also be used with respect to fig. 7, 8 and 9 to further improve dynamic performance. The additional Ps information can be used to prevent the evaporator from freezing.

In certain embodiments, depending on certain system variables (such as Ps, piston stroke length, RPM, Pd, evaporator air outlet temperature, humidity, etc.), it may be advantageous to adjust one or more controller parameters of the controller during operation.

For example, the PID parameters (proportional, integral and differential parameters) can be adjusted depending on the current Ps and/or Pd and/or the piston stroke length and/or the opening degree (openlevel) of the control valve. If Ps is lower, the P-parameter and/or I-parameter and/or D-parameter may be different than if Ps pressure is higher, since less control gas is drawn from the crank chamber for higher Ps. If Pd is higher, the P-parameter and/or I-parameter and/or D-parameter may be lower than if Pd pressure is lower, since for higher Pd more control gas will be delivered to the crank chamber.

If the piston stroke length is short, the P-parameter and/or I-parameter and/or D-parameter may be higher than for a larger stroke case.

Depending on the control deviation of the outer control loop, it may be advantageous to adjust the I parameter to increase the response of the controller. For example, if the control deviation is greater than a predefined limit, the I parameter may be set to a larger value than a smaller control deviation.

Furthermore, to improve controllability, a feed forward function may be advantageous for any of the embodiments described herein.

This is because a rapid RPM change causes Ps to increase or decrease. Without using these RPM changes as input values to the controller, the response of the controller to such RPM changes is very slow, since the suction pressure response is very slow (system dependent). In this case, the Ps pressure is logically varied, which may lead to increased energy consumption due to an unexpected ramp (ramp) of Ps level/mass flow.

The compressor RPM value is used as an input for the controller to improve the dynamic performance as the compressor RPM changes.

For example, compressor RPM and/or a derivative thereof may be used as an input to a feed forward function to adjust the input and/or output of one or more controller loops.

Although the exemplary embodiments are described above, the scope of the present disclosure is not limited to the specific embodiments, and the present disclosure may be appropriately changed within the scope described in the claims. For example, the suction pressure sensor 401 may be disposed at one of a suction chamber of the compressor, an outlet end of the evaporator, and a working fluid pipe between the evaporator and the compressor.

Although cascade control, PI, PID are mentioned in the examples, any other type or configuration of control mechanism may be used as appropriate by those skilled in the art, such as Model Predictive Control (MPC), IMC, online predictive controller such as a neural network, Multiple Input Single Output (MISO) controller.

Hereinafter, embodiments of a Compressor Control Module (CCM), a variable displacement swash plate compressor having the CCM, and an air conditioning system including the CCM and the air conditioning system according to the present disclosure will be described in detail with reference to the accompanying drawings.

An example of a variable displacement swash plate compressor is shown in fig. 1. The example variable displacement swash plate compressor may include: a center hole 11 formed through the center of the cylinder housing 10; and a plurality of cylinder bores 13 formed through the cylinder around the center hole 11. The piston 15 may be movably disposed in the cylinder bore 13 and compress a working fluid in the cylinder bore 13.

The front housing 20 may be coupled to an end of the cylinder housing 10. The front housing 20 may form a crank chamber 21 therein together with the cylinder housing 10. A suction chamber 31 selectively communicating with the cylinder bore 13 may be formed in the rear housing 30. The suction chamber 31 may transmit the working fluid to be compressed into the cylinder bore 13.

The discharge chamber 33 may be formed in the rear housing 30. The four-way control valve 100 may be provided at one side of the rear housing 30. The control valve 100 adjusts the angle of the swash plate 48 by alternately adjusting the opening degree of a flow path (P1) between the crank chamber 21 and the suction chamber 31 and the opening degree of a flow path (P2) between the discharge chamber 33 and the crank chamber 21.

The rotation shaft 40 is rotatably provided to pass through the center hole 11 of the cylinder housing 10 and the shaft hole 23 of the front housing 20. The rotary shaft 40 may be rotated by power from an engine (not shown). The rotary shaft 40 may be rotatably provided in the cylinder housing 10 and the front housing 20 through a bearing 42.

A rotor 44 having a rotation shaft 40 passing through the center thereof to rotate integrally with the rotation shaft 40 is provided in the crank chamber 21. The rotor 44 is formed in a substantially disk shape and fixed to the rotation shaft 40, and a protruding hinge arm (not shown) may be formed at one side of the rotor 44.

The swash plate 48 may be hinged to the rotor 44 on the rotary shaft 40 to rotate together. The swash plate 48 may be disposed such that an angle is variable with respect to the rotary shaft 40 according to a discharge capacity (discharge capacity) of the compressor. That is, the swash plate 48 may be moved between a position perpendicular to the axis of the rotary shaft 40 and a position inclined at a predetermined angle with respect to the rotary shaft 40. The swash plate 48 may be connected to the pistons 15 at edges by shoes (not shown). That is, the edge of the swash plate 48 is connected to the connection portion 17 of the piston 15 through the shoe, so that the piston 15 is reciprocated in the cylinder hole 13 by the rotation of the swash plate 48.

A half tilt spring (not shown) providing elasticity may be provided between the rotor 44 and the swash plate 48. The half-tilt spring may be disposed around the outside of the rotating shaft 40 and provide elasticity to cause the tilt angle of the swash plate 48 to decrease.

In fig. 1, a path connecting the crank chamber 21 and the suction chamber 31 is defined as a first communication passage P1, and a path connecting the discharge chamber 33 and the crank chamber 21 is defined as a second communication passage P2. These passages are indicated by arrows in fig. 1, and the working fluid flows in the direction indicated by the arrows due to the pressure difference between the suction chamber, the crank chamber, and the discharge chamber.

When the first communication passage P1 is opened, the crank chamber and the suction chamber communicate with each other, so that the pressure in the crank chamber is reduced. Therefore, the inclination angle of the swash plate is increased, and the stroke of the piston is increased. Further, when the second communication passage P2 is opened, the crank chamber and the discharge chamber communicate with each other, so that the pressure in the crank chamber increases. Therefore, the inclination angle of the swash plate is decreased and the stroke of the piston is decreased.

Referring to fig. 2, the horizontal axis represents the movement distance of the valve body of the four-way control valve, and the vertical axis represents the opening degrees of the first communication passage (P1) and the second communication passage (P2).

In the left area, it is shown that when the valve body moves downward, the second communication passage P2 is gradually closed until it is completely closed. In the right side area, it is shown that the first communicating passage P1 is gradually opened when the valve body is moved downward. The opposite portions of the first and second communication passages that are open and closed appear in the area around the origin, and it should be noted that preferably there is no portion in which both communication passages are open, since this would result in a large leakage of the refrigerant fluid via the crank chamber. The bleed port may not be fully closed for ease of control. This will result in both channels being slightly open at the same time. This increases controllability.

In this embodiment, the control valve does not use the entire portion shown in fig. 2, but operates in a region indicated by "control portion". Depending on the leakage from the discharge chamber to the crank chamber above the piston, most of the control parts are located in the part: the opening/closing of the first communication passage P1 is regulated. This is in contrast to the prior art, where control is performed by opening a passage between the discharge chamber and the crank chamber.

The goal of control of the control valve may be to achieve a certain suction chamber pressure required by the HVAC system. In order to improve the accuracy of the achieved suction pressure in case the discharge opening is closed, a pressure sensor may be included on the evaporator side of the refrigeration cycle, preferably in the suction chamber of the compressor. The sensor measures the suction pressure. A control unit having a controller, such as a PI/PID controller, may further be included and configured to adjust the control valve to close the gap between the target and actual suction pressures. Feedback of suction pressure in a closed loop improves the stability and accuracy of suction pressure control. However, a considerable delay in the refrigeration cycle may cause controllability problems and complicate the control.

As shown in fig. 3, the Compressor Control Module (CCM) may be part of a vehicle Heating Ventilation and Air Conditioning (HVAC) system.

The HVAC control module may receive a passenger cooling demand. The HVAC control module, in turn, provides a target value for the CCM, which controls the control valve of the compressor. The sensor values are fed back to the CCM to improve compressor control.

The compressor may affect the pressure in the evaporator and the evaporator air outlet temperature, which may be measured and provided to the HVAC control module.

Feedback from the swashplate angle measurement may be faster than feedback from the suction pressure sensor. In general, feedback from the swash plate angle can be much faster than feedback from the suction pressure sensor in response to compressor load changes.

Using sensors to provide information for calculating the current swash plate position and/or compressor mass flow solves the problem associated with refrigeration cycle delay. In addition, by measuring the swash plate angle, problems caused by hysteresis, such as due to swash plate friction, are significantly reduced. This allows for faster and more accurate control of the compressor.

FIG. 4 is a graph illustrating suction pressure adjustment and valve opening change in response to an increased cooling demand according to an embodiment of the present invention. Enhanced cooling is desirable due to user selection or other reasons. The CCM (and/or HVAC system) determines the suction pressure to achieve the corresponding cooling effect and sets the target suction pressure accordingly. The target suction pressure is input to the control unit. The suction pressure set point is shown in dashed lines in fig. 4.

Then, the control unit applies a control input to the electrically controlled valve by applying a current to the electromagnetic actuator, so that the opening degree of the first communication passage P1 increases. When the first communication passage P1 increases, the crank chamber and the suction chamber communicate with each other, so that the pressure in the crank chamber decreases. The inclination angle of the swash plate is increased and thus the stroke of the piston is increased. This increases the load of the compressor (assuming that the rotational speed of the swash plate is constant), and causes a pressure decrease on the evaporation side of the refrigeration cycle. The measured suction pressure is reduced and using the control algorithm of the controller, the control unit is configured to adjust the input to the control valve in order to maintain the target suction pressure.

Fig. 5 is a graph illustrating a change in suction pressure and a change in valve opening during a reduction in piston stroke according to an embodiment of the present invention. The cooling required is reduced due to user selection or other reasons. To reduce cooling, the stroke length of the piston may be reduced, as described above. For this reason, the control unit (such as an AC ECU) determines the suction pressure at which the corresponding stroke is available, and sets the suction pressure as the target suction pressure. The suction pressure set point is shown in dashed lines in fig. 5. When the target suction pressure value becomes a higher value (i.e., lower cooling), the current applied to the electromagnetic actuator is reduced or blocked according to the instruction of the control unit, so the first communication passage is closed and the second communication passage is opened. When the second communication passage P2 is opened, the crank chamber and the discharge chamber communicate with each other, so that the pressure in the crank chamber increases. Therefore, the inclination angle of the swash plate is decreased and the stroke of the piston is decreased. The output of the compressor decreases, resulting in a decrease in evaporator temperature.

The above relates to solenoid actuators. The skilled person can easily adapt the invention to use a step actuator or any other suitable actuator.

If the P2 passage is open long enough, the pressure in the crank chamber will be the same as the discharge pressure, causing the angle of inclination of the swash plate to decrease to its minimum. In the case where the compressor does not keep the suction pressure low, the pressure in the evaporator may rise due to heating and additional refrigerant entering through the thermal expansion valve. When the suction pressure reaches the target value, current will be applied to the actuator again to increase the stroke length to maintain the proper suction pressure.

As shown in fig. 4 and 5, a constant level of P1 opening may be required at a fixed suction pressure to compensate for leakage into the crank chamber inside the cylinder.

Example sensors that provide information that may be used to calculate the current compressor mass flow rate include sensors that provide information about the swash plate rotation speed and angle.

Another example of sensors that provide information that may be used to calculate the current swash plate angle and/or compressor mass flow rate includes sensors that provide information about the frequency of piston reciprocation and the stroke length. The current swash plate angle and/or compressor mass flow rate may be measured and/or calculated in other ways.

The swash plate rotation speed may be the same as the piston reciprocation frequency. The swash plate angle may be derived from the piston stroke length from preset data regarding the compressor configuration including the swash plate and piston arrangement.

FIG. 6 depicts a flow chart of a method that may be used by the CCM to control the output of a variable displacement swash plate compressor (e.g., current compressor work) by:

a) calculating a signal directly or receiving (610) a signal from an external source (e.g., an HVAC control unit) that represents a desired or required output from the variable displacement swash plate compressor, such as, but not limited to, suction pressure, piston stroke length, evaporator outlet air temperature, refrigerant mass flow, and/or work done on the fluid;

b) receiving (620) the current/actual value of the value described in a);

c) receiving or calculating (630) a current rotational speed and angle of a swash plate of the variable displacement swash plate compressor relative to a rotational axis or a current piston stroke length and a reciprocating frequency thereof, respectively;

d) optionally receiving or calculating (640) additional current values of the compressor, air conditioning system, or from the vehicle, such as, but not limited to, discharge pressure, crankcase pressure, pressure differential between suction pressure and crankcase pressure, evaporator outlet air temperature, engine speed;

e) Determining (650) a difference between a desired or requested output from the variable displacement swash plate compressor and a current output of the variable displacement swash plate compressor; and

f) outputting (660) a signal to the valve drive unit that will adjust the angle of the swash plate to bring the actual output of the variable displacement swash plate compressor closer to or equal to the desired or demanded output obtained in step a), taking into account the additional values received or calculated in c) and d).

In closed loop control, which may include the use of input signals from additional sensors, the present CCM may drive a control valve to adjust the pressure ratio between Pc and Ps to adjust the swash plate angle and the output of the compressor.

In one example, the CCM contains an automatic control algorithm that includes an inner loop that regulates the control valve actuators to achieve a certain swash plate angle and/or compressor discharge rate that is set in a cascade fashion by the outer control loop. The inner circuit may be closed by an input from a sensor that provides a measurement for determining the swash plate angle or current compressor discharge rate. The delay may be relatively small, e.g., well below a one second delay, compared to the delay from the suction pressure sensor.

An embodiment for regulating suction pressure using an inner circuit for adjusting the angle of the swash plate is shown in fig. 7. The inner loop may include a PID controller that regulates the piston stroke length. The inner control loop feedback delay time is typically well below one second.

The outer loop may include a refrigeration cycle and a PID controller that adjusts Ps relative to a target Ps set point from the HVAC control system. The inner loop may include piston stroke length feedback. The outer loop may include Ps sensor feedback from a pressure sensor on the suction side of the refrigeration cycle (preferably in the suction chamber of the compressor).

The delay in the outer loop is longer than in the inner loop, depending on the a/C system. Piston stroke length feedback is much faster than using only suction pressure measurement feedback. Measuring the piston stroke length can significantly improve the stability and response time of the control system. Direct piston stroke length feedback also overcomes the difficulty in controlling swashplate motion due to friction. The incorrect position of the swash plate can be measured and the control valve opening adjusted accordingly until the correct swash plate angle is achieved.

Additionally, the swashplate position may be monitored before and/or during operation, and if the swashplate does not attempt to account for changes in control valve changes as expected, a fault may be detected.

The example CCM may also include a piston reciprocation speed sensor. Measurements from the piston reciprocation speed sensor may provide information about the frequency of piston reciprocation to the inner and/or outer controller in a feed forward manner to inhibit engine rpm changes in advance, thereby allowing the control valve to be adjusted so that the stroke length compensates for the increased frequency of piston reciprocation to maintain a constant working load placed on the fluid. If the engine speed suddenly increases, the increased compressor speed will feed forward, for example, to the inner loop and the stroke length will decrease, thereby preventing a peak in compressor output. Otherwise, the peaks would result in torque peaks and unnecessary cooling, and waste energy.

As an example, the piston reciprocation frequency and piston stroke length of the piston may be calculated from signals received from at least one speed-stroke sensor, such as the speed-stroke sensor described in european patent application 19159899.4.

Without using information about the rotational speed of the swash plate (such as feed forward swash plate rotational speed), the controller can recognize a change in compressor speed only after a change in suction pressure occurs. In this case, if the speed of the compressor is increased due to a change in the engine rpm, the cooling effect of the air conditioning system will be too high until the suction pressure stabilizes around the higher desired level/value, resulting in passenger discomfort and wasted energy. By sensing and responding to changes in compressor rotational speed (such as by feed forward), the CCM can react to speed changes earlier.

Examples of piston positioning sensors and piston speed sensors include eddy current sensors, cylinder pressure sensors, hall sensors, magnetoresistive sensors, capacitance-based sensors, and inductance-based sensors.

By using the piston stroke length information corresponding to the swash plate angle in the internal control circuit of the cascade controller, the piston stroke length can be directly controlled. This greatly improves the quality of control.

The difference between the crank chamber pressure and the suction chamber pressure value (Pc-Ps) can also be used instead of the piston length information of the second control loop.

FIG. 8 depicts a control according to an embodiment of the invention. Additional sensors are included to measure crank chamber pressure. The pressure difference (Pc-Ps) between the crankcase pressure and the suction pressure is calculated from fig. 8 and used as an actual value of the third controller.

In order to change the swash plate (SWP) angle, the pressure difference between Pc and Ps (Pc-Ps) must be below or above some threshold. Lower values of Pc-Ps pressure increase the SWP angle, and higher values of Pc-Ps pressure decrease the SWP angle.

If Pc-Ps are between the upper and lower thresholds, the SWP does not move at all due to static friction.

The use of Pc-Ps further improves the control behavior in terms of response time and control quality, since Pc-Ps is directly responsible for swashplate motion.

The input to the first controller in figure 8 is the difference between the suction chamber target pressure value and the measured suction chamber pressure value (in "barA").

The output signal of the first controller is indicative of a target piston stroke length compared to the measured value. The difference is used as an input (in "mm") to the second controller. The second controller uses the difference value to output a target pressure difference (Pc-Ps) between the crank chamber and the suction chamber.

This output signal of the second controller is compared to the measured Pc-Ps value and the difference is used as an input to a third controller which adjusts the electric control valve to reach this value.

The output value of the second controller, which is the Pc-Ps value, has no upper or lower limit and depends on the control deviation (input) of the second controller and its control parameters.

FIG. 9 depicts a control according to an embodiment of the invention. Since the Pc-Ps thresholds for increasing and decreasing the SWP angle depend on different parameters (RPM, stroke, friction, temperature, etc.), it is an advantage to know the exact threshold.

For example, under certain conditions, the controller adjusts the compressor to decrease the SWP angle (by opening the PdPc passage while the PsPc passage remains closed). If Pd is high, or if the PID parameters have a significant gain in this case, the amount of control gas passing through the PdPc channel can be quite large, resulting in a high Pc pressure increase, and therefore the Pc-Ps pressure will also increase rapidly, and will far exceed the current Pc-Ps threshold (which may not be suitable for operating conditions in this case). The SWP angle decreases too quickly, with the result that the controller needs to correct the SWP angle. In some cases, this behavior may lead to an oscillation of the swashplate angle. This problem can be overcome by accurately determining the Pc-Ps threshold during operation (online/real-time).

By measuring the piston stroke length (related to the SWP angle) and the Pc and Ps pressures, the actual Pc-Ps threshold for the current operating state can be determined.

When the SWP angle changes (i.e., its derivative is not zero or differs from some tolerance band around zero), the corresponding Pc-Ps value is logically the current lower Pc-Ps threshold or the current upper Pc-Ps threshold and is stored in the "lower threshold variable" or the "upper threshold variable".

This can be done permanently, meaning that the Pc-Ps threshold is constantly updated. These thresholds are used by the "second controller" to precisely control SWP angular motion.

FIG. 10 depicts a control according to an embodiment of the invention. The HVAC control unit provides the piston stroke length as a target value to the CCM. In this case, a single controller may be sufficient to control the piston stroke length.